ADVERTISEMENT. 
 
 SAMUEL BROOKS, MANCHESTER. 
 
 SPECIALITY : 
 
 "Ring" System of Spinning- 
 Warp and Weft. 
 
 SPECIALITY : 
 
 l< Ring " System of Spinning- 
 Warp and Weft. 
 
 LARGE STOCKS 
 OF 
 
 TRAVELLERS 
 
 ALWAYS ON 
 HAND. 
 
 THESE TRAVELLERS 
 
 ARE MADE 
 UPON THE PREMISES 
 IN 
 
 WEST GORTON, 
 A LARGE AND 
 EXPENSIVE PLANT 
 HAVING 
 BEEN PUT DOWN 
 SPECIALLY 
 FOR THE PURPOSE. 
 
 Franklin Institute Librart 
 
 PHILADELPHIA 
 
 Class^ l Bool^lOk^ Accession 
 
 Article V.— The Library shall be divided into two classes ; the first 
 comprising such works as, from their rarity or value, should not be lent 
 out, all unbound periodicals, and such text books as ought to be found 
 in a library of reference except when required by Committees ot the 
 Institute, or by members or holders of second class stock, who haxv 
 obtained the sanction of the Committee. The second class shall include 
 those books intended for circulation. : 
 
 Article VI.— The Secretary shall have authority to loan to Members 
 and to holders of second class stock, any work belonging to the second 
 class, subject to the following regulations: 
 
 Section I— No individual shall be permitted to have more than two 
 books out at one time, without a written permission, signed by at leas 
 two members of the Library Committe ; nor shall a book be kept out 
 more than two weeks ; but if no one has applied for it, the former bor- 
 rower may renew the loan. Should any person have applied tor it, the 
 latter shall have the preference. ■ 
 
 Section 2— A fine of ten cents per aveek shall be exacted tor the 
 detention of a book beyond the limited time ; and if a book be not re- 
 turned within three months it shall be deemed lost, and the borrower 
 shall, in addition to his fines, forfeit its value. ... , 
 
 Section 3.— Should any book be returned injured, the borrower shall 
 pay for the injury, or replace the book, as the Library Committee may 
 direct ; and if one or more books, belonging to a set or sets, be lost, tin; 
 borrower shall replace them or make full restitution. 
 
 Article VII.— Any person removing from the Hall, without permis- 
 sion from the proper authorities, any book, newspaper or other property 
 in charge of the Library Committee, shall be reported to the Committee, 
 who may inflict any fine not exceeding twenty-five dollars. 
 
 Article VIII. — No member or holder of second class stock, whose 
 annual contribution for the current year shall be unpaid or who is in 
 arrears for fines, shall be entitled to the privileges ot the Library or 
 Reading Room. . ' «. « 
 
 Article IX.— If any member or holder of second class stock, shall 
 refuse or neglect to comply with the foregoing rules, it shall be the duty 
 of the Secretary to report him to the Committee on the Library. 
 
 Article X.— Any Member or holder of second class stock, detected 
 in mutilating the newspapers, pamphlets or books belonging to the Insti- 
 tute shall be deprived of his right of membership, and the name ot the 
 offender shall be made public. 
 
 Chief Works and Head Offices: UNION IRON WORKS, WEST GORTON. 
 
 Branch Works: JUNCTION IRON WORKS, NEWTON HEATH. 
 
 Town Office: 15, MARKET ST. (Opposite Royal Exchange), MANCHESTER 
 
 Tlcleiji'apbic H&t>ics8 : 
 " UNION," 
 
 MANCHESTER. 
 
 REATEST 
 RE IS 
 5ISED IN 
 DUCING 
 
 ELLERS 
 
 OF 
 
 RM SIZE 
 VEIGHT. 
 
 LISTS 
 )N 
 
 3ATION. 
 
 )ERS 
 2ITED. 
 
 [see next page 
 
/ 
 
 AD VERTISEMENT. 
 
 SAMUEL BROOKS, 
 
 UNION IRON WORKS, WEST CORTON, 
 
 AND 
 
 Town Office: 15, Market Street, 
 opposite Royal Exchange, 
 Manchester. 
 
 Manchester Royal Exchange, 
 Tuesday and Friday, i to 3 p.m. 
 No. 4 Pillar. 
 
 JUNCTION IRON WORKS, NEWTON HEATH 
 
 Telephone No. 605 |\^| A N C H EST E R Telegraphic Address : 
 
 ' "UNION," Manchester. 
 
 MAKER OF 
 
 PREPARATION & SPINNING MACHINERY FOR COTTON, &C. 
 
 REVOLVING FLAT CARDING ENGINES 
 
 (With Wilkinson's Patent Adjustable Revolving Discs.) 
 
 DRAWING FRAMES, 
 
 With Patented Motions, all Positive and Instantaneous in Action. 
 
 SLUBBING, INTERMEDIATE, and ROVING FRAMES, 
 
 From entirely New Models. 
 
 "RING" SPINNING FRAMES, 
 
 For Cotton Yarns (Warp and Weft), and also for Worsted Yarn. 
 
 The "RING" System has long been my Speciality, and the Frames contain many most valuable patented Inventions for increasing the production 
 
 and improving the quality of the yarn. 
 
 "RING" and "FLYER" DOUBLING FRAMES, 
 
 For Sewing Cottons, Mendings, Knittings, Heald Yarns, Nettings, &c; also RING TWISTING FRAMES, 
 
 fitted with Yorkshire " Trap " System, for Worsted Yarn. 
 
 SAMUEL BROOKS has supplied most of the SEWING COTTON MANUFACTURERS with their Machinery, one Firm alone having over ISO.OOO 
 
 "RING" Spindles at work. 
 
 HILL & BROWN'S PATENT WINDING FRAME, 
 
 With or Without Patent Stop Motion, to wind upon Paper Tubes or Bobbins without heads ; will build the 
 yarn any width, from fin. upwards, and any diameter, either Parallel or Conical. The Machine is perfectly noise- 
 less, has no traverse motion to get out of order, and can be run at any speed at which the yarn will come off the 
 cop or bobbin — Patent Stop Motion for winding two or more ends together upon one spool. 
 
 "FLYER" SPINNING and DOUBLING FRAMES, 
 
 Converted (at reasonable cost) into "RING" System. 
 
 RESULTS ALMOS EQUAL TO NEW FRAMES. THOUSANDS OF SPINDLES CAN BE SHOWN AT WORK SUCCESSFULLY. 
 
 Sole Maker of the "AMERICAN STANDARD RING TRAVELLER," for Spinning and Doubling, in Steel 
 or Composition. A large and special plant has been put down for the production of these Travellers, and Custo- 
 mers may rely upon perfect exactness as to size and weight of each number of Traveller. Price Lists on 
 
 application. Orders solicited. 
 LOO M TEMPLES, DOFFER COMBS, ASHWORTH'S LONG COLLARS AND SHELLS, &C. 
 
 All communications to be addressed to the Head Offices: 
 
 SAMUEL BROOKS, Union Iron Works, WEST GORTON, MANCHESTER. 
 
ADVERTISEMENT. 
 
 ESTABLISHED X838. 
 
 BENJ 11 GOODFELLOW 
 
 HYDE, near MANCHESTER. 
 
 MAKER OF HIGH-CLASS 
 
 With Corliss or other Valve Gear, especially adapted for driving all 
 
 description of Mills. 
 
 ROPE, BELT, AND WHEEL GEARING. 
 
 MAIN DRIVING DRUMS TURNED TO ANY DIAMETER OR WIDTH. 
 Improved Metallic Pistons and Air Pump Buckets. 
 
ADVERTISEMENT. 
 
 GRIGHTON & SONS, 
 
 Castlefield Iron Works, 
 
 HAKOHISTI. 
 
 ESTABLISHED 1814. 
 
 Improved Roller Cotton Mixer. 
 
 Improved Crighton Opener, with and without 
 
 Feed Table. 
 Patent Exhaust Crighton Openers. 
 
 Patent Combined Openers and Lap Machines 
 with or without Exhaust. 
 
 Lap Machines, with Patent Leaf Extractor. 
 
 Do., do., and Cone Regulator. 
 
 Do., do., and Piano Motion Regulator. 
 Derby Doublers. 
 Grinding Machines. 
 
 Proprietors by Assignment from W. Higgins 
 
 & Sons and Sole Makers of 
 W. HIGGINS & SONS' PATENT EXPRESS 
 ROVING FRAMES 
 
 Higg 
 Higg 
 
 ns' Drawing Frames. 
 
 ns' HSSJ Stubbing Frames. 
 
 Intermediate 
 Roving 
 
 Jack 
 Merino 
 Silk Dandy 
 
 The above made with Short Collars if required. 
 
 SLUBBING, INTERMEDIATE & ROVING FRAMES, with Mason's Collars. 
 
 SELF-ACTING MULES, PARR'S PRINCIPLE, FOR ALL COUNTS. 
 
 See CRIGHTON'S NEW PATENT OPENER before ordering. 
 
 References to the above Machines will be found in the Chapters relating to them. 
 
ADVERTISEMENT. 
 
 ESTABLISHED 1790. 
 
 DOBSON A BARLOW, 
 
 BOLTON, Lancashire. 
 
 THE OLDEST MACHINE MAKERS IN THE TRADE. 
 
 PATENTEES AND MAKERS OF ALL KINDS OF 
 
 MACHINERY 
 
 On the Latest and Most Approved Principles 
 
 FOR 
 
 PREPARING, SPINNING & DOUBLING 
 
 Cotton Waste, Wool, Worsted, 
 and Vigonia Yarns. 
 
 SEE NEXT PAGE. 
 
ADVERTISEMENT. 
 
 PROPRIETORS OF 
 
 SPECIAL PATENTS 
 
 In the following Machines :— 
 
 Double-Action Knife Roller Cotton Gin, suitable for all 
 classes of Cotton. 
 
 Vertical Conical Beater Openers. 
 
 Double and Single Openers, with or without Lap Machine. 
 
 Double and Single Scutchers, with or without pedal motion 
 Grinding Machines and Grinding Boilers on our improved 
 
 principle. 
 
 Carding Engines on Wellman'S principle, with our patented 
 improvements and additional motions. 
 
 New Patent Comb Box. 
 
 Carding Engines with revolving flats, with our improvements. 
 
 McConnel & Higginson's Patent Flat Grinding Apparatus, 
 
 for grinding Revolving Flats from their working surfaces. 
 
 Carding Engines, "Simplex,'' with revolving flats, with our 
 
 Patent Automitic Flexible Bend Adjustment, 110 flats, 44 
 constantly at work. Flats set to the cylinder to the two- 
 thousandth part of an inch. Patent Adjustable Pedestal 
 mathematically correct, for adjusting cylinder in any direction' 
 Carding Engines, with rollers and clearers, specially adapted 
 for waste and for coarse spinning, with or without Patent 
 Condensers. 
 
 Sliver Lap Machines and Derby Doublers. 
 Heilmann's Cotton Combing Machines, of 6 or 8 heads, 
 
 with our improvements for various kinds of Cotton. 
 
 Patent Draw Frame and Ribbon Lap Machine combined, 
 
 which gives increased out-turn, causes less waste and less wear 
 to the Combers. 
 
 Drawing, Slubbing, Intermediate, Roving and Jack 
 Frames. 
 
 Patent Self -Acting Mules for spinning fine or coarse counts. 
 
 Patent Self-Acting Mules for spinning Vigonia yarns. 
 
 Ring Throstles and Doublers for Cotton, Silk, Combed 
 Wool and Merino Yarns, with our patented cork-cushion 
 flexible Spindle ; also with the " Rabbeth " or other Spindle. 
 
 D. & B.'s Patent Automatic Anti-Ballooning 
 
 Motion, its application economising almost 10 per cent, spindle 
 space ; can be applied to existing Frames of any make. 
 Mule Twiners on our recently improved principle. 
 
 Patent Quick Traverse Drum Winding Frames, with or 
 
 without Stop Motion to each end, for making parallel or 
 conical bobbins, or parallel bobbins with tapered ends. 
 
 Improved Cop Winding Frame. 
 
 Patent Gassing Frames, with or without Patent Quick 
 
 Traverse Motion, for winding on to wood or paper tubes, or 
 with Patent Tapering Motion. 
 Cop Reels on Coleby'S principle, with our Patent Instanta- 
 neous Stop Motion for stopping the swift when a thread 
 breaks, or when the required length is put on the swift. 
 
 SPECIAL APPLIANCES FOR COVERING ALL KINDS OF ROLLERS, CLEARERS AND FLATS. 
 
 Also Makers of many other Machines and Tools. 
 
 SOLE OPRIETORS OF THE 
 
 Patented Cork-Cushion Flexible Spindle, 
 
 WITH OR WITHOUT THE 
 
 DOBSON-MARSH SELF-LUBRICATING ATTACHMENT, 
 
 For Spinning and Doubling. Will run either twist or weft way by simply changing the position of the bands. 
 
 PERFECT LUBRICATION. LIGHT RUNNING. 
 
 Stoppages of Spindles not required whilst Re-Oiling. No Pumping out of Dirty Oil. Oil Cups can be taken off, dirty oil 
 removed, cups re-filled and attached whilst Spindles are in motion. 
 
 The Dobson-Marsh Lubrication Attachment can also be applied to Rabbeth Spindles. 
 ALSO MANUFACTURERS OF MANY OTHER KNOWN KINDS OF SPINDLES. 
 
 Particulars of Special Improvements in Cotton Preparing and Spinning Machinery, also Plans and Estimates, 
 
 may be had on application to 
 
 DOBSON & BARLOW, Kay Street Works, BOLTON. 
 
 Manchester Office : 2, ST. ANN S PLACE. 
 
ADVERTISEMENT. 
 
 HOWARD & BULLOUGH, 
 
 MAKERS OF 
 
 Cotton Spinning & Manufacturing Machinery 
 
 Of the most modern and approved principle, and embracing all the latest 
 
 patent improvements. 
 
 ANGLO-AMERICAN OPENERS and SCUTCHERS 
 
 Comprise the best points of English and American Machines. 
 
 These Openers and Scutchers are remarkable for cleaning power without damaging Staple, and for regularity 
 
 and evenness of LAP. 
 
 NEW PATENT REVOLVING FLAT CARDING ENGINE 
 
 With rigid Bend. 110 Flats. 43 Working. 
 MADE AND ON ORDER UP TO DATE 3,583. 
 
 1. — Rigid bend, mathematically correct at all stages of the wire. 
 
 2. —Arrangement for adjusting Flats, whereby accuracy to the thousandth part of an inch is attained. The 
 
 most ordinary workman can be entrusted with this adjusting arrangement. 
 
 3. — Flats and Cylinders are covered with hardened and tempered steel wire. 
 
 4. — Quantity carded, from 900 to 1,100 lbs. per week. 
 
 5- — Fewer engines required — less oil — less power— less room — less attention required, and equal yarn made 
 
 from CHEAPER COTTON Or HIGHER PRICED YARN from EQUAL PRICED COTTON. 
 
 PATENT ELECTRIC STOP-MOTION 
 
 Applied to Drawing and Intermediate Frames, for preventing "Single"; patented August, 1875; applied already 
 to 27,631 Delivery heads of drawing, and 165,027 Intermediate Sj>indles. 
 
ADVERTISEMENT. 
 
 mm SPIMING FRAME. 
 
 • 1 1 1 1 1 1 1 i . i ■ 1 1 1 . i . 1 1 1 1 1 1 1 i . i . 1 1 1 , i , i ■ i . 1 1 1 ■ i i ■ i ■ 
 
 THE LARGEST MAKERS IN THE WORLD. 
 
 This Spinning Frame has been so extensively adopted, and has attained its present high degree of perfection 
 owing, Firstly — to its being properly made. We had the advantage of Mr. Kabbeth's personal assistance and 
 experience, and he furnished us with the most perfect special tools for making the spindles and rings. 
 
 Secondly : — Our experience, now extending over 3,792,570 spindles — constituting ns the largest makers of 
 ring frames in the world — has enabled us to perfect the machine mechanically and to introduce improvements 
 which have increased its production 20 per cent, in five years — extended its scope into higher counts of yarn, and 
 enabled it to compete successfully with the Mule in spinning weft and soft yarn. 
 
 Ring Weft Frames. 
 
 Howard & Bullough desire to say that their Ring Spinning Weft Frame is successfully established. It is as 
 successful for spinning Weft on Pirns (not on the bare spindle) as is their well-known Rabbeth Ring Frame for 
 spinning Twist, and is entitled to equal confidence. 
 
 References given on application, comprising leading and extensive mills where the Weft Ring has entirely 
 displaced the mule. 
 
 RING DOUBLING FRAMES. 
 
 Made either on the English or Scotch system, for ordinary Doubling or for Sewing Cottons. 
 
 AMERICAN STANDARD RING TRAVELLERS, for 
 
 Spinning and Doubling. 
 
 AMERICAN SPINDLE OIL, for Ring Spindles. 
 
 BEST BOBBINS for Ring Spinning. 
 
 CAUTIONi — Howard & Bullough emphatically warn the trade against the evils arising from bad or 
 unsuitable oil, and ill-fitting or badly balanced bobbins. 
 
 HOWARD & BULLOUGH, Accrington, Lancashire. 
 
 Accrington is distant from Manchester only 20 miles. Frequent trains run daily from Victoria or 
 Salford Stations on the Lancashire and Yorkshire Railway. 
 
 July 31st, 1890. 
 
ADVERTISEMENT. 
 
ADVERTISEMENT. 
 
 LORD BROTHERS 
 
 Can&l Biwmmi W@rito 
 
 LORD BROTHERS are Makers of the following Machinery, off 
 Newest Models, with all latest Improvements: — 
 
 "Cotton Pulling" or "Bale Breaking" and Mixing 
 
 Machines. 
 Patent "Exhaust" Fans. 
 
 Patent " Exhaust" Openers. 
 
 Patent "Exhaust" Horizontal Cylinder 
 
 Openers, combined with Scutchers and 
 
 Lap Machines, for drawing Cotton any 
 
 distance up to 1,000 feet. 
 Patent Combined "Exhaust" VERTICAL 
 
 CYLINDER Openers, with or without 
 
 Scutchers and Lap Machines. 
 Patent Openers, with Cylinders and Beaters, 
 
 combined with Scutchers and Lap 
 
 Machines. 
 
 Patent Scutchers, with Lap Machines. 
 
 Patent "Express" Cards. 
 Patent Improved ' Piano '' Regulators. 
 Patent ' Revolving" Flat and Improved "Wellman" 
 Flat Cards. 
 
 Single and Double Roller and Clearer Carding Engines, 
 with Patent Setting Arrangements for Rollers, 
 Clearers, Grinding Rollers and Mote Knife. 
 
 Drawing Frames, with Improved Quick-Stop Motions. 
 Slubbing Frames, with Patent Steps, Short or Long 
 
 Collars, Patent Cone Motion, and built to stand high 
 
 speeds. 
 
 Intermediate Frames, Short or Long Collars, as above. 
 
 Roving Frames, with do. do. do. 
 
 Fine Jack Frames, with do. do. do. 
 
 Improved " High-Speed Flyer " Throstle, with Patent 
 Steel, New Patent " Self- Lubricating," or our Im- 
 proved Ashworth's Cast-Iron Collars. 
 
 Flyer Doubling Frames, on same principle as High-Speed 
 Throstle, for every description of Thread or Lace 
 Yarns. 
 
 Ring Spinning Frames with our Improved " Flexible " or 
 
 Rabbeth Spindles. 
 Improved Ring Doubling Frames. 
 Winding Frames. 
 Warping Mills. 
 Ball-Sizing Machinery. 
 Warp- Drying Machines. 
 Beaming Machines. 
 Patent Looms, Single Shuttle or Box. 
 Looms with Patent Positive "Let-off" Motion. 
 Patent Indigo Mills, &c, &c. 
 
 MILLWRIGHTS, BRASS AND IRON FOUNDERS. 
 
 N.B.— LORD BROTHERS purchased the whole of the Patterns and Business of the late 
 firm of John Elce & Co., Limited, and can execute orders for new or repairs for existing 
 Machinery. 
 
 Telephone Number 6. Manchester Exchange, Tuesdays and Fridays, No. 12 Pillar. 
 
 Telegraphic Address: " LORDS, TODMOKDEN." 
 
ADVERTISEMENT. 
 
 ASA LEES^^CO. 
 
 LI IM! ITS ID, 
 
 SOHO IRON WORKS, OLDHAM. 
 
 MANCHESTER OFFICE (Open Tuesdays and Fridays), 27, H0PW00D AVENUE. 
 
 CONSTRUCTORS OK 
 
 ALL KINDS OF MACHINERY 
 
 For Preparing, Spinning, and Doubling Cotton and Wool. 
 
 OPENERS. — Improved Cotton Openers, with Porcupine 
 Cylinders. Crighton's Openers and Patent Exhaust 
 Openers. 
 
 SCUTCHERS OR LAP MACHINES. -Single or Double, 
 with our Patent Feed Regulator, with rope driving. 
 
 OPENER AND LAP MACHINES combined. 
 
 SINGLE CARDING ENGINES, with Rollers and Clearers. 
 
 SINGLE REVOLVING FLAT CARDING ENGINES, 
 
 with various widths of flats, and recent improvements. 
 
 DOUBLE CARDING ENGINES of various Patterns, with 
 Rollers and Clearers, or with Revolving Flats. 
 
 COMPOSITE DOUBLE CARDING ENGINES, with 
 Rollers and Clearers on first Cylinder, and Revolving Flats 
 on Finishing Cylinder. 
 
 CARDING ENGINES for Wool, Wadding, &c. Con- 
 densers, &c. 
 
 DRAWING FRAMES, with Improved Front and Back 
 Stopping Motions. With Full Can Stopping Motion, 
 Weight Relieving Motion, and Traverse Motion, if required. 
 
 SLUBBING, INTERMEDIATE & ROVING FRAMES, 
 
 made from new Patterns, with recent Improvements, 
 Ordinary or Long Spindle Collars, &c. Taylor's Patent 
 Cone Releasing Motion. 
 
 PATENT SELF-ACTING MULES for Cotton, Coarse 
 
 or Fine Counts. 
 
 PATENT SELF-ACTING MULES for Wool, Shoddy, 
 Mungo, and Cotton Waste. 
 
 PATENT SELF-ACTING MULES for Worsted. 
 
 PATENT SELF-ACTING TWINERS, with Improved 
 Horizontal Brass Locking Slide with Moving Creels, or on 
 the Mule principle, with Stationary Creels. 
 
 PATENT SELF-ACTING TWINERS for Twisting or 
 Doubling Wool, Worsted, or Mixed Yarns. 
 
 FLYER THROSTLE FRAMES, for Spinning or Doub- 
 ling. 
 
 IMPROVED RING SPINNING AND DOUBLING 
 FRAMES. 
 
 SOLE AGENTS FOR THE CONTINENT OF EUROPE : — 
 
 BAERLEIN & CO., 12, Blaekfriars Street, SALFORD, MANCHESTER, 
 
 To whom all Communications relating to Continental Business should be addressed. 
 
ADVERTISEMENT. 
 
 PLATT BROTHERS & CO. Ltd., 
 
 HARTFORD WORKS, OLDHAM, ENGLAND. 
 
 Plain op Fancy, with Lifting op Revolving Boxes, for Cotton, Linen, Woollen, Worsted, Jute, 
 
 Silk, and Carpets. 
 
 JAGQUARD DOBBIES, WITCHES, PATENT OSCILLATING TAPPETS, WOODCROFT TAPPETS, ANO SHEDDING MOTIONS 
 
 OF EVERY DESCRIPTION. 
 
 COTTONJ.MULB— Front View. 
 
 PATENT SELF-ACTING MULES and TWINERS, 
 
 For COTTON, COTTON WASTE, WOOL, WOOLLEN WASTE, WORSTED, and SILK. 
 
 CLOTH FOLDING AND MEASURING MACHINE S. 
 IMPROVED HYDRAULIC AND CAM BUNDLING PRESSE S. 
 COLEBY'S IMPROVED BUNDLING PRESSES. 
 
 CHAPON'S PATENT CUP SPINNING MACHINE FOR COTTON, WOOL, AND WASTE. 
 
 MANCHESTER OFFICE :— 5, St. Ann's Square. 
 
 GLASGOW OFFICE:— 160, Hope Street— Mr. RICHARD MURRAY, Agent. 
 
 FOEEIGN 
 RUSSIA.— Messrs. De Jersey and Co , Manchester ; and Mr. L. 
 
 Knoop. Moscow. 
 FRANCE, BELGIUM, ITALY, BAVARIA, &c.-Messrs. Adolphus 
 
 Sington & Co., Manchester. 
 BOHEMIA and SAXONY.-Mr. W. W. Derham, Leipsic 
 AUSTRLA-Messrs. M. Schoch & Co.. Vienna. 
 BADEN. WURTEMBURG and SWITZERLAND.— Messrs. M. 
 
 Schoch & Co., Zurich. 
 SPAIN, PORTUGAL and MEXICO.-Messrs. John M. Sumner 
 
 & Co., Manchester. 
 
 AGENTS 
 
 WESTPHALIA.— Messrs. S. D. Bles & Sons, Manchester ; and in 
 
 HOLLAND (for Cotton Machinery only). 
 SCANDINAVIA and DENMARK — Messrs. D. Foxwell & Son, 
 
 1, North Parade, Parsonage, Manchester. 
 UNITED STATES— Messrs. F. A. Leigh & Co., 35 and 36, Mason 
 
 Building. Boston, Mass. 
 BOMBAY PRESIDENCY.— The Hon. N. N. Wadia, CLE., Tardeo, 
 
 Bombay. 
 
 JAPAN and the COREA.— Messrs. Mitsui & Co-, 1, Crosby 
 Square, London. 
 
 SEE TWO FOLLOWING PAGES 
 
ADVERTISEMENT. 
 
 Machinery for Preparing and Spinning Vigogne and 
 Cotton Waste or Barchant Yarns. 
 
 MACHINERY FOR CARDING & SPINNING SILK WASTE. 
 
 For Cotton, Wool, Worsted, and Silk. 
 
 DRAWING, SLUBBING, INTERMEDIATE, and ROYING FRAMES, 
 
 Fop Cotton, Worsted, and Silk. 
 
 PATENT WEFT RING FRAME (on Bare Spindle). 
 
 RING SPINNING FRAMES (for Warp and Weft), 
 
 To Spin on Bobbins, Pirns, Paper Tubes, and BARE SPINDLE. 
 
 BOYD'S PATENT STOP-MOTION TWISTERS. 
 
 RING DOUBLING FRAMES, 
 
 For Cotton, Wool and Worsted— with Motions for making Spot, Loop, and all kinds of Fancy Yarns. 
 
 IMPROVED MACHINERY FOR 
 
 PREPARING, COMBING, ROVING, AND SPINNING WORSTED 
 
 On the FRENCH SYSTEM, as lately Exhibited at the Manchester Jubilee Exhibition. 
 
 PREPARING MACHINERY FOR WEAVING, 
 
 Including Winding, Warping, Sizing, Beaming, and Dressing Machines, for Cotton, Linen, 
 and Jute Yarns, and Starching Machines for Carpet Yarns. 
 
 SEE NEXT PAGE. 
 
ADVERTISEMENT. 
 
 Telegraphic Address: " PLATTS, OLDHAM." 
 
 Telephone No. 26. 
 
 PLATT BROTHERS A CO. Ltd. 
 
 MACHINISTS, 
 
 HARTFORD WORKS, OLDHAM, ENGLAND, 
 
 MAKERS OF MACHINERY FOR 
 
 PREPARING, COMBING, SPINNING, DOUBLING & WEAVING 
 COTTON, WOOL, WORSTED, & SILK, 
 
 PATENT MACARTHY ROLLER COTTON GINS, 
 for Long or Short Stapled Cotton. 
 
 IMPROVED COTTON BALE BREAKER, with and 
 without Mixing Lattices. 
 
 HARD WASTE BREAKING UP MACHINES. 
 
 CRIGHTON'S OPENERS, with Improved Creeper 
 Feeder. 
 
 PATENT "EXHAUST'' OPENERS, with or without 
 Lap Machines, and with Patent Travelling Dirt 
 Lattice applied to Dust Trunk. 
 
 SCUTCHERS, with Patent Pedal Regulators. 
 
 REVOLVING SELF-STRIPPING FLAT CARDING ENGINES, 
 
 1888 3E»A.mi3XrT, 
 
 Of Various Sections, from 72 Flats 2in. wide, 90 Flats X|in. wide, to X06 Flats lfin. wide. 
 
 PATENT APPARATUS FOR GRINDING THE FLATS FROM THEIR WORKING SURFACES. 
 ROLLER & CLEARER CARDING ENGINES, Single of Double, made to any width required. 
 
 CARD GRINDING MACHINES. PATENT BURRING MACHINES FOR WOOL 
 COTTON CARDS combined with CONDENSERS, 
 
 SPECIALLY ADAPTED FOR WASTE OR COARSE SPINNING. 
 
 CARDS AND CONDENSERS FOR WOOL, Martin's, Bolette's, Sachsische and other Systems, with Ball, Scotch, 
 
 and Blamire's Feeding Arrangements. 
 
 SEE TWO PRECEDING PAGES. 
 
MODERN COTTON SPINNING MACHINERY, 
 ITS PRINCIPLES AND CONSTRUCTION. 
 
 BY 
 
 JOSEPH NASMITH, 
 
 ASSOCIATE INSTITUTION MECHANICAL ENGINEERS, 
 MEMBER MANCHESTER ASSOCIATION OP ENGINEERS, ETC. 
 
 WITH TWO HUNDRED AND THIRTY-TWO ILLUSTRATIONS. 
 
 MANCHESTER : 
 JOSEPH NASMITH, 4, Arcade Chambers, St. Mary's Gate; 
 JOHN HEYWOOD, Ridgefield and Deansgate. 
 
 LONDON : 
 
 E. & F. N. SPON, 125, Strand; and 12, Cortlandt Street, New York. 
 
 1890. 
 
 [COPYRIGHT. ALL RIGHTS RESERVED.] 
 
PEEF ACE. 
 
 > * < 
 
 TN submitting the following pages to the judgment of the public, the Author does not pretend to have written 
 an exhaustive treatise. This would require a volume much larger than the present. It has rather been his 
 aim to treat a branch of the subject thoroughly, which has hitherto had scant justice done to it. While the 
 market is flooded with books detailing the rules by which speeds are calculated, and the necessary wheel changes 
 made, those dealing with the construction of the machinery employed are few in number. This is the more 
 singular, because England is, beyond doubt, the true mother of this department of mechanics, and to-day her 
 textile machinists head the lists alike for excellence of production and fertility of invention. 
 
 Since the issue of the late Mr. Evan Leigh's " Science of Modern Cotton Spinning "-comparatively a long 
 time ago-no book has appeared which treats the subject from the machinist's point of view. The well known 
 book of Mr. Richard Marsden, "A Handbook of Cotton Spinning," as its name implies, deals more with the 
 operation than the machinery, although the latter is described in considerable detail. In the present work, 
 while it has been impossible to avoid saying something of spinning, the enunciation of the principles on which 
 the machinery is constructed forms its raison d'itre. On the Continent, more than one ponderous treatise has 
 been published, which possess the peculiarity of foreign technical works in the disproportionate way in which 
 the small details are treated. While this is valuable from the professorial point of view, it is apt to be 
 prejudicial in actual practice, because the operation of these details varies considerably at different times. The 
 avoidance of pedantry is very essential in any book dealing with practical work, and with this in view, the 
 Author has endeavoured, while fully considering every principle involved, to do so in a plain manner, which will 
 be readily understood. It has rather been the aim to suggest the inferences to be drawn than to dogmatically 
 state inflexible rules. 
 
 The whole of the machines have been considered fully, and the most important modifications described. 
 The preparation of the drawings has been a long labour, but the Author believes they have not hitherto been so 
 fully given in any English work. In order to keep the book within bounds, it has been almost rigidly confined 
 to a consideration of the art of textile mechanics as applied to the spinning of cotton to-day. It is believed that 
 the book will provide an accurate account of the state of present knowledge, and will be valuable for that 
 reason. 
 
 It should be distinctly understood that the mention of any machinist does not imply any approval or 
 otherwise of his particular appliance, but is simply given in order to identify the maker of it, which it is only 
 fair to do. The Author's opinions can be easily gathered, but it is no part of the scheme to enter into controversy 
 about different methods, or to make the book a treatise on comparative textile mechanics. 
 
 The Author desires to thank all those firms who have aided him by the loan of drawings, or in other ways. 
 Without this aid the labour involved would have been largely increased. Thanks are due to Signor Alfredo 
 Galassini and the Director of the Unione Tipografico-Editrice of Turin for permission to reproduce some of the 
 drawings relating to Messrs. Piatt Brothers and Co.'s mule, which will be found in Chapter XI. These had 
 appeared in the " Enciclopedia Delle Arti E Industrie," and were so much in accord with the treatment the Author 
 had resolved to give that machine, that the permission to use them was of great service. The special thanks of 
 the Author are also due to Mr. B. A. Dobson for the permission to reproduce two photographs of a lap, 
 given in Chapter VI., and other drawings from his pamphlet on "Carding." In conclusion, before leaving 
 the book to the indulgent judgment of his readers, the Author wishes to say that the proofs have been 
 read by gentlemen conversant with the whole of the details, and every care has been taken to make it at once 
 accurate and instructive. 
 
 8 (o Z I 
 
TABLE OF CONTENTS 
 
 Introductory 
 
 The Structure of Cotton 
 
 Ginning and Mixing Machines 
 
 The Opening Machine 
 
 The Scutching Machine ... 
 
 The Carding Machine 
 
 CHAPTER I. 
 
 CHAPTER II. 
 
 CHAPTER III. 
 
 CHAPTER IV. 
 
 CHAPTER V. 
 
 CHAPTER VI. 
 
 CHAPTER VII. 
 Card Clothing, Grinding, aud Stripping Machines 
 
 The Combing Machine 
 The Drawing Machine 
 Slubbing and Roving Machines 
 
 The Mule 
 
 The Ring Spinning Machine 
 
 CHAPTER VIII. 
 
 CHAPTER IX. 
 
 CHAPTER X. 
 
 CHAPTER XI. 
 
 CHAPTER XII. 
 
 CHAPTER XIII. 
 Reeling, Winding, Gassing, and Spooling Machines ... 
 
 CHAPTER XIV. 
 
 Miscellaneous Machines and Accessories 
 
 Appendix ... 
 
 List of Illustrations ... 
 
 Glossary 
 
 General Index 
 
 PAGK 
 
 5 
 12 
 
 .. 15 
 
 23 
 
 ... 35 
 53 
 
 ... 91 
 
 120 
 ... 137 
 
 147 
 ... 176 
 
 234 
 ... 262 
 
 282 
 
 ... 297 
 301 
 ... 308 
 309 
 
V -L lx V JL JLl^JA, 1. 
 
 E E R ATA. 
 
 The reader is requested to make the alterations enumerated below at once in order to prevent any 
 misunderstanding. 
 
 Oil page 51, end of line 23, for "it" read "is." 
 On page 66, line 15, for "Fig. 51" read "Fig. 52." 
 
 On page 162, third line from bottom, for "n = b - 21" read " n = 21 - b." 
 
 On page 163, line 7, for "n - 250 - 2 (-% 0 -) " read «n = - 250 - 2 (^% 0 -)" 
 
 On page 165, second line from bottom, for "G " read " E." 
 
 On page 210, line 3, for "B" read " D." 
 
 On page 212, end of last line, for "fallen" read "faller." 
 
 On page 267, line 4, for "straps" read "shafts." 
 
 The author is fully conscious of many shortcomings, which are inevitable in a task of this magnitude, 
 but he believes that something has been done to formulate present knowledge and practice. Any suggestions 
 of improvements or enlargements will be gratefully received, so as to enable future issues to be more valuable 
 and useful. 
 
 enlarging, the possible extent of the cotton industrv bein<r enormous. The number of sninrllfis «t in 
 
CHAPTER T. 
 
 CHAPTER XIV. 
 
CHAPTER I. 
 
 INTRODUCTORY. 
 
 (1) The rapid growth of the cotton trade is in no small degree due to the exertions and ingenuity of the 
 engineers and machinists who have devoted themselves to the subject. It is remarkable how few of the later 
 inventions, at any rate, are those of persons actually engaged in the operations of spinning or weaving. It is quite 
 true that James Smith, of Deanston, forms a conspicuous exception, and that many others could be also named 
 who were at once manufacturers and mechanicians, but the general fact is as stated. To-day, the spinner, who is 
 in a difficulty requiring a mechanical solution, turns the whole matter over to the machinist, who puzzles it out 
 without, in many cases, getting his due reward. It is, however, a general practice for machinists to originate 
 improvements, and the competition in this respect is so keen, that a spinner is never at a loss for a choice of 
 appliances. 
 
 (2) In the early part of the century it was no uncommon thing to find textile machines made in a workshop 
 where engines, machine tools, and other forms of machinery were also constructed. For about the last forty years 
 this practice has ceased, and it is now the universal custom to make textile machines only, in any works where they 
 are produced. This practice has led to a subdivision, not only of labour, but of procedure, which enables good 
 results to be attained. The machine of to-day, although not absolutely, is comparatively, cheaper, and is constructed 
 in a way that even thirty years ago would have been deemed impossible. When the author was an apprentice, about 
 twenty years since, the fitting of cotton machinery was a byeword to the engineer and tool maker. To-day, it would be 
 difficult to find more accurate workmanship or sounder construction in any machine of whatever kind. 
 
 (3) This is a matter of more importance than might be supposed. The cotton spinning machine making 
 trade in England is a very extensive one, finding employment in Lancashire alone for not less than 25,000 
 men and boys. This does not include the large number of persons employed in the various businesses which 
 are allied to it, such as spindle and card clothing manufactories. The field for spinning machines is ever 
 enlarging, the possible extent of the cotton industry being enormous. The number of spindles at work in 
 Great Britain exceeds 44,000,000 ; on the Continent the number is about 23,800,000 ; in the United States 
 14,500,000 • and in India and Japan it exceeds 3,000,000. These figures, which are approximate 
 only, give a grand total of 85,300,000 spindles, which may all be said to have sprung into being during 
 the present century. Assuming the value of a mill to be equal to 21 shillings per spindle m England, the 
 fixed capital embarked in this branch of the trade alone is £44,220,000. If the very moderate amount of 
 20 per cent be added to this for working capital, the sum invested in cotton spinning concerns in this 
 
6 
 
 INTRO DUCTOEY. 
 
 country is not less than £53,000,000. The cost per spindle in other countries is much in excess of the 
 amount stated above, being in many cases doubled. In the United States the cost of a fully equipped 
 spinning-mill ranges from 40 to 42 shillings per spindle, and the capital needed for working is also greater 
 than in this country. On the Continent, and in India, the cost per spindle will be less than in America, 
 but the working expenses are also higher than in Great Britain. In thus stating the facts it is impossible 
 to accurately fix the capital employed, but it will probably approach in the aggregate £150,000,000 
 for spinning mills alone. 
 
 (4) The foregoing figures, which are very briefly put, are sufficient to show the magnitude of the industry 
 for which spinning machinists cater. But there is another aspect of the question which is noteworthy, and 
 illustrative of the effect of the work of machine makers. This is the large increase in the productive 
 capacity of the machinery. The production of a self-acting mule in 1835 is given in the following state- 
 ment, issued by the eminent firm of Sharp, Roberts and Co., and extracted from Dr. Ure's work on "Cotton 
 Spinning." 
 
 "Statement of the quantity of Yarn produced on Messrs. Sharp, Roberts & Co.'s self-acting mules in twelve 
 working hours, including the usual stoppages connected with spinning, estimated on the average of upwards of 20 
 mills : — 
 
 No. of hanks per spindle. 
 No. of yarn. Twist. Weft. 
 
 16's «... 4£ 4g 
 
 24's 4i 4g 
 
 32's 4 4§ 
 
 40's 3| 4J." 
 
 This statement is dated December 23rd, 1834, so that it may fairly serve as a basis of comparison, assuming 
 the number of turns of yarn to be in each case the same. Testing the advance by taking the production of 32's, as 
 stated above, the amount spun per spindle in a working week of 50| hours — its present duration — would be 18| 
 banks. Mules at that period were only made 400 to 500 spindles long. To-day they contain over 1,200 spindles, 
 and produce of 32's 32£ hanks per spindle. This is an increase of 60 per cent. 
 
 (5) The increase of production has not, however, required a larger number of workpeople to obtain. On the 
 other hand, fewer persons are needed to attend to the long mules named than were formerly required for less than 
 half the number of spindles. The effect of this is seen in the decreased margin between cotton and yarns, which 
 is very striking. The average price of 30's twist yarn in 1832 is stated in Dr. Ure to be 12'7d. per lb., and of 
 cotton 7-ld., leaving a margin of 5'6d. At the time of writing the price of 32's twist is 8j|4., and of cotton 
 6 x \d. per lb., leaving a margin of 2£d. These figures are based upon the assumption that American cotton of 
 middling quality is used in each case. Thus the price of yarn is much less, while that of cotton is little reduced. 
 It is true that a margin of 2£d. is barely sufficient to permit of a profit being made, but £d. per lb. added will do 
 so, and a margin of 2 Jd. is considered a large one in these days. 
 
INTKODUCTOKY. 
 
 7 
 
 (6) This reduction in the cost of production has not been brought about by any diminution in the wages of 
 the operatives, as could very clearly be shown if it were necessary. Nor is it the result of a lessened cost of erec- 
 tion. A spinning mill of 40,000 spindles, which in 1835 would be looked upon as a large one, cost, at that time, 
 from 24 to 26 shillings per spindle to erect, including the buildings and accessories. At the present time mills 
 are built to contain as many as 110,000 spindles, and these are filled ready for work at a cost not exceeding 21 
 shillings per spindle, the apportionment of which is as follows : The machinery costs nine shillings, the buildings 
 eight shillings, and the engines, boilers, furnishings, and all accessories four shillings per spindle. Considering the 
 great increase in the productive power of the machinery, the fact that it is so much less expensive to work, and 
 that each machine is of much greater capacity, the figures given show that the tendency towards diminished cost 
 is owing very largely to the efforts of machine makers. 
 
 (7) It is not necessary to pursue this matter further, as the present work is not intended as a statistical 
 abstract, but the few facts stated show that in the general march of improvement the textile mechanic has not been 
 idle. A consideration of the methods of construction adopted to-day, as compared with those in vogue even so 
 recently as twenty years ago, will further demonstrate this fact. Formerly the work of construction was very 
 largely if not mainly carried out by fitters who were engaged in manually shaping the brackets and fitting them 
 to the frames. The brackets were formed with feet, on which were cast nipples or projections. These were 
 used to reduce the labour in filing, and, as the bracket was always fitted on to the face produced in the ordinary 
 operation of casting, it will be seen that anything tending to diminish the work of fitting was valuable. But as 
 the bedding of the brackets was dependent upon the proper shaping of a few points, the tendency to slip was con- 
 siderable. Although, by being always engaged in fitting a few patterns of brackets, the workmen became extra- 
 ordinarily expert, the method was at best an uncertain one, and did not lead to the rigidity absolutely essential in 
 high-speed machines. 
 
 (8) All this is now changed, and the machine tool enables the work to be at once more expeditiously and 
 economically carried out. The labours of mechanics of precision, like the late Sir Joseph Whitworth, are bearing 
 fruit, and the effect is seen in the comparative excellence of the product. The solidity of English machinery has 
 been sometimes scoffed at by Continental and American rivals, but it would be difficult to find any which runs at 
 higher velocities with greater steadiness and less repairs. It cannot be too often insisted on that the rigidity 
 which arises from mere weight is by no means an unimportant quality. Of course, there are limits to this as to every 
 other principle, but generally it is a true one. Of quite as much importance is the rigidity which comes from 
 sound construction ; and in this respect modern spinning machinery is remarkable. Instead of a framing built up 
 by hand with its various pieces manually fitted, it is now made in a much more enduring way. Raised faces are 
 formed on the framing, which are planed or milled, so as to be quite true. To these the cross-beams or bars, the 
 ends of which are similarly treated, are bolted. Thus, instead of the contact of several narrow faces, two bread plane 
 surfaces are bolted together, and it will be easily seen how much more solid the framing will be in consequence. 
 Again, in lieu of each part being at once like and unlike, as must necessarily happen when it is hand-fitted, it is 
 now shaped by special machinery to templates, thus being interchangeable. The rails or beams to which bearings, 
 
8 
 
 INTRODUCTORY. 
 
 brackets, or spindles are to be attached are planed or milled accurately on their surfaces, so that the long and 
 unsatisfactory labour of fitting each piece separately is substituted by a true mechanical process. The advent of 
 the milling machine and the discovery of the wonderful economic power of the circular cutter has had a wide- 
 reaching influence. In brief, the present is an age of an increased development of machine instead of manual 
 treatment, which has gone far to revolutionise the machinery used in spinning. Every student who may hereafter 
 be engaged in the construction of this class of machinery should impress firmly upon his mind the fact that the 
 machine tool is the best instrument for his purpose, and should develop it as far as possible. A special tool is 
 invaluable, and the opportunities for its use are always increasing. 
 
 (9) A comparison of the speeds of various machines will demonstrate the value of improved construction. Mule 
 spindles, which in 1834 were run at a maximum velocity of 4,500 revolutions per minute, are now revolved 11,000 
 times per minute with much greater ease and freedom from vibration. The throstle spindles running at a speed 
 of 4,500 revolutions, are superseded by ring spindles, which rotate from 9,000 to 11,000 times per minute. As 
 shown in Chapter XII, it would ba impossible to attain such a velocity unless the spindles were accurately con- 
 structed by special tools. Although the mechanism of a ring spindle is much more elaborate than that of a 
 throstle spindle, the cost of the one but little exceeds that of the other. Again, a carding engine cylinder, formerly 
 made of wood, and running 80 to 100 revolutions, is now constructed entirely of iron, and revolved at from 160 to 180 
 times per minnte. In spite of thia increase it is more free from vibration than its slower runniog predecessor. A 
 similar comparison can be made of every machine with like results, but it is not necessary. Enough has been said 
 to show the important part played by the machinist, to whom, as was pointed out in paragraph 1, most of the credit 
 is due. The economical improvement which is noticeable in the condition of the workpeople is largely the result 
 of the improvements made in the machinery. In fewer hours more work can be turned out, and this with a con- 
 stantly decreasing strain upon the operatives. The breakage of the fibres in the various stages of manufacture is 
 reduced to a very low point, with the two-fold advantage of diminished waste and decreased labour. 
 
 (10) A modern mill differs from its immediate predecessor, not only in the quality of the machinery but in its 
 general construction. The height and width of the whole building have materially increased, and the result is that 
 the rooms in which the operations of spinning are conducted are both lighter and more airy. The building is 
 usually made as far as possible fire-p:oof, and is of very substantial design and construction. The larger number 
 of spindles in a mill necessarily imply greater capacity, but there is no comparison between the low-ceilinged, 
 imperfectly lighted and ventilated rooms of the last generation with the airy and light erections of to-day. The 
 sanitary arrangements are infinitely superior, and there is a noticeable improvement in the health and physique 
 of the workpeople arising therefrom. 
 
 (11) Among the features which deserve mention is the improved type of engines used. In lieu of the 
 old-fashioned beam engine, compounded or otherwise, working at a steam pressure of 501b. or less, the modern 
 engine is of the horizontal type. The favourite class for mill driving is the tandem compound, in which the 
 high pressure cylinder is behind the low-pressure, but on the same bed. Latterly the vertical triple expansion engine 
 has been adopted in a few cases, and there is a continual tendency towards higher steam pressures and more 
 
INTKODUCTOEY. 
 
 9 
 
 expansions. The introduction of steel boiler plates has rendered the construction of steam boilers for high 
 pressures much more easy, and the author has seen a Lancashire boiler, intended for habitual use at a pressure 
 of 2201b., tested with highly satisfactory results. Within limits, therefore, there is room for a further increase 
 from the normal working pressure of 801b. The steam-engines used are mostly of the Corliss type, with quick 
 cut-off gear of high efficiency, and they are constructed to develop in many cases from 1,000 to 2,000 horse- 
 power. The water used for condensing purposes is stored in reservoirs or "lodges," from which it is drawn 
 as required. It is sometimes difficult to cool it sufficiently to get a good vacuum, owing to the fact that the 
 cooling and storage space is insufficient. For this purpose a type of condenser known as Theisen's, which has 
 been largely adopted in Germany and is now being introduced into this country, will be of value. It is 
 arranged as a surface condenser, the steam passing through the tubes and being cooled by water surrounding 
 them. In lieu of giving the water a circulatory movement it always remains in one position, any loss by 
 evaporation being replaced. Between each vertical row of pipes cast-iron discs revolve, which are fixed on a 
 shaft suitably driven. As each disc dips into the water— which is usually about 160 deg. R— it picks up 
 a thin film and carries it round in its revolution. At the upper part of the case, in which the discs revolve, 
 an air propeller is fixed, which sends a current of air past and through the spaces between the discs. This 
 leads to a rapid cooling of the disc and its water film, the heat absorbed by the water being in this way 
 dissipated. The action is one of evaporative cooling, of which many instances abound, and is very effective. 
 An equal weight of water will effectually condense any given volume of steam, and this quantity is not difficult 
 to find in most places. The results obtained by the Union Engineering Company in this country have been 
 satisfactory, and there appears to be no doubt as to the efficacy of the machine. Steadiness of rotation is a 
 sine qua non in mill engines, a very slight difference in their velocity having a great effect upon the work of 
 the mill. This is now attained in most cases with certainty, and by means of the Moscrop Recorder— an 
 instrument denoting graphically the changes of speed — a very salutary check is kept upon the engineer. In 
 order to prevent any variations occurring high-speed governors are largely employed, and in some cases their 
 action is aided by special means, such as Knowles's supplementary governor or Higginson's patent regulator. 
 Either of these appliances give good results, and the last named is very simple and effective. 
 
 (12) Up to within 15 or 20 years ago the most common mode of transmitting the power developed by the 
 steam engine was by means of toothed gearing. About that period the American method of driving by a series of 
 broad belts was introduced and for a time was largely adopted. When toothed gearing was used the power was 
 conveyed to the various flats or storeys of the mill by means of an upright shaft, on which were bevel wheels 
 gearing with others on the line shafts. The introduction of belt driving led to a system of transmitting the power 
 to the main shaft in each room independently of its fellows, and this system found further development when 
 driving by a series of ropes was adopted a short time afterwards. , In this case the power is taken off by a number 
 of ropes working in the grooves of a large pulley on the engine shaft and of smaller ones fixed on the line shafts. 
 This is now the favourite method of driving and is more extensively adopted than any other. The reason for this 
 is principally the ease with which breakdowns can be guarded against. If a rope breaks it falls into the race, and 
 
14) INTRODUCTORY. 
 
 in rare instances does it become entangled. It is only necessary to replace it, and any delay thus caused is 
 not great. 
 
 (13) As the question of driving is a somewhat important one a few remarks may be made on it. There is no 
 doubt that toothed gearing properly constructed forms the most economical method, the loss of power in trans- 
 mission not exceeding 2§ per cent. In constructing wheels for this purpose care should be taken that the 
 tooth is not too long, fths of the pitch being a sufficient length. Next to toothed wheels for economy belts 
 may be placed. The loss in transmission varies, if the belts are properly applied, from three to five per cent. 
 A good speed for leather belts is 3,000 feet per minute if they are single, and 4,000 feet if double. Hope 
 driving is the least economical of the three methods, this arising from a variety of causes. Chief among 
 these is the difficulty of maintaining an equal diameter in every rope of the series, which leads to a difference 
 in their driving power, owing to their unequal engagement with the V grooves. Another cause of this loss of 
 power is found in the fact that they jam in the grooves and have to be forcibly extracted as the pulleys 
 revolve. The following rules laid down by Mr. Alexander Rea in a discussion, at a meeting of the Manchester 
 Association of Engineers, on the subject of the comparative merits of the three systems of driving, are worth 
 reproducing. 
 
 " The ropes should not be too large in diameter ; it is much safer to use 25 If inch ropes than 20 
 2 inch diameter ropes. The tension in the several ropes should be kept as low as possible. The power should 
 be subdivided to different points. The centres of the several shafts should be kept well apart. The pulleys 
 should be large in diameter. The best speed for the ropes is from 4,000 to 6,000 feet per minute. Care 
 should be taken in turning the V groove pulleys j the best angle for these is now found to be 45 degrees." 
 
 (14) As this subject of rope driving is an interesting one, it is worth noting that Mr. George Goodfellow, 
 of Hyde, who has had a wide experience in this matter, confirms the advice as to small diameter of ropes. 
 In the same discussion he stated that he did not now use larger diameters than If inch, and had ropes running 
 successfully, the diameter of which was only 1£ inches. Mr. James Hartley also bore out this experience. 
 By the reduction of ropes from 2 inches to 1£ inches diameter the friction diagram from the engine had 
 been materially reduced, indicating a saving of power. Mr. J. H. Ratcliffe, of Dukinfield, has recently revived 
 a method by which, instead of using a series of ropes, he uses one only, this being endless, and being 
 wrapped spirally on the pulleys. At one point the slack is taken up by a compensating apparatus, so that 
 the whole of the coils are tight back and front instead of having one side slack and bellying. For this 
 arrangement Mr. Ratcliffe claims that it materially reduces the friction diagram, inasmuch as there is no 
 necessity to drag the rope forcibly out of the grooves at each revolution. It is not necessary for a detailed 
 examination of this subject to be made, bu the hints given will probably prove useful to many readers. 
 
 (15) It is essential, owing to the peculiar structure of the cotton fibre, to which reference will be made 
 in the next chapter, that the rooms in which spinning is conducted should be heated to a certain temperature. 
 Closely allied to this question is that of humidification. It is not only essential to have heat, but that must be 
 accompanied by a certain amount of moisture, a point which is often neglected. Spinning rooms are often heated 
 
INTRODUCTORY. 
 
 11 
 
 to over 90° F. } which is quite unnecessary, and is, moreover, detrimental to good work. At such a temperature 
 much of the natural moisture of the cotton is extracted, and the fibre becomes harsh and brittle. A tempera- 
 ture of from 75° to 80° R, with a humidity of about 75 per cent, is absolutely the best condition for spinning. 
 The question is an important one, and deserves greater consideration at the hands of spinners. The artificial heat 
 required is now obtained by the use of wrought-iron steam pipes, through which high-pressure steam is 
 passed. The radiation from these is much greater than from cast-iron pipes of larger diameter filled with 
 low-pressure steam. 
 
 (16) Having thus briefly glanced at some of the chief features of modern practice, it is now only necessary 
 to say that the utmost cleanliness is absolutely essential to good working. The manipulation of the cotton is now 
 so largely automatically performed that there is much less difficulty in keeping a mill clean than formerly. It 
 should be the aim of every spinner to diminish the handling of the material as much as possible, and students of 
 this subject should remember that it is never too early to begin to deal with the cotton so as to prepare it for 
 subsequent treatment. Efficient purification at an early stage is a great help towards economical and efficient 
 spinning. In conclusion, it may be remarked that one of the worst faults in studying a subject of this sort is any. 
 kind of crystallised thought. The conditions of work vary from day to day, and there are wise variations in 
 procedure which can easily be discovered by the observant mind. This watchful attitude is the proper one to 
 cultivate, and the succeeding pages are written in the hope that they will lead some reader to a deeper and closer 
 observation of the facts which are discoverable in the actual work of construction or spinning. 
 
CHAPTER II. 
 
 THE STRUCTURE OF COTTON. 
 
 (17) The cotton plant is indigenous to many tropical countries, in which it is often found in a wild state. The 
 product of the wild plant is, however, quite unsuitable for manufacturing purposes, and, even iu cases where cotton 
 is produced by cultivation, the value of the fibre varies very largely. Into the question of the growth and structure 
 of the fibre it is not necessary to go in detail, as this is a subject which has a literature of its own. The student 
 who is desirous of obtaining a thorough knowledge of the subject can find it fully treated in the " Structure of the 
 Cotton Fibre," by Dr. Bowman, and in a recent work by Mr. Hugh Monie, jun., of Glasgow. It will suffice for 
 present purposes to state briefly the characteristics of cotton, which are of essential importance in its subsequent 
 treatment mechanically. The cotton fibre is a hollow tube of cellular construction, and is of an oval or flattened 
 cylindrical shape. Ripe or fully matured fibres of the best cotton are convoluted or spirally twisted on their axis, 
 and the edge of such a fibre presents a corrugated appearance. The regularity of the convolutions, or twists, is 
 greatest in the highest class of cotton, and reaches its lowest point in the poorer grades. One important effect of 
 such a formation is that each fibre naturally tends to coil round its neighbour, and thus lends itself to spinning. 
 The outer sheath of each fibre is apparently continuous, and the diameter is greater at the end which is attached 
 to the seed. The diameter of the fibre varies from of an inch in the case of Sea Island cotton, to of an 
 inch in Indian cotton. In length a similar variation is observable, reaching a mean of 1*8 inch in Sea Island, 
 and being as low as 0"8 inch in Indian cotton. The length of the fibres in any particular class of cotton is 
 known as the "staple," and this is one of the chief commercial merits of the better kinds. The strength of cotton 
 fibres varies very materially, and on the authority of Mr. Charles O'Neill, of Manchester, the order in which 
 the various classes ought to be placed is as follows :— Surat (Comptah), New Orleans, Queensland, Surat 
 (Dhollerah), Pernambuco, Egyptian, Maranham, Upland, Sea Island. It does not necessarily follow that the 
 possession of greater strength by one class of fibre over another involves an advantage, for the greatest strength is 
 possessed by a fibre which is the most deficient in regularity of the convolute form and length, which are much 
 more important than strength. Again, the diameter of Comptah cotton is much greater than that of longer- 
 stapled varieties, and this is important in determining the value to be placed upon the strength. Viewed in 
 this light, Egyptian cotton is the strongest, and this fact, in conjunction with certain other qualities to which 
 attention will afterwards be called, renders it of high value. It only remains to be said that a waxy covering is 
 found on the outside of each fibre, which requires to be softened by heat during spinning so that the flexibility of 
 the fibre may be fully maintained. Where it is intended to dye fabrics it is necessary to remove the whole or the 
 greater part of this wax, and so permit the dye to penetrate the fibre. H iving briefly indicated the chief 
 characteristics of the cotton fibre, a detailed account of some of the principal varieties may now be given. 
 
THE STRUCTURE OF COTTON. 
 
 13 
 
 (18) Sea Island Cotton. This is the finest class of cotton produced, being long in the staple, very flexible, 
 and having very regular convolutions. If care be taken in ginning, so that the fibre is not broken, the finest 
 yarns can be produced from this variety. The length of Sea Island Cotton is stated by Dr. Bowman to 
 reach 2 -20 inches in the case of Florida grown, but Mr. Monie states the average length to be 1-8 inches. 
 Mr. Evan Leigh confirms the higher length, but only in the case of cotton grown on the Edisto. Island. Varieties 
 of this grade are grown in Peru, Fiji, and Australia, the average lengths being respectively 1-56, 1-87, 1-65 inches. 
 Fijian Sea Island is spoiled by bad ginning, which breaks the fibres very much. The colour of Sea Island cotton 
 is a light creamy one, and is peculiar to it. 
 
 (19) Egyptian Cotton. Egyptian cotton varies considerably in colour, length, and quality. The variety 
 known as Gallini is of a golden colour, the fibres being tough and strong, and the convulutions very regular. It 
 has a mean length of 1'5 inch. Brown Egyptian is, as its name implies, of that colour, and like Gallini, the fibres 
 are strong and tough, but are coarser, the convolutions are less regular, and the wall of the fibre is also 
 denser. The mean length is 1-4 inch and the diameter inch. White Egyptian is, perhaps, the most 
 valuable of all this class of cotton when properly treated. It is of a light gold colour, the fibres being 
 strong and pliable, but only partially spiral. As a result , of this, the yarn spun is greater in diameter than that 
 spun from Gallini (weights being equal), the fibres not lying so closely together. This cotton mixes well with 
 American and Brazilian. 
 
 (20) Brazilian and Peruvian Cotton. Pernambuco cotton is of a slightly golden colour, and is, compara- 
 tively speaking, hard and wiry, being thus well adapted for twist yarn. The twists in the fibre are well developed, 
 and the average length is 1-25 inch. Maranham is of a dull gold colour, mixing well with American cotton. 
 There are several other varieties of Brazilian cotton, which need not be further referred to. Kough Peruvian cotton 
 is very clean, of a creamy colour, and is possessed of an average strength. The fibres are only irregularly twisted, 
 and an average length is 1 3 inch. The smooth variety is fairly regularly convoluted, and mixes well with Orleans. 
 
 (21) American. There are several varieties of American cotton, which are grown in the Southern States. 
 Taking them in their order as regards length of staple, the first to notice is Orleans. The better classes of this 
 are very uniform in length, clean and light in colour, often being pure white. One feature of Orleans cotton 
 which renders it very acceptable to spinners, is that it is very flexible, and possessed of a high elasticity. In 
 addition to this, as has been previously noted, its strength is fairly great, and generally its spiral form is well de- 
 veloped. The average length is about 1 inch. Texas cotton is less pliable than Orleans, darker in colour, and is 
 not put on the market so free from immature fibre. Its diameter is greater, and its average length about equal to 
 Orleans. Upland cotton is clean, and little waste is produced from it. The fibres are well suited for weft 
 yarns, being soft and elastic, and of a very light colour. Spun without any admixture of other cotton, yarns as 
 high as 425's can be produced, but when mixed with Egyptian or some other strong fibre, higher counts can be 
 obtained. Mobile is similar in oolour to Orleans, and is equal to Uplands in strength. It is not so good as either 
 of these for manufacturing purposes, being much dirtier, and having more flattened fibres in it. 
 
 (22) Indian. The whole of the cottons grown in India are less valuable than the preceding varieties, owing 
 to the facts that they are not so regularly spiral, and that the staple is more variable. The highest class is 
 
14 
 
 THE STRUCTURE OF COTTON. 
 
 Hingunghat, which is more convolute than any other Indian grown cotton. The fibres vary in diameter, but have 
 an average length of 1 '03 inch. Broach is brownish gold in colour and is fairly clean, although it is not 
 thoroughly cleaned, and contains a good deal of leaf and nep. It is about 0'9 inch long, and is more regular in 
 this respect than Hingunghat. The spirals are fewer in number, and it is stated by Mr. Monie that the walls arc 
 very liable to rupture. Dhollerah is of a white colour, and is best adapted for weft yarn. Oomrawuttee is creamy 
 in colour, being strong but rather short in the staple. A good deal of impurity is found in this quality, but the 
 convolute form is moderately developed. Tinnivelly is grown in the Madras Presidency, and is a fairly good 
 cotton. In strength it is high and is very elastic, its colour being a dull, creamy one. The fibres have a small 
 bore and thick walls, and are, in addition, only slightly twisted. The worst Indian fibre is Bengal, which is short, 
 strong, and dirty. 
 
 (23) Commercial qualities. The recapitulation of the principal features of various growths of cotton just 
 given enables their relative value for spinning to be pointed out, and at the same time to indicate the qualities it 
 is desirable to retain during the subsequent mechanical treatment. Sea Island cotton is beyond doubt the finest 
 quality existing, and, in the manufacture of fine counts, is absolutely essential. Its general excellence is 
 undoubtedly attributable to the conditions under which it is grown, and even this might be improved by more 
 careful cultivation. Egyptian cotton is also of gi-eat value in the production of good yarns, and is very 
 largely used for this purpose. Owing to the existence of a number of short fibres, always found in commercial 
 quantities, but present here in larger proportion, it is necessary to comb all Egyptian cotton. The chief 
 advantage of its use is that being relatively stronger, smoother surfaced, and more flexible than qualities 
 other than Sea Island, a large range of yarns for various uses can be spun at a price which enables them 
 to be profitably used. The fibres are very regular in diameter, and when twisted lie very close together. 
 The most widely used cotton is, however, the various brands of American, which have the advantage of 
 careful attention during their growth and collection. In consequence of this, there is a very high uniformity 
 attained, together with great freedom from all sorts of impurities, these two qualities rendering American 
 cotton highly suited for general use. Indian cotton is coarser, harsher, and not so clean as other varieties, and 
 requires greater care in its manufacture. Summing up, the desirable points in cotton are the length and regular 
 convolute form of the fibre, together with its freedom from mechanical and chemical impurities. The object of the 
 earlier mechanical processes through which cotton passes is to remove all the impurities, lay the fibres regularly 
 and in equal numbers alongside each other, without breaking or rupturing them, and without destroying their 
 natural tendency to twist round each other. In doing this, not merely do the seeds, leaf, and sand require 
 removal, but also the short immature fibres which form into little knots or tangles called " neps." Great care is 
 needed in the preparatory stages so as to avoid damage, and it is especially necessary to avoid the removal 
 of the waxy sheath which plays an important part in the manufacture of the fibre. The necessity for a 
 warm, humid atmosphere has already been referred to, but it may be noted that it is very important on 
 account of its softening effect upon the waxy sheath. If the latter be removed the heat becomes a source of 
 difficulty instead of a help, as the natural moisture existing in the fibre is more speedily absorbed. 
 
CHAPTER III. 
 
 GINNING AND MIXING MACHINES. 
 
 (24) When the cotton is ready for harvesting it is picked from the shrubs by hand. There have been many 
 attempts to pick it by machinery, but these have not hitherto been very successful. After picking, it is subjected 
 to the action of a machine called a " gin," which is sometimes arranged to be worked by hand, but more often by power. 
 In the latter case the machines are placed in a shed, and the cotton is brought there for treatment. The object 
 of ginning is to remove from the cotton the seeds, which adhere closely to the fibre, and which have of late years 
 acquired considerable value for oil-producing purposes. In order to remove them it is necessary that the fibre 
 should be held in some way while it is submitted to a rubbing or scraping action, by which the seed is separated. 
 To effectually perform this function great care is required, as otherwise a quantity of the seed is broken, and the 
 fibres are rubbed up into " neps." If either of these effects is produced additional labour is thrown on the spinner 
 in his subsequent treatment, and it is therefore desirable to avoid such a manipulation of the machine as would 
 lead to so undesirable a result. 
 
 (25) In Figs. 1 and 2 a single Macarthy gin is illustrated in part sectional side elevation and front elevation. 
 This is a type which, in principle, is now largely adopted. It consists of a roller A, rotated in the direction 
 shown by the arrow, by means of a strap passing over a pulley fixed on the end of the roller shaft. The latter is 
 square, and is passed through the centre of the roller, fitting a corresponding hole in the latter, and being carried 
 by suitable bearings fixed on the machine frame. In constructing the roller A the following method is adopted. 
 Wood segments are fitted together so as to form the complete cylinder, or the latter may be made in one piece. 
 Having produced the body, it is fixed on the shaft, and is then turned quite round and parallel. Upon the 
 surface so prepared a thick covering of walrus leather B is fixed, in which spiral grooves are formed. The rough 
 surface of the leather, as the roller is revolving, seizes the cotton fibres as they are fed along the table F, which 
 has a grid G at its inner end, a special feed being sometimes fitted. When the fibres are drawn in by the roller 
 they are taken under a knife blade C, which is fixed above the roller by means of the sets of clamps D and E. 
 The clamps D bind the blade to its bearings, and those marked E are used to regulate its pressure on the roller A. 
 As the roller occasionally becomes hollow the wisdom of this procedure will be seen. A crank shaft is placed 
 and driven from the shaft of the roller, and gives a rapid reciprocating motion to a connecting rod I, which has at 
 its upper end a blade H. The height of the blade H is regulated by means of the adjustment of the connecting 
 rod strap, to which it is jointed, and which can be packed to any desired amount. The blade is coupled to radius 
 arms J, adjustable by nuts at their outer ends, and oscillating on a rod fixed below the feed-table. 
 
 (26) As the fibres are drawn under the upper blade C, the lower blade H pushes up the seeds, which cannot 
 pass between the roller and the blade C- In this way the seeds are freed from the fibre, which is carried forward 
 
16 
 
 GINNING AND MIXING MACHINES. 
 
 and thrown off at the front of the machine, or it may be stripped by a fixed blade. The setting of the blades C 
 and H should be arranged so that the necessary pressure is applied to the seeds to free them, but care must be 
 taken that the lower blade does not rise so high as to crush them. It should also be set relatively to the roller, 
 so as not to roll up the fibre by having close contact with either the roller or upper blade, while effectually removing 
 the seeds. Other forms of ginning machines are made, including one in which rollers formed of a number of saws 
 are employed, but their use is not so large as that of the Macarthy machine, which may be taken as typical. 
 
 (27) After the cotton is ginned, it is pressed in large hydraulic presses into bales of various sizes 
 and weights, ranging from 400 to 6001bs. each. Tn this form it is imported into this country, and delivered to 
 the mill-owners. The purchases of the material are made from samples of a few pounds taken from one or two 
 bales of a lot of the same brand, and it is essential in purchasing that not only the "staple" but the condition 
 
 in which the cotton is packed should be taken into account. In some seasons the percentage of moisture 
 is much higher than in others, and in wet seasons a large weight of adherent sand is certain to be found. This, 
 indeed, is the case always, but it is much greater after a bad season than when the weather is normal during 
 picking. The question of the delivered condition of the fibre is a very sore one commercially, as it results in 
 serious loss to the millowner, and there is little doubt that in many cases a fraudulent intermixture of sand is made. 
 
 (28) Whatever may be the condition in which the cotton is received, the first operation at the mill is to open 
 out the bale and break it up into pieces of a convenient size. For many years this was conducted purely as a 
 manual operation, but an arrangement which was made by Messrs. Piatt Bros, and Co., in 1855, and has been 
 working ever since, is shown in Fig. 3. This consists of a lattice feed table F, vshich delivers the cotton and 
 brings it into the range of action of an opener cylinder C. The latter opened the material to a considerable extent, 
 
 J.N. 
 
 Fig. 1. 
 
 Fig. 2. 
 
GINNING AND MIXING MACHINES. 
 
 17 
 
 and threw it on to a second lattice H, by which it wasdelivered to a" third one, and conveyed to the mixing stacks 
 in a manner to be afterwards described. The operation is now almost always carried out by a machine known as 
 a "bale breaker," a perspective view of which, as made by Messrs. Piatt Bros*, and Co. Limited, is shown in Fig. 4. 
 
 Fig. 3. 
 
 It consists of a feed table, placed between the projecting framework, and is usually of the lattice type. The 
 lattice feed apron consists of a number of narrow strips of wood fixed to two endless bands passing round rollers at 
 each end of a longitudinal frame fixed to the machine. By suitably driving one or both of the rollers a continuous 
 
 Fra 4. 
 
 motion is obtained, and the wood strips being each free from the other no difficulty is experienced in forming an 
 endless apron or feed table. The cotton is placed upon the table in large pieces or lumps, just as these are taken 
 from the bale, and they are carried forward until they come into contact with the first pair of rollers. There are 
 c 
 
18 
 
 GINNING AND MIXING MACHINES. 
 
 usually four pairs of rollers driven by means of the spur pinions shown in the illustrations. The first 
 pair are provided with coarsely-pitched blunt teeth or spikes, which seize the cotton and pass it onward 
 to the next pair, which are of similar construction. The last pair of rollers are usually made with coarse, longitu- 
 dinal corrugations, or flutes, as shown in Fig. 4, which deliver the cotton either on to the floor of the room, or onto 
 lattice aprons arranged as hereafter noted. The top rollers are weighted by helical springs in the manner shown, 
 and can easily yield if any obstruction or unusually large piecs of material passes between them. The speed of the 
 rollers increases rapidly, but there is a divergence of opinion as to the proportion of increase over the whole series. 
 It will be well, therefore, at this point to state the conditions of the case fully. 
 
 (29) Before doing so, however, it is necessary to explain a term which even at this early stage is used, 
 and which is a common one throughout the whole series of operations constituting spinning. The variation 
 in the speed of the rollers of the bale breaker is known as its " draught." In other words, an elongation or 
 enlargement of the bulk of the cotton occurs in exact proportion to the velocity of the rollers. Thus, if the 
 relative speed of the first and last of the series of rollers is as 1 : 30, the draught of the machine is the same. 
 In the case of the bale breaker the draught results merely in an increase in the bulk of the cotton, but 
 subsequently it leads to an elongation of the sheet or sliver into which it is formed. 
 
 (30) It being highly desirable that the naturally open fleecy condition of the cotton shall be restored at the 
 earliest moment, the question arises, What shall be the draught of the bale breaker rollers ] Is it necessary 
 to do more than break up the lumps of cotton into smaller pieces, which can be readily treated by the 
 subsequent machines? To these questions different answers are given. On the one hand, it is contended 
 that what is required is to reproduce the conditions of hand breaking, by which the cotton was pulled from 
 the bales in small tufts ready for delivery to the opening machinery. Another practice advocated is to so 
 pull the lumps into which the bale is broken up that the cotton when delivered is in an open fleecy condition. 
 It would be preferred by spinners if they could obtain the cotton in the loosely packed condition in 
 which it is received by the Indian spinners, for instance. As this cannot be done, owing to commercial and 
 transit considerations, the question arises whether the first stage in the processes conducted in this country 
 is not the right one to restore this condition. 
 
 (31) Between the two positions formulated there is a wide divergence, but, to the author, the latter appears 
 to possess the balance of advantage. There can be no doubt that the preparation of the fibre cannot be com- 
 menced at too early a stage, and, as efficient cleansing is one of the first objects to be attainel, it follows that the 
 earlier the open condition of the cotton is reached the more readily can cleaning be effected. It must not be for- 
 gotten that care is necessary to avoid possible damage to the fibres, but, with rollers properly speeded, there 
 appears to be no reason to expect such a result. 
 
 (32) In consequence of the divergent views held, the draught of a bale breaker varies considerably. In some 
 cases it is only 2 : 1, while in others it reaches 30 : 1. The former is the rule adopted by Messrs. Crighton and 
 Sons, who advocate the first course named, and the latter that adopted by Messrs. Lord Brothers, who prefer the 
 second. Messrs. Piatt Brothers and Company recommend a wise variation in this respect, proceeding upon the 
 
GINNING AND MIXING MACHINES. 
 
 19 
 
 principle that different staples require different treatment. Thus one machine made by them has four rollers with 
 a large draught, this being used for good staples, and producing as much as 90,0001bs. weight in 50 hours. In 
 dealing with Surat cotton, which is more hardly pressed, two sets of rollers are used, followed by a beating cylinder 
 by which the cotton is thoroughly broken up (Fig. 8). In each case it is customary to attach lattices to the 
 machine, by which the cotton is carried forward and deposited in the mixing bins (E Fig. 13). (See also Figs. 6, 7, 
 and 8). Another method is to treat Surat cotton by first passing it through breaker rollers, and thence through a 
 Crighton cylinder, described in Chapter IV. The bale breaker may in this case be used either singly or as 
 part of the combination. 
 
 (33) The rollers are made in two ways. They are cast in one piece and are mounted upon the shaft; or are 
 built up from a number of discs threaded and fastened upon the shaft and bolted together. The latter is the pre- 
 ferable course, the breakage of a few teeth being easily remedied. 
 
 Fig. 5. 
 
 (34) Before proceeding further, reference may be made to Fig. 5, which is a transverse section of the machine 
 as made by Messrs. Dobson and Barlow. The top rollers of the machine, as ordinarily made, are provided with 
 spring weighting, in order to permit them to rise if an unusually large piece of cotton is passed between them. If 
 this enters at one side of the machine it will be at once seen that the roller will be raised at that side, and 
 that its axis will be angularly disposed to that of the bottom roller. The two rollers will only be near each 
 other at one side, and between them, across the whole of the width of the machine, will be a gradually increasing 
 space through which lumps of cotton can pass uupulled. This is a defect of more or less magnitude, but is one 
 which is ingeniously remedied in the machine shown in Fig. 5. Only one line of rollers, marked U V Y Z, is used, 
 
20 
 
 GINNING AND MIXING MACHINES. 
 
 by two of which the pulling is effected. Below these the noses of iron bars or levers, Q R, fulcrumed on knife 
 edges, are placed. The bars are a few inches wide, and extend below the rollers over their entire width. The 
 cotton passes over these "pedal" levers, which are weightel at their other end, and yield, as shown by the dotted 
 lines, when an extra large piece of cotton passes. The weight is sufficient to enable the cotton to be held until it is 
 pulled by the roller. It will be at once seen that only the pedals affected by the lump will be depressed, the 
 remainder occupying their normal relative position to the roller, which is fixed by the stop shown. In this way 
 the presence of a thick piece at one point in the width of the rollers does not affect the pulling at another point. 
 
 mm *i 3 
 
 
 
 
 
 J . N. 
 
 Fig. 6. 
 
 (35) The cotton being pulled, it is necessary to mix it. This is effected by delivering it upon a second lattice, 
 B Fig. 13, which can be made of any desired length, and by which the cotton can be delivered onto a third lattice 
 C running transversely or in any other direction. Three such arrangements— the sketches supplied by Messrs. 
 
 r. 7. 
 
 Piatt Bros, and Company— are shown in Figs. 6, 7, and 8, but there is practically no limit to them. By 
 means of these devices as much as 90,0001bs. weight can be laid down per wedk by two workmen. To avoid the 
 risk of fire, the flutes are so arranged as not to come into contact, but it is advisable to place the 
 machine in a building removed, if possible, from the main structure. 
 
OPENING AND MIXING MACHINES. 
 
 21 
 
 (36) Having broken up the bale as described, the cotton is in a condition to be mixed. This operation is one 
 of the most important in the economy of a cotton mill, and on its judicious and thorough accomplishment depends 
 very often the production of a profit or loss. In order to obtain the best possible yarn the longest-stapled cotton 
 should be used, and should be selected so that the fibres, when spun, are as nearly as possible of one length. By 
 careful selection a practically perfect yarn can be produced, but it would naturally be a dear one. It is, however, 
 possible to apply the same principle in the production of cheaper qualities of yai-n. Briefly stated, the principle 
 is, that to spin a good yarn it is necessary to U3e cotton in which the fibres are of approximately the same length 
 The longer the "staple" of the cotton the better the yarn ; but, even when short staples are used, this selection 
 is still essential to success. This does not necessarily mean that the same grade of cotton should be used 
 exclusively, but, on the contrary, several can be mixed, provided that the staples are equal, even if they are not of 
 the same commercial value, and differ in other characteristics. By a careful selection of cotton a mixture can be 
 obtained from which a good even yarn of fair strength can be spun, the cost of which would be lower than it would 
 be if a single good grade only was used. 
 
 J.N. 
 
 Fig. 8. 
 
 (37) It is the practice in making a mixing to place round the breaker bales of the various grades which 
 are to compose it. The attendant takes a layer from each bale in succession, and places it on the feed 
 lattice of the bale breaker, by which it is broken and partially mixed, so that when stacked the elements 
 of the mixing are well incorporated. The size of the stack depends very largely on the requirements of the 
 spinner, but as most mills now are employed on a small range of counts, some of them on one or two, it is 
 most usual to make a large one containing sufficient cotton to last for several weeks. By pursuing this 
 course there is a very much better chance of getting a regular quality of yarn, which is essential to the 
 commercial success of the mill. In taking cotton from the heap it is the best plan to begin at 
 the top of the face and work downwards in a straight line, as by this procedure a uniform 
 quantity of the different elements in the mixing is obtained. It is desirable to make a small 
 stack of the same classes of cotton as the larger one is to be composed of, and in the same 
 proportion. By passing this through the various machines a test can be made of its yarn producing 
 qualities, and the mixture of the larger stack can be varied so as to remedy any defects discovered in the 
 smaller one. It is impossible to lay down any definite rule as to mixings, the production of which is a matter of 
 experience, and can only be arrived successfully at in that way. Not only must the strength and cost of the yarn 
 
22 
 
 GINNING AND MIXING MACHINES. 
 
 be considered, but also its colour, and it is for this reason essential that a thorough knowledge of the structure and 
 characteristics of various growths should be acquired in addition to one of commercial values. 
 
 (38) It will be easily seen, when the operations of the various machines employed in cotton spinning are 
 considered, how essential it is that the fibres in a mixing should be approximately equal in length. Unless 
 this condition is observed there is likely to be a good deal of loss from fly in the carding engine, and the 
 slivers in the drawing frame would tend to have the long fibres in the centre and the short ones on the 
 surface, owing to the difficulty experienced in drawing different lengths with the same setting of rollers. These 
 remarks are, of course, only relatively true, as it is possible to mix different staples economically, but the 
 process is a difficult one. For instance, in the scutching room, laps, each consisting of cotton of different 
 staples, can be fed simultaneously on the same lattice, and so produce a lap of the mixed staples. It is 
 found to give the best results when the laps are made on the opener and mixed on the intermediate scutcher 
 in the proportion required. By these means a better mixing is obtained than if the laps are put on the 
 finishing scutchor only. Individual experience is the guide to a thorough comprehension of this 
 department of spinning, and beyond enunciating these general principles no aid can be given to the student 
 which is likely to be of value. The actual condition of even the same class of cotton, in different seasons, 
 varies so largely that a mixture which is valuable one season is unsuitable in the next. 
 
CHAPTER IV. 
 
 THE OPENING MACHINE. 
 
 (39) Mixing being completed, the cotton is treated by machines specially designed to remove the impurities 
 which are always mixed with it as received from the shipper. These impurities include sand, dirt, broken 
 seed, and leaf. In addition to these there is a certain quantity of " nep " which is caused, as previously 
 described, by the matting together of short, unripe, or immature fibres. To eliminate the whole of these 
 substances, two sets of machines are required ; the first being responsible for the removal of the heavier 
 foreign bodies, such as sand and dirt, and the second for that of leaf, nep, and short fibres. 
 
 (40) Of the machines in the first division the opening machine, or more briefly the " opener," is the first. 
 Its raison d'etre is found in the matted condition of the cotton as taken from the bale, and the less open it 
 is when taken from the stack, the greater the work of the machine. As the name indicates, the object of 
 the latter is to disentangle the fibres, but it is also designed to remove many of the impurities held by the cotton. 
 This twofold aim is the one with which all the series of cleaning machines are constructed. 
 
 (41) The method invariably pursued in opening is to beat the cotton by subjecting it to the blows of arms 
 revolving with considerable velocity. It may aid in the understanding of the process, if a few words are said as 
 to the primitive method of cleaning. Formerly the material was laid upon grids in small quantities, and 
 was submitted to repeated light blows of rods or sticks delivered manually. In this way the mass was gradually 
 beaten into a fleecy condition, and the dirt held by it dropped through the interstices of the grid. In some 
 respects, this treatment has never been equalled, but it is, of necessity, very slow, and could not be commercially 
 employed at the present day. At the same time, it affords a clear indication of the needs of the case, and 
 is a guide to the proper treatment. 
 
 (42) In dealing with the fibre by revolving beaters of any kind, two things are essential to success. 
 First, the blow given must be of such a character that the fibres are completely separated, while any rupture 
 or breakage of them is avoided. Second, the surface against which the cotton is flung after being struck by 
 the beater, must be arranged to permit of the free passage of all impurities, while, at the same time, so 
 arresting the movement of the tufts or pieces of cotton as to shake out the extraneous substances. 
 
 (43) The direction in which the cotton enters the machine, the diameter, construction, and shape of the 
 beater arm, and the speed of the beater, are three of the essential features of a machine of this kind. The 
 successful removal of the impurities depends on the rate of the feed — that is, the amount of material passed 
 into the machine in a given time — the shape of the projections on the casing surrounding the beater, and 
 the distance of these from each other; in other words, their pitch. It is not a difficult matter to effectually 
 
24 
 
 THE OPENING MACHINE. 
 
 cleanse the cotton, so long as regard is not paid to the loss arising from damaged or broken fibres, or from 
 the amount of fibre driven out with the dirt. It is, however, always to be remembered that it is desirable 
 in any process to utilise every portion of the material which is capable of being worked up, aud herein lies 
 the chief difficulty of the subject. In brief, the essential consideration is a commercial one, and that machine 
 is the best, and is used most skilfully, which effectually opens the matted cotton and shakes out the largest body of 
 impurities with the least loss of fibre, either from its being driven out with the dirt or by breakage or rupture. 
 Economy and efficiency are the watchwords of a good spinner, and nowhere is this combination more desirable 
 than in the early stages of the manufacture. 
 
 (44) There are three principal forms of machine used for the purpose of opening — the Oldham Willow, 
 the Porcupine, and the Crighton Opener. The former is now employed rarely for cotton, but extensively for 
 the manufacture of yarn from waste. The other two are often employed, but the Crighton type of machine 
 is perhaps more widely used than any other. There is another type of machine, which is also in extensive 
 employment, to which reference should be made, viz., a modified opener, on the Willow model, of which a 
 description will be given. 
 
 (45) The Willow is constructed with a revolving cylinder, about forty inches wide and the same diameter, 
 fixed on a shaft borne by suitable pedestals. It is provided with several rows of blunt teeth on its periphery. 
 Above the cylinder a so mi-circular casing is fixed, which is provided with similar projections to those of the 
 cylinder. Below the latter a grating, grid, or " undercasing," formed of a number of parallel bars, is placed. 
 The cotton is flung against these bars, and the loosened dirt falls through the spaces between them, being 
 drawn away by an exhaust fan and delivered outside the room. It is the usual practice to feed the machine 
 by an endless lattice, or apron, of a similar construction to that previously described. When the cotton enters 
 the machine it is struck by the teeth on the cylinder and thrown forcibly against the projections on the casing. 
 The blow thus given, combined with the periodical arrest of its motion, causes the cotton to be thoroughly 
 opened and shaken, the dirt falling downwards and being drawn away by the air current. As has been said, 
 the Willow is falling into disfavour. The cotton is subjected to too severe punishment, and is therefore 
 damaged. In addition to this, it is sometimes carried round several times, and is formed into a sort of rope, 
 which reuders its subsequent treatment more difficult. Moreover, the waste is greater than is desirable, and, 
 generally speaking, the use of this machine for cotton is of doubtful utility. 
 
 (46) In Fig. 9 a longitudinal section of an opener, which in some respects is a modified type of willow, is 
 illustrated. This machine is made by Messrs. Taylor, Lang and Co., Limited. It consists of a feed lattice Q, 
 which travels in the direction of the arrow, aud delivers the cotton to the pair of feed rollers shown. These 
 are duplicated when no regulating apparatus is used, and are three inches in diameter. The cotton is 
 delivered at any desired speed by the rollers, and as it projects from them is struck by the spikes or teeth on 
 the cylinder O, which revolves in the direction shown by the arrow. Surrounding the cylinder is a case P, the 
 inner surface of which has a number of projecting nogs formed on it, against which the cotton is flung with con- 
 siderable force. This shakes out the dirt to a great extent, and opens the material. After passing the casing P 
 
THE OPENING MACHINE. 
 
 25 
 
 the cotton is taken over a circular grid surrounding one side of the cylinder, and contained in the body of the 
 machine. This grid is formed of a number of steel bars, between each pair of which an opening is left. Thus as 
 the disentangled cotton passes over it the heavy dirt falls out through the openings into a space left for the pur- 
 pose. After passing the grid the material leaves the cylinder by the passage shown, immediately on entering 
 which it travels over the top of fixed grids R, through which the sand and similar material can fall, After this 
 the cotton is either delivered into the room or is carried forward to a pair of " cages " S, through which a current 
 
 Fig. 9. 
 
 of air is drawn. This part of the machine will be described in the next chapter, and it is only necessary to say that 
 the fleece of cotton is formed into a sheet and rolled up as shown at L ; into a " lap." If the cotton is delivered 
 loose it is thrown on to a second lattice, by which the delivery is made. In order to secure a regulation of the air 
 current the louvre openings I are provided. The area of the cleansing surface in this machine is great, and 50,0001bs. 
 of cotton can be cleaned in a week of 60 hours unless a "lap" is formed, when the quantitity is reduced to 
 28,0001bs. 
 
 Fig. 10. 
 
 (47) In Fig. 10 is illustrated, al so iu longitudinal elevation, a machine made by Messrs, Dobson and Barlow. 
 The cotton is fed by a lattice L, as in the preceding example, the course of which is clearly shown. In this case 
 the machine is fitted with pedal levers V, these being employed to regulate the feed, This motion and its method 
 
26 
 
 THE OPENING MACHINE 
 
 of action will be described at length in the next chapter. It suffices to say that the cotton on issuing from the 
 feed roller is struck by teeth or projections on the surface of the cylinder O which revolves from left to right. 
 Surrounding the latter is a semi-circular grid K with conical teeth, which encircles the cylinder for more than half 
 its circumference, through which the dirt is thrown, the cotton being cleaned by these means. It will be 
 noticed that in this machine the area of the circular grid K is large, and that the material at once passes upon it 
 after it is struck by the cylinder. As soon as the cotton leaves the surface of K it is carried forward over the grid 
 
 J.N. 
 
 Fig. 11. 
 
 U, placed in a position well c-tlculated to allow of the easy movement of the material, and by means of which the 
 removal of the dirt and sand is more easily effected. The grid U is also made of considerable area, so as to afford a 
 large cleaning surface, which is a desideratum in this class of machine. After leaving U the cotton is collected on 
 the cages D, and subsequently passed through the scutching machine, which in this case is combined with the 
 opener. As this machine is used as a separate one, it will be better to leave its description until it is dealt 
 with by itself. It is only necessary to say that it will be shown by numerous examples that the whole of the 
 
 J.N 
 
 Fig. 12. 
 
 cleaning machines are often combined in various ways, which are arranged to suit the special circumstances of any 
 case. These are so different that the combinations are widely diverse. 
 
 (48) The Porcupine opener is so named from the employment of a cylinder or beater consisting of a number 
 of teeth spikes or blades. Two forms of the beater, as made by Messrs. Lord Brothers, are shown respectively in 
 Figs. 11 and 12. The form shown in Fig. 11 is intended for use in cleaning long-stapled cotton, and consists of a 
 number of discs secured to a central shaft. To these steel blades are bolted, which are so shaped that they 
 
THE OPENING MACHINE. 
 
 27 
 
 can be reversed when worn. The beater illustrated in Fig. 12 is formed of a number of cast-iron discs, each 
 of which is hollowed on one side, and has a projecting flange or boss on the other. These are turned to fit one 
 another, and are bolted together by long screws. They are further bound by a nut fitting on a screwed part at 
 one end of the shaft, by which they are pressed against a collar at the other end. The teeth are V shaped and 
 are chilled, being readily sharpened after wear. In the event of the teeth of one of the discs being broken, it is 
 only necessary to remove it by breaking it up. An additional disc can then be put on the end of the shaft, 
 and the whole screwed up again as at first. In this way the whole of the advantages of a solid roller are secured, 
 with much greater facilities for repair. 
 
 (49) However the cylinder is constructed it is sustained by bearings secured to the framing of the machine. 
 Beneath it a grating or grid is fixed, similar in construction to those previously described. The bars are in 
 all cases shaped so as to present a sharp angle to the cotton as it is thrown forward by the cylinder. A dirt 
 chamber is, as usual, formed below the grid. The cotton is fed by a lattice and feed rollers. The latter are 
 
 
 
 
 
 K 
 
 
 
 
 
 
 J • N 
 
 Fig. 13. 
 
 formed in the ordinary way, with a number of circumferential V grooves, crossed by a series of similar longi- 
 tudinal grooves, so as to form a large number of teeth, which securely hold the material as it is fed. As 
 the cylinder revolves 1,000 times per minute, the teeth strike the cotton and disentangle the fibres, throwing 
 them with considerable force against the grid. 
 
 (50) Although the Porcupine opener can be used separately and the cotton discharged into the room, it 
 is more usually employed in connection with some other type of opener, or with a scutching machine. 
 Formerly it was a common practice to use this machine separately, in which case it was fitted with two 
 cylinders one behind the other. Now it is mostly employed as a feeder to another machine, and the combination 
 gives very effective cleaning. 
 
 (51) Such an arrangement is shown in Fig. 13, which is a special one of Messrs. Piatt -Bros, and Co. 
 The lattice feed F is placed alongside the mixing bins, and is provided with a large collecting roller, 
 
28 
 
 THE OPENING MACHINE. 
 
 behind which are a series of pedals, described in the next chapter, and two pairs of breaker cylinders. By 
 these the cotton is fed regularly and broken up into small pieces, or partially opened before being passed 
 forward to the opener cylinder. The Porcupine feed rollers G deliver the cotton, in the case illustrated, into 
 the air tubes D, and thence over a patent dust trunk K, where much of the dirt is deposited, and which 
 is afterwards described. 
 
 (52) The opener, as made by Messrs. Piatt Brothers and Co., Limited, is shown in perspective in Fig. 14. 
 The cotton enters the opener chamber by the tube, as described, and is at once acted on by the cylinder, 
 which revolves horizontally. The cylinder is surrounded by grids, against which the cotton is thrown, and 
 through which the dirt is ejected. The forward movement of the cotton is induced by the exhaustion of the 
 air, produced by means of a pair of fans, placed one at each side of the machine and adjoining the exit orifice 
 
 Fig. 14. 
 
 from the cylinder chamber. Power of lateral adjustment is given to these fans, so that they may be set in 
 towards the centre of the machine to a greater or less extent. In this way the stream of cotton, as it issues 
 from the cylinder, is directed on to the cages as required, and a very even lap or sheet is thus obtained. It 
 is obvious that the guiding power of the air current is the right thing to rely upon, and, by the arrangement 
 described, ample regulation of it is obtained. A lap which is even in thickness is absolutely essential to good 
 work, and the arrangement of fans in the way described ensures this being obtained. The author recently 
 saw the first lap made on a machine of this type in a large Oldham spinning mill, and the regularity of 
 the thickness and evenness of the selvedge was very noticeable. The machine as shown in Fig. 14 is a 
 combined one. 
 
THE OPENING MACHINE. 
 
 29 
 
 (53) The Crighton Opener is a machine the distinctive feature of which is the employment of a vertical 
 conical beater. A sectional elevation of the machine as made by Messrs. Crighton and Sous is shown in 
 Fig. 15. The beater consists of a number of cast-iron discs D securely keyed upon a vertical shaft, which 
 is sustained at its lower end by a bearing E in the frame F, and at its upper end by the bearing A. On 
 the d iscs are fastened steel blades, and it will be noticed that their diameter increases from 18in. to 33in. 
 Surrounding the beater is a casing B, in which are a number of longitudinal slots, the inner surface of the 
 grids being in most cases made of the shape shown in section in Fig. 16. A recent improvement by Messrs. 
 Crighton and Sons is shown in Figs. 17, 18, and 19. 
 
 Fig. 15. Fig. 17. 
 
 (54) The cotton is fed by the tube placed at C, and a fan is fixed just below the entrance of the tube into 
 the beater chamber. The direction in which the cotton enters and the positions of the fans are important points 
 of construction. The feed tube is not fixed in a straight line, but is slightly curved so as to direct the cotton up- 
 ward as it enters the beater chamber. As it enters it comes in contact with the serrated surface of a truncated 
 conical dish, within which the lowest arm D of the beater revolves. Immediately below this dish a fan disc of the 
 Schiele type is fixed in machines in which a combination of feed table, air trunks, and opener is made. The object of 
 this fan is to exhaust the air in the tubes up to that point, and draw the cotton forward until it reaches the 
 cylinder. There is a decided advantage in this arrangement over one in which the fan is placed beyond the exit 
 orifice at the top of the opener chamber. In the latter case the air is required to draw the cotton through the dust 
 trunks into the opener, upwards past the cylinder, and so on to the cages. In the machine as made by Messrs. 
 
30 
 
 THE OPENING MACHINE. 
 
 Crighton, the fan at the bottom of the dish is sufficient to bring the cotton to that point, and all that is subse- 
 quently required of the fans placed beyond the cylinder is to lift the cotton upwards during its progress through 
 the beater chamber. On this account a slower moving current of air can be employed, and the fans connected 
 with the cages can be revolved at a less velocity. The full advantages of this arrangement will be afterwards 
 pointed out, but as the cotton is raised slowly while being beaten, it is thoroughly opened and cleaned. 
 
 (55) When the cotton enters the beater chamber it is at once struck by the blades of the beater, which 
 revolve at a speed of about 1,000 turns per minute. The peripheral velocity of the blades is thus at the bottom 
 4,712 feet per minute, and at the top 8,639 feet. The blow thus given disentangles the cotton and flings it 
 against the inner surface of the grid, thus momentarily arresting its motion. As the beater revolves, the cotton 
 
 Fig. 16. 
 
 Fia. 19. 
 
 continues to find its way upwards, and in its course is repeatedly struck by the blades, which, as has been seen, 
 have a continually increasing peripheral velocity as they near the top. In this way, as the cotton nears the exit 
 orifice, which is placed at the upper part of the machine frame/on the opposite side to the tube C, it is thoroughly 
 beaten into a fleecy condition, with its fibres well disentangled. 
 
 (56) The shape of the grids surrounding the cylinder is an important matter. In the form illustrated 
 in Fig. 16, the projections on the grid are triangular in shape, and have slots between each pair through 
 Which the dirt can freely pass. It will be easily seen that the shape of these grids is one which will only 
 exercise a little clinging effect upon the cotton, which, as it is impelled by the stroke of the beating blade, 
 will very readily roll pass the projections. As the rapid rotation of the cylinder tends to slightly compress 
 the air, the latter finds an outlet if possibK This is the object of the slots in the grid casing, and they 
 
THE OPENING MACHINE. 
 
 31 
 
 fulfil it very well. But there is always a liability that along with the air and dirt — which also passes the 
 grids— a little fibre may escape. It is desirable to avoid "fat droppings" as they are called, and the grid shown 
 in Figs. 17 to 19 has been designed for this purpose. Each of the pockets C Fig. 18 shown becomes a resting 
 place for the opened fibre, and as its lower end C 2 is open, the dirt can fall freely. In order that the air can 
 easily get away, between each pair of pockets a small slot is formed, and in this way there is no downward 
 impulse given to the cotton while held in the pocket. Thus each blow given to the material opens it, drives 
 it into the pockets where it dwells for a short time, and from which after the passage of the beater blade A, 
 it is drawn by the suction of the air. By this system there are given short periods of rest, which very 
 materially facilitate the fall of the dirt. 
 
 (57) Instead of feeding the opener manually as shown in Fig. 15, a lattice feed can be adopted. Among 
 the many important points in connection with the Crighton, or, as it is sometimes called, the " exhaust " opener, 
 none is more so thin the construction and lubrication of the footstep. This is arranged so that the foot of 
 the beater shaft revolves in a constant bath, eithsr of oil or water, and great care is taken to cover it so as 
 to prevent the entrance of sediment or dust. 
 
 (58) In Fig. 20, a longitudinal section of the machine as made by Messrs. Lord Bros., is given, and is 
 accompanied by a plan of the same machine as combined with a porcupine feed. Referring first to the plan, 
 the lattice feed A delivers the cotton to the porcupine roller C, by which it is passed in a partially opened 
 condition to the air trunks D. By these it i3 conducted to the opening chamber F, being admitted to it by 
 flap valves G- The cotton enters the chamber F by the tube H, terminating in the dish I. The exit orifice 
 is placed at the top of the chamber F, the course of the cotton being shown by the arrows. The cylinder 
 is similar to the Crighton, but the blades E are fixed in malleable iron arms L fastened to the shaft, and 
 can, after wear, be reversed. Below the foot of the shaft, and within the bearing O, is a loose washer P, which 
 can rotate with the pressure of the shaft, this arrangement considerably lessening the wear. At each side of 
 the exit of the delivery tube, fans N are fixed, which, like those in the Piatt machine, can be adjusted side- 
 ways for the same object. The cotton then passes over grids R on to the cages T, from whence it passes 
 through the scutching beater W to another pair of cages S, as indicated by the arrows, and is finally formed into 
 a lap as shown. The special construction of the beaters enables the cotton to pass freely upwards, and prevents 
 any stringing occurring. The speed of the beater in this machine is 520 revolutions per minute for American 
 cotton, and 720 for Indian. The slower velocities used necessarily imply the use of less power. 
 
 (59) There are one or two points to be noticed in concluding the consideration of the Crighton type of machine. 
 The distance from the face of the grids to the ends of the beater blades should be carefully arranged to suit the 
 class of cotton treated, as, if it is too great, the opening is not properly effected, and, if too little, the cotton is 
 liable to be damaged. The rate at which the feed is conducted should always be carefully watched, because, if the 
 material is passed in too quickly, its bulk becomes so great in the lower part that the dirt cannot fall freely, but 
 is received by the entering cotton. Cleaning is not, therefore, so effectually carried out. In addition to this, it is 
 desirable that the cotton should be allowed to assume a perfectly open condition, which it would do with difficulty 
 
32 
 
 THE OPENING MACHINE. 
 
 if the space were overfilled. Cotton has been passed through, for a short time, at the rate of 110,0001bs. per week 
 of 60 hours, but for the reasons stated, 30,0001bs. is ample. 
 
 (60) It might be thought that the pitch of the projections on the inner surface of the grid should be as small 
 as possible, but this is a mistake. It is essential that the cotton should strike not merely the top or apex, but one 
 face or side of the projection, if the full cleaning effect is to be obtained. It is obvious that if the pitch is too 
 fine no such face blow would be given, and very inefficient purification would occur. The considerations thus 
 stated are founded on actual experience in working the machines, and should be borne in mind in construct- 
 ing or controlling an opener of this type. 
 
 (61) It is considered by some makers to be advisable when using this style of machine to employ one with two 
 beaters revolving in separate chambers, connected to each other by an air pipe. This is more especially the case 
 when Indian or short stapled cotton is used. When the double machine is used, the conducting tube between the 
 two leaves the first chamber at the top, and enters the second at the bottom. The driving of the opening machine 
 is usually obtained from a counter shaft, by which means the speed of the driving pulley becomes a moderate one. 
 
 (62) A machine, of which large numbers have been made by Messrs. Lord Brothers and Howard and 
 Bullough, has a conical beater placed in a horizontal position, and the opener proper is usually combined with a 
 scutching and lap machine. As this type of machine is very similar in its general principles to that previously 
 described, and is not now. so largely made as formerly, it is not necessary to give a detailed description of its 
 mechanism. 
 
 (63) It has been repeatedly stated that the various machines are united by means of tubes, so that the 
 cotton can readily be taken from one machine to another. It does not matter whether the midlines are in 
 the same room or not, or what distances separate the rooms in which they are placed. This has been shown 
 in Figs. 6, 7, and 8, referred to in the preceding chapter, and the further arrangement is illustrated in Fig. 13. 
 In this case the cotton, after being delivered into the dust trunk, or tube D, on its way to the opening 
 cylinder, may be carried two or three hundred yards, if desired, before it reaches the latter. There is, of 
 course, a limit to the distance it may be conveyed, but it is a very wide one. There are many conveniences 
 arising from this procedure. It is becoming a very common practice to build the mixing and scutching rooms 
 away from the main body of the mill in order to minimise the risk of fire. But even where this practice 
 does not obtain, the employment of air tubes is a good one, as it enables the material to be transferred from 
 one point to another without handling. In this way the cost of labour is much reduced, and in addition the 
 cotton is less liable to damage. 
 
 (64) At one portion K of the conducting tube D an arrangement is fitted by which a partial cleansing 
 of the cotton occurs before it reaches the opener. Below the level of the tube a chamber nearly square in 
 section is formed, as shown in section at the left-hand corner in Fig. 20, forming the tube into a D shape. 
 This chamber is made of a length which is determined by the character of the material used and considerations 
 of its position, etc. At intervals of a few inches plates are arranged so as to divide the chamber into a 
 number of compartments, as shown by the sectional view. Over the top of these plates the material rolls 
 
THE OPENING MACHINE. 
 
 33 
 
 in its forward movement, and a large quantity of dust, sand, and heavy impurities are deposited in the trunk. 
 Doors are fitted to the underside of the chamber, by which the droppings can be removed at intervals as 
 desired. The use of these grids has been attended with unmistakeable benefit, and leads to a much more 
 effective cleaning of the cotton. 
 
 (65) By the method just described it is necessary to cleanse the trunks manually at intervals, and if any 
 neglect occurs there is some danger of the dirt being carried forward. To obviate this, Messrs. Piatt Bros, and Co. 
 Limited have patented and applied the arrangement shown in Fig. 21. In this case the dust chamber L is sus- 
 
 Fig. 20. 
 
 tained in a manner arranged to suit the circumstances of the case. Instead of being fitted with the vertical plates 
 described, au endless band is carried over two drums, one at each end of the chamber. This band K is driven 
 from the pulley shown by means of worm gear, and receives a traverse at its top side in the reverse direction to 
 the air current. On the band are fitted a number of blades or teeth, between which the dust or dirt can fall. The 
 traverse of the lattice carries the dirt forward, and when the teeth are turned downward it falls into the spout or 
 receptacle N, and on to the top of an iron flap P, usually kept in a horizontal position by the balanced lever fitted 
 
 D 
 
34 
 
 THE OPENING MACHINE. 
 
 on the spindle on which the flap oscillates. The collection of a sufficient quantity of dirt destroys the equilibrium 
 and causes the flap to tip, allowing the dirt to fall into a sack suspended below the orifice to receive it. In the 
 event of any dirt falling on to the bottom of the chamber, two or three special blades are arranged to scrape 
 
 J.N. 
 
 Fig. 21. 
 
 along it and draw the dirt to the other down spout O, where a similar action occurs. This arrangement has 
 two advantages. It constantly presents to the advance of the cotton new and clean receptacles for the dirt, and 
 it automatically removes the latter from the path of the material. These are decided improvements, and the 
 arrangement is a considerable advance on its predecessor. 
 
CHAPTER V. 
 
 THE SCUTCHING MACHINE. 
 
 (66) After the cotton has been opened by any of the machines just described it is passed into a machine 
 commonly known as a " scutcher." In this it is subjected to a further beating action, which in this case, 
 however, has the object of cleansing rather than opening it. Machines of this class may be either single or 
 double, that is, the cotton may in passing through the machine be subjected to the action of one or two beaters. 
 Occasionally, but very rarely now, three beaters are used. It is becoming a more general practice to use an 
 opener and single beater combined as a first stage and a single beater machine as a second stage, but there 
 is no fixed rule in this respect, the actual facts of each case determining the procedure. At one time the 
 opened cotton was ejected in a loose condition from the opener, and was placed upon the scutching machine 
 feed-table by hand, often being weighed. As an English practice this is becoming obsolete, the system of 
 pneumatic suction being employed to convey the cotton from one machine to another. Openers have very 
 often attached to them a lap machine, which forms the cotton into a roll or "lap." As the u lap" attachment 
 is one which is common to most cleaning machines a description may be given of it at this point. 
 
 (67) This attachment consists of two fluted rollers (|_ L Fig. 22), which are suitably revolved, and on 
 which the roll of cotton M is formed, being lapped round a rod or tube by the frictional contact of its surface 
 with the rollers L. Before it reaches this point the cotton is formed into a sheet on the dust cages, as 
 described in the preceding chapter. The iron rod or tube is made long enough to act as an axis for the lap 
 to revolve on, and to enable it to be carried about from place to place for further treatment by succeeding 
 machines. As the sheet or fleece leaves the dust cages J it is passed between a pair of smoothly turned 
 rollers, the upper one of which is weighted so as to calender or compress the lap. This is a matter of some 
 importance, as it renders the surface of the lap smoother and prevents the various layers adhering to each 
 other when unrolled. An arrangement is fitted by which the attainment of a defined diameter of lap releases 
 the setting on haudle, causing the latter to move and transfer the strap on to the loose pulley stopping the 
 machine. The importance of forming laps is now well recognised, and will be dealt with at greater length 
 at the end of this chapter. 
 
 (68) Fig. 22 represents a side elevation of a single scutching machine, as made by Messrs. Lord Brothers, that 
 is, one which beats the cotton once. It contains a revolving beater A, fixed upon a central shaft and driven at 
 a high velocity from a counter shaft. The beater consists of arms, forged solid, with a central boss, and having 
 feet at their outer ends. The arms are keyed firmly on the shaft, and may be either round or elliptical in shape. 
 There are either two or three arms on each boss, and a number of them are secured to the shaft along its length 
 
36 
 
 THE SCUTCHING MACHINE. 
 
 within the beater case. According to its construction the beater is known as a two or three "winged" beater. 
 However made, it is carefully shaped and machined, so as to be in perfect balance, and this is a most 
 important point in the construction of the machine. Too much stress cannot be laid on the necessity for 
 extreme care in this matter. Not only should the beater arms be balanced prior to fixing, but after having 
 been keyed on the shaft the same operation should be carried out. In order to balance the beaters thoroughly 
 it is better to revolve them rapidly, while sustained in bearings having freedom of sliding movement in a 
 frame. The velocity at which they are tested should be considerably in excess of that at which' they work, 
 and no pains ought to be spared to get the beater in absolutely true balance when working. Otherwise the 
 vibration set up would be considerable, and the character of the blow given would be intermittent instead of 
 regular. Before the final balance is given the blades should be attached to the arms. The blades are made 
 
 Fig. 22. 
 
 of steel — or of a combination of steel and iron fused together — of an irregular section, angularly formed at 
 one side, so as to present a moderately sharp face to the cotton as it strikes it. The blade requires to 
 be made with a slight clearance, so as not to rub the cotton after striking it. 
 
 (69) The question as to which is the better form of beater to use — a two or three-winged — is one which 
 is difficult to answer. Most makers to-day are using the former, while others — as for instance, Messrs. Piatt, 
 Brothers and Co. — while employing a two-winged beater for the " breaker," use a three-winged for the "finisher" 
 scutching machine. From the constructor's point of view the two-winged beater has undoubted advantages, 
 as it is at once more easily made, and balanced with much less difficulty. The diameter of a 
 two-winged beater is usually 14 inches across the blades, and of a three-winged 16 to 18 inches. The velocity 
 of the former is greater than that of the latter, being in one case 1,200 to .1,500 revolutions per minute, and 
 
THE SCUTCHING MACHINE. 
 
 37 
 
 in the other 900 to 1,000. Thus the peripheral velocity of the two- winged beater is from 4,314 to 5,497 
 feet per minute, and that of a three-winged, 4,100 to 4,700 feet per minute. Although a three-winged 
 beater, running at 1,000 revolutions, will strike the cotton 3,000 times per minute, the two-winged form, 
 running at the higher velocity of 1,500 revolutions, will give the same number of blows. There is, 
 however, the character of the blow to be considered. The smaller diameter in the case of the two-winged 
 enables the higher velocity to be reached, and the blow given is sharp and quick. In addition to this, 
 the smaller circle described by this form of beater causes the blade, after having struck the cotton, to 
 leave it rapidly; whereas the larger diameter of the three-winged one leads to the blade being longer 
 in contact with the cotton than it otherwise would be. This, coupled to the comparative slowness of 
 its peripheral velocity, gives a dragging blow, which is not a good thing for the cotton, as it is 
 apt to crush or bruise the fibres. The longer the staple the slower the velocity of the beater should 
 be, and this has an important bearing on the subject. For instance, with good cotton, the velocity of a 
 two-winged beater is sometimes reduced to as low as 1,000 revolutions, while with Indian cotton the higher 
 velocity is preferable. These considerations tend to show that the two-winged beater is the most suitable. 
 
 (70) There is another point which, however, deserves a word or two. The regularity of the pulsations 
 of a scutcher beater is a matter requiring consideration. It is a subject not always thought of, but it has 
 a great influence upon the resultant lap. The cotton— as will be hereafter shown — is struck from a roller or 
 pedal, and is thrust into the range of action of the beater blades at a defined and regular rate. As it is 
 desirable to beat it into small tufts before flinging it on to the grids, and as the cotton is liable to damage 
 if the pieces struck off are too large, it follows that the oftener the blades strike the better. That is, of 
 course, assuming they do not strike so often as to powder or crush the fibre. Now, there is no reason in 
 this consideration, for the employment of a three-bladed beater, which does not strike the cotton more frequently 
 than is the case with one with two blades. 
 
 (71) It is usual to form laps at the termination of each scutching process. These are first made, in most 
 cases, on the opener, or failing that, on the breaker scutcher. The laps thus made are fed to a second machine 
 called the finisher scutcher, where a new lap is made, which is fed to the carding engine. It is therefore 
 desirable to obtain the utmost regularity in the last lap named, and for this reason the pulsations of the 
 beater become important. On this account Messrs. Piatt Bros, and Company use a three-winged beater in their 
 finisher scutcher, believing that the result is more satisfactory. 
 
 (72) Surrounding the beater at its upper portion is a case, made quite air-tight. Beneath the beater a grid 
 H is placed, the bars of which are set to present a sharp edge to the cotton. The number of these varies according 
 to the class of cotton used. Careful regard should be given to this factor. In fixing the bars they should be 
 placed as shown in Fig. 24. The front bars C should have their cleaning edges set a little in advance of a 
 perpendicular line drawn across an imaginary line horizontal to the axis. The angularity thus given should 
 decrease as the bars are further from the feed roller. The reason of this is obvious. As the cotton is struck from 
 the feed rollers it is desirable that it should receive a sharp check at once, in order to shake out the freshly-freed 
 
38 
 
 THE SCUTCHING MACHINE. 
 
 impurities. This requirement becomes less urgent as the cotton passes onward and the arrestment of it 
 traverse is less necessary. 
 
 (73) The circle described by the top of the bars should not be concentric with that of the beater blades, but 
 ought to be as shown in Fig. 24, further from the centre of the beater shaft at the back than it is at the front of 
 the grid. The reason for this is that the bulk of the cotton after being scutched becomes greater, owing to 
 its more open condition, and it naturally requires more room, to avoid any choking or entanglement. Further, if 
 the grid is comparatively long the distance between the bars— in other words, their pitch— must be increased. 
 Below the bars is a chamber into which the dirt can fall freely, and which is closed by doors from without. The 
 pitch of the bars should be large enough to permit of the easy passage of the dirt. 
 
 Fig. 24. 
 
 (74) Messrs. Howard and Bullough use, in addition to the fixed bars shown, the additional bars D, which are 
 pivoted at their lower end, as shown, in a movable plate. This plate is attached to a lever E, which can be 
 operated from the outside. The purpose of these bars is to admit of the admission of more or less air as desired. 
 The space below the fixed bars and that below the air bars are separated by a thin division plate F. It is claimed 
 for this arrangement that the fall of the dirt through the bars C is considerably facilitated. 
 
THE SCUTCHING MACHINE. 
 
 39 
 
 (75) After passing the dirt grids, the cotton falls on to a second grid, or plate, as preferred, and then between 
 a short " dead " plate and " beater sheet " to the cage J on to which it is drawn. The cage J consists of a skeleton 
 cylinder revolving on a shaft, and having its periphery formed of finely-perforated sheet metal. Each end of the 
 cage terminates in an air passage or trunk extending upward as shown. At the foot of the trunk the fan I is 
 placed, which exhausts the air through the cages, and sucks the cotton on to them so as to form a continuous sheet 
 or fleece. From the cages the fleece is taken to the lap attachment, which has been previously described. 
 
 (76) Messrs. Crighton and Sons, a perspective view of whose machine is given in Fig. 25, make their 
 cages in a somewhat different manner to that just described. The ends of the cages are fitted into 
 the framing, which is recessed at each side to receive them. Their peripheries are formed of woven wire 
 webbing, instead of the perforated zinc sheets mostly used. At the end of the cage the webbing is protected 
 
 Fig. 25. 
 
 by a brass ring, which keeps it firmly in position. The effect of this arrangement is two-fold. A greater 
 space is left for the passage of the air than is possible with a perforated metal covering, and as a result, 
 the intensity of the current is reduced. In addition to this, the fleece of cotton is laid on the whole of the face of 
 the cages, because the manner in which they are fitted into the framing practically causes the latter to act as a 
 guide, beyond which the cotton cannot spread. In this way the edge, or " selvedge," of the lap is rendered very 
 even, a subject the importance of which is further dealt with in paragraph 99. 
 
 (77) Another point of special construction, adopted by the same firm, is the position of the " dead plate." 
 Tjjs is the name given to a plate below which the scutched cotton travels, extending across the machine 
 
40 
 
 THE SCUTCHING MACHINE. 
 
 immediately behind the beater. As the cotton leaves the range of the beater, it falls upon a plate or sheet 
 called the " beater sheet," immediately below the "dead plate." Now, for reasons to be given, the position of this 
 plate is important, and in the machine as made by Messrs. Crighton, its distance from the beater sheet is 1\ 
 inches. Immediately beyond this point the same firm use an appliance known as a "leaf extractor," of which an 
 illustration is given in Fig. 26. It consists of an endless brattice or canvas band D, as wide as the space between the 
 frames, and having fastened to it transverse bars of wood B. These are shaped as shown, with an edge meeting the 
 cotton as it moves forward, thus scraping off the leaf, and the space contained between each pair of these practically 
 forms an air-tight box for the reception of the leaf. The brattice moves in the direction of the arrow, and thus 
 
 J.N 
 
 Fig. 26. 
 
 meets the cotton as it passes from the beater. It is kept in tension by means of the rollers E F and G, and as 
 the bars pass over E, which is unattached, its weight causes them to open, and so drop the leaf into the chamber 
 bebv/, Having thus described the mechanism of this special arrangement, it is necessary to say something of the 
 draught regulation and the effect it has upon the work. 
 
 (78) The regulation of the air current is one of the most important features in the working of a scutcher. 
 Other things being equal, it is not too much to say that success or failure largely depends upon it. On the one hand, 
 it is necessary to provide sufficient suction to draw the cotton forward and lay it evenly on the cages ; on the other, 
 an excess of suction is very detrimental, as, if the movement of the cotton is too rapid it will be drawn over the 
 dirt grids before instead of after the dirt and leaf has fallen. More especially for the sake of the removal of leaf 
 does the current require to be slow. With any other procedure the lighter matter cannot fall, and is carried 
 
THE SCUTCHING MACHINE. 
 
 41 
 
 forward to the cages. An excess of suction further results in the cotton fibres being drawn into the interstices of 
 the cage surface, and the fleece does not in that case leave the latter easily. This results in a rough surface of the 
 lap, and leads when it is rolled up to " licking," or adhesion of the different layers. 
 
 (79) It is therefore desirable to get the draught as nearly balanced as is consistent with the required 
 onward movement of the cotton. What is wanted is rather a large volume of air moving at a slow pace 
 than a smaller one travelling more quickly. The fau should therefore be as large as can be conveniently 
 arranged, and should be run at a comparatively slow velocity. Its exit orifice must be of ample size, and 
 no obstruction be presented to the current of air. The latter is delivered into a passage or conduit running 
 below the floor and terminating either in the open air or a specially-arranged chimney. All these passages 
 must be made of ample size, and cases are numerous in which neglect of this requirement has resulted in 
 the inefficient working of a machine which otherwise ought to have worked well. The atmospheric changes 
 render it necessary to watch the regulation of the current so as to suit them, within limits. 
 
 Fig. 27. 
 
 (80) The precise effect of the arrangement of the dead-plate and beater-sheet referred to in paragraph 77 
 is to decrease the work thrown upon the fans. The beater, by reason of its rapid rotation, creates a sufficient 
 current to carry the cotton on to the grids or extractor, if the space between the dead-plate and sheet is 
 narrowed as described. If that be increased the effect of the impulse thus given is diminished proportionately. 
 When so arranged, the cotton impelled as described passes gently over the leaf extractor, being aided by the 
 slow current created by the fans, and thus allows the leaf to fall freely and without difficulty. 
 
 (81) In Fig. 27 a diagrammatic representation of Messrs. Piatt Brothers and Company's arrangement is 
 given. In this case, also, the dead-plate is arranged so as to narrow the exit orifice from the beater, with 
 a similar beneficial effect to that described. The cotton then passes over the bars of a dirt box |_, into which ' 
 the leaf can fall, being periodically removed. 
 
42 
 
 THE SCUTCHING MACHINE. 
 
 (82) The feed apparatus used is now almost universally combined with a regulator which bears the name 
 of its inventor, the late Mr. E. Lord, of Todmorden, and is commonly known as the " piano feed." It is one of 
 the most effective motions in the whole range of textile mechanics, and lias considerably increased the regular 
 working of this particular machine. Referring now to Figs. 28 to 31, which are respectively side, end, and 
 plan views, it will be seen that the cotton is fed from the lattice H over the nose of the pedal lever A 
 and under the feed roller B- After this it is struck by the beater G in its rotation. The shape of the pedal 
 nose varies considerably, according to the length of the cotton used, the modification in Fig. 28 being that 
 used for short, and the one in Fig. 29 being employed for long stapled cotton. The pedal lever is hinged 
 upon a rod, and has behind its fulcrum a long tail piece which terminates in a hook I. On to this a pendant 
 lever C is suspended. The lower portion of each of these pendants is widened so as to form a double taper 
 surface, as shown in the end view at D. Between each pair of pendants, at its lower end, small runners or 
 bowls are placed, these being fixed in rods sliding in the double frame F, which at the end E is tied together. 
 The last of the series of pendants C 1 is formed with a slot, as shown, with which a lever is jointed, as will 
 afterwards be described, and as is further shown in Fig. 23, which is an end view of the machine shown in 
 Fig. 22. All the pendants can swing freely upon the pedal levers. The latter are placed, as shown in the 
 plan, in close proximity to each other, so as to cover the whole space below the feed roller, while at the 
 same time they have freedom of movement. 
 
 (83) Referring now more particularly to Figs. 22 and 23, the last pendant lever is coupled by the connecting 
 rod O and the levers shown to the two strap levers E, which have sectors formed at one end gearing with 
 each other. ' These levers carry the guides for the strap N, which is tightly placed upon the cones D D 1 . 
 These are respectively convex and concave, their outline being a parabola. The cone D 1 is driven by means 
 of the strap shown from a pulley on a counter shaft, and revolves at a velocity of 600 revolutions. The 
 other cone D is driven from D l by the strap N, and is fixed upon a spindle or shaft which is carried 
 upward (Fig. 23). On the upper end of the shaft is a worm P engaging with a worm wheel R on the feed 
 roller, which is driven by these means, or a change wheel may be interposed if desired. 
 
 (84) The action of this mechanism is as follows. As the cotton is delivered by the lattice it passes over 
 the nose of the pedal and between it and the feed roller. If there happens to be a thick piece in the feed 
 it depresses the nose of the pedal over which it passes. This raises the pendant rod C. Now the space 
 between the thinnest portion of the pendant foot and the bowls is only sufficient to enable the pendant to 
 rise a little before pressing on the bowl next it. Its motion being limited in this way, and the tendency to rise still 
 occurring, either the pendant must become jammed or the bowl must have liberty to move to one side. This 
 is what occurs, the lateral movement of the bowl being permissible to the extent which corresponds to the space 
 between the remaining pedals and their adjoining bowls. After this is taken up, pressure exercised by the rising 
 pendant upon the bowl causes the bar in which the latter is fixed to move in the box to an extent which 
 is regulated by the depression of the pedal nose. In other words, the pendant swings on the end of 
 the pedal lever either to the right or the left as may be required, giving a similar movement to the 
 
THE SCUTCHING MACHINE. 
 
 43 
 
 rest of the series. The movement thus set up is communicated to the strap levers E by 
 means of the connecting rod O and its attachments, and the strap is accordingly raised or lowered as 
 required by the circumstances of the case. The weight of the parts connected to the pedal levers are sufficient 
 to press their noses against the feed roller unless prevented by means of the cotton being fed. Thus a thin 
 place in the material at any part of the width of the feed roller is followed by the reverse action to that 
 named, the strap being moved on the cones in a similar manner. The presence of a thick place in the feed 
 
 Figs. 28, 29, 30, and 31, 
 
 decreases the velocity of the driven cone and feed roller, while the reverse action occurs when a thin place 
 is presented. Thus the retardation of the cotton in the one case leads to any extra thickness being rapidly 
 beaten out, more blows being given to the same length fed than would be under ordinary circumstances. On 
 the other hand, a thin place results in the quickening of the feed roller and a greater quantity of cotton is 
 beaten off in the same time. In this way an evenly-weighted delivery takes place, and this, in conjunction 
 with the lap feed, of which more will be said hereafter, enables a lap to be finally produced, in which the 
 variations of thickness are comparatively slight. 
 
44 
 
 THE SCUTCHING MACHINE. 
 
 (85) At one time it was the universal custom to strike the cotton directly from the pedal nose Fig. 32, 
 a practice which, however the latter was shaped, had many defects. A much better method is adopted by 
 Messrs. Piatt Brothers and Company, and is shown in Fig. 33, which illustrates the new practice. It will be 
 seen that, when the beater strikes the cotton directly from the pedal nose, the fibres will be bent sharply round 
 an angle. In the case of long-stapled cottons especially this is detrimental, as it is liable to lead to rupture or 
 breakage of the fibre. With the shorter-stapled varieties this is not so likely to occur, and the use of a pedal 
 and feed-roller is more permissible. The arrangement shown in Fig. 33 is a much better one, and consists 
 in the employment of an additional pair of feed rollers placed between the pedal and the path of the beater. 
 There are two distinct advantages from this procedure. The cotton is bent round a larger curve when it is 
 
 Fig. 34. 
 
 struck by the beater, and is, therefore, less liable to rupture; and the feed-rollers exercise a certain amount 
 of drawing action. The latter point is of some value. The cotton in passing under the feed roller and between it 
 and the pedal nose is held by them. The correction of thick or thin places and the alteration of the speed of 
 the feed to meet them is controlled from this point. If the second set of rollers revolves at, a slightly quicker 
 speed than the one above the pedal the cotton will be a little drawn. In any case, this action will take place 
 to a greater or less extent, and the thick places will thus be partially thinned out before being struck by the 
 beater. The shock of the stroke is thus considerably diminished, and the risk of damage much lessened. 
 
 (86) It only remains to be said with regard to the Lord pedal motion shown in Figs. 28 to 31 that it is now 
 amended by the introduction of two bowls between each pair of pendants, which are acted upon singly by the pendant 
 they adjoin. The latter point is illustrated in Fig. 34, which represents the old method of arranging the pendants 
 and rollers, and an improved plan of Messrs. Howard and Bullough. In the former case each pendant engaged 
 with one side of a bowl, with the other side of which the adjoining pendant also engaged. In the event of 
 
THE SCUTCHING MACHINE. 
 
 45 
 
 both of the latter rising at once, it is apparent that the bowl will tend to be rotated in opposite directions. In 
 effect it becomes practically inoperative, and the friction set up is considerable, preventing the easy movement 
 of either pendant. To obviate this, the three-bowl arrangement shown in Fig. 34 is adopted. The pendants 
 are made with one fiat face, and with one on which a rib is formed. On the spindle three bowls are placed, the 
 centre one being of smaller diameter than the others. The two outer bowls engage with the flat side of one of the 
 pendants, but are entirely out of contact with the adjoining one. On the other hand, the central bowl engages 
 with the rib formed on one pendant, but is too small in diameter to engage with the flat face of the next of 
 the series. Thus the whole of the pendants could rise simultaneously without setting up the friction referred 
 to owing to the cross torsion on the rollers. The sensitiveness of the motion is thus largely increased. The 
 adoption of two bowls, each independent of and out of contact with the other, produces a similar result. 
 
 Fig. 35. 
 
 (87) There are several modifications of the pedal motion in use, but, before passing on, the arrangements 
 used by Messrs. Piatt Brothers and Company may ba described. Dealing first with the driving of the cones 
 reference may be made to Fig. 35. The spindle of the driving cone B is prolonged so as to rest in a footstep 
 and has fixed upon it the double-grooved pulley S- An endless rope or band is passed round the pulley I, 
 which is the driving pulley, and thence passes round the pulley G, carried on a pin, the position of which 
 can be regulated by the screw shown. After going once over the pulley G the band is conveyed round 
 the upper groove of the pulley S, back to G, thence to the carrier pulley shown, again round S, and finally 
 returns to the driving pulley I. A little consideration of the course thus followed will show that there is 
 a pull upon the spindle of the coae B in diametrically opposite directions, and as the pull is in each case 
 equal, the wear of the shaft and footstep is materially reduced. The consequence is that high velocities can 
 be attained with the utmost ease, and without any undue strain upon the ropes or shafts. 
 
 (88) Referring now to Fig. 36, which is a front view of the pedal arrangement, it will be noticed that 
 the levers P are each of them placed between two bowls, which are actuated by their own pendants only. 
 
46 
 
 THE SCUTCHING MACHINE. 
 
 Instead of coupling the regulating levers to the last of the series of pendants, a different arrangement is 
 adopted. The hanging lever O is fastened at its upper end on a pin carried by the horn bracket shown, 
 which is fixed to the bowl box. On the other end of the pin is a second lever, shorter than O, and also fixed to 
 the pin. Thus any oscillation of the lever O is followed by a similar movement of the second lever. 
 The lever O is long enough to enter the bowl box, and any lateral movement of the bowls 
 causes a similar movement in the lever. This is repeated by the shorter lever, which is coupled 
 to a connecting rod Q. The latter is made in two parts, connected by a nut, with a right 
 and left handed thread, so as to permit of any adjustment necessary, which is also aided by the slots shown as 
 existing in the various levers in the series. The rod Q is jointed to an L lever R, on the horizontal limb 
 
 Fig. 36. 
 
 of which the balance weight T is fastened by means of a pin passing through the slot. To the extremity 
 of this limb of the lever R a chain F is coupled, which, passing over a grooved pulley placed above the 
 cone box, is attached to each of the strap levers O P (Fig. 35). These levers are hinged in the manner 
 shown, and carry strap forks acting upon the strap C- The relative positions of the strap and levers, at a 
 point midway of the length of the cones, are shown by the dotted lines in Fig. 35. On the spindle of the 
 cone A is the worm L, by which the feed rollers are driven, the three roller arrangement being in this case 
 used, one of them revolving above the nose of the pedal lever. 
 
 (89) The action of this mechanism is easily explained. As the pedals are depressed or elevated the 
 bowls are moved laterally, as previously described. The last of the series being in contact with the lever O 
 
THE SCUTCHING MACHINE. 
 
 47 
 
 causes it to oscillate, and, in consequence, the shorter lever jointed to the rod Q is moved. This motion is 
 communicated to the chain F, which exerts a pull upon the strap guides, and raises or allows them to fall as 
 described. One cardinal feature in this arrangement is the power of adjustment which is given at every point, the 
 balance weight T being easily set to give the exact amount of pressure of the lever O upon the last bowl, while 
 at the same time permitting it to oscillate without an excessive power being required. This makes the motion 
 very sensitive, which is assisted by the size of the cones, and by placing the pedals on knife-edged supports 
 instead of a shaft. Usually the cones are made about 4 inches diameter at the large end and 2| inches at 
 the smaller. In the machine, as made by Messrs. Piatt, the cones are 8 and 5 inches diameter respectively 
 at each end, and, as their velocity is high, a slight pull upon the strap vertically is sufficient to move it up 
 or down the cones. 
 
 (90) A special arrangement, made by Messrs. Dobson and Barlow, is shown in Figs. 37 and 38 in elevation 
 and plan. Here the pedals WW 1 are all of the same shape, and the last of the series W is not coupled 
 to a connecting rod, as shown in Fig. 22. Instead of this, three bowls, R R T, are placed upon a pin which 
 passes through the forked end of the small frame Z. The rollers R R roll in the groove in the box, and are 
 provided with broad flanges which keep them in position laterally. The roller T is in contact with one edge 
 of the last pendant W, and when the latter is pushed to one side it presses upon the roller and causes it 
 and the cradle Z to move in the same direction. A pin in the other end of the cradle passes through the 
 end of a lever Y, which fits between the fork in Z and passes through a hole in the cross-piece of the bowl-box. 
 The thrust upon the rod Y is therefore given in the centre of the pendants, and these are not liable to be 
 twisted. The rod Y is jointed to the L lever shown, which forms part of the series connecting the pedals 
 and strap guide levers. As shown in the detached sectional view, Messrs. Dobson and Barlow employ between 
 each pair of pendants three anti-friction bowls, U V U, which work loosely upon the pin X. The latter is made 
 in the centre with a boss, eccentric to its main portion, and in this way the central bowl V is caused to 
 engage with the pendant W, while the other two U engage only with the pendant W 1 . The pin X cannot 
 revolve by reason of being fitted into a square hole in one of the bowls sliding in the groove in the box, so 
 that the relative positions of U and V are always maintained. 
 
 (91) In Figs. 39 and 40 a front and side elevation of the pedal regulator as made by Messrs. Asa Lees and Co. 
 Limited, is illustrated. The pedals E are hinged at one end, and rest upon vertical rods J, the lower ends of 
 which press on the extremities of the balanced plates B. Each of these is suspended on a larger plate C, of similar 
 construction, which in turn rests on the extremity of a plate D. The latter is suspended by its centre from a 
 lever, F, which is fulcrumed on a knife edge at H. The lever F is coupled in the manner shown to the strap guide 
 lever I, which is moved by means of the horizontal bar shown, which slides upon guide runners. The cones A A 1 , 
 are placed horizontally, the advantage claimed for this position being that the strap has a much easier motion 
 along the cones than is the case when the latter are vertical. It will be observed that the whole of the 
 balanced plates are in equilibrium, and are suspended on the end of the lever F. Thus a slight movement of 
 one of the smaller plates, B, is multiplied before it acts upon the lever F, and the regulation of the strap 
 is thus rendered more sensitive. 
 
48 
 
 THE SCUTCHING MACHINE. 
 
 (92) In Fig. 41 a side elevation of the driving gear used by Messrs. Asa Lees and Co. is shown. In this 
 case the whole of the essential movements are driven by means of one endless rope. This plan obviates the 
 difficulties which arise if a beater strap breaks and the feed continues, or if the delivery ceases from the same 
 cause and under the same circumstances. In this case the lap attachment and cages are driven from the 
 pulley D, the beater and the cones also by the same rope. The direction of the rope's movement is indicated 
 by the arrows, and a tightening screw is provided to keep the band in tension. On the shaft of the beater is 
 a friction clutch, one-half of which is formed into a grooved pulley. By disconnecting the clutch, the beater can 
 be stopped independently of the rest of the machine. 
 
 (93) Having thus described the principal methods of arranging the mechanism adopted by various machinists, 
 there are one or two words to be said with reference to combined machines. These are very numerous and 
 various, being arranged in several ways to suit the requirements of particular spinners. For instance, in Fig. 9, 
 
 = J.N. 
 
 Fig. 41. 
 
 described in the last chapter, there is a combined machine, viz., an opener and lapper. The machine shown in 
 Fig. 20 is an instance of a combined opener, scutcher, and lap machine. So, again, the machines shown in Figs. 
 13 and 14 are similar combinations, and in Fig. 8 is an example of a breaker feed combined with an opening 
 cylinder — in different rooms but coupled by an air pipe — used as an aid in forming a stack of mixed cotton 
 partially cleaned. In Fig. 13 a representation of the arrangement of a scutching room with a mixing room above 
 it is given in section, and in Fig. 42 a plan of the mixing lattices. In this the bale breaker A delivers the cotton to 
 a double ascending lattice B by which it is transferred to the series of longitudinal aprons C. Openings are placed 
 above each bin E so that the cotton can be discharged into any of them at will. Alongside the mixing bins is a 
 longitudinal lattice F, on to which the cotton is placed as it is taken from the stacks, and is carried to the porcupine 
 
50 
 
 THE SCUTCHING MACHINE. 
 
 feed table G. Immediately after being treated by that machine the material passes into the dust trunks D, 
 over the dirt grids at K, to the cylinder of the opener H . The laps there formed are placed in the scutcher |_, 
 and those made in that machine are fed to M . The laps formed on the opener are fed to the scutchers, as shown 
 in Fig. 22. In Fig. 43 a plan is given of one arrangement of a scutching room, showing a complete set of 
 machines for dealing with Indian or other dirty cotton. For long staple 1 clean cotton, such as Egyptian, 
 
 Fig. 
 
 only the two machines enclosed within the dotted lines are necessary. Most of the figures, dealing with 
 these combinations are representations of actual arrangements carried out by Messrs. Piatt Brothers. It 
 is obvious that some plan must be adopted by which the supply of cotton must be stopped when the 
 scutching machine is knocked oft. If this was not the case, the air tubes and dust trunks would speedily 
 become full, and there would be the risk of a breakdown when the machine was re-started. In view of this 
 
 J.N. 
 
 Fig. 43. 
 
 difficulty, Messrs. Piatt arranged that when the machine is being stopped, the porcupine feed roller is stopped 
 so much before the opener cylinder that the whole of the cotton delivered by it is drawn out of the dust, 
 trunks. Conversely, when the machine is being re-started, the feed mechanism is the first to begin operations,, 
 
 1>:'' '■ 
 
 so as to ensure an ample supply of cotton to the cylinder, and thus avoid any thin places or failure in the) 
 resultant lap. This is a matter of some importance, as upon it depends very largely the regularity of the laps. 
 
THE SCUTCHING MACHINE. 
 
 51 
 
 (94) It is of extreme importance to produce laps at an early stage, as they play a great part in effective 
 spinning. Before dealing with this point a few words may be said about the necessity for care in feeding the cotton. 
 The fibre is easily ruptured, more especially at the points, which, owing to their distance from the seed during growth, 
 are often solid. It is conceivable that the cotton might be fed at precisely the same speed as that of the periphery 
 of the beater blades. In that case it would simply pass through the machine without any treatment whatsoever. 
 Or it might be fed so rapidly that the beater in its rotation would knock it off the end of the lap in tufts or lumps. 
 As the blow of the beater is given transversely of the fibre, such a treatment would produce a large amount of broken 
 fibre. It is, therefore, of importance to feed so that the cotton is neither broken by overfeeding or pulverised by 
 underfeeding, and in fixing the right velocity the length of the fibre requires carefully taking into account. The 
 conditions of successful and economical work are well known, and may be stated as follows : The blow given must 
 be sharp, and not dragging j the beater blades must be shaped to detach, without rupturing, the fibres ; the rate of 
 the feed roller must be regulated to insure the thorough detachment of the material ; and, finally, the cotton should 
 not be struck from a sharply angular surface. It is, of course, impossible so long as revolving beaters are used to 
 avoid bending the fibres, but it is quite possible to so shape the surface from which they are struck as to minimise 
 the risk of damage. 
 
 (95) The various illustrations given of both opening and scutching machines show that it is the practice 
 to form the cotton at as early a stage as possible into a lap. Not only is this course more convenient, but 
 it is decidedly preferable where good work is required. In cases where it is the custom to eject the cotton 
 from the opener in its opened condition, it is necessary to lay it on the feed lattice of the scutcher, either 
 manually or by means of a lattice. A practice which is now almost obsolete is to weigh the cotton by means 
 of scales adjoining the feed apron, and spread it on the latter by hand. Even with expert attendants, the 
 risk of uneven feeding by this plan is great, and uneven feeding means unevenly-weighted laps as a result. 
 By the exercise of a little care, and more especially if the piano-feed be fitted to the opener, a lap it 
 produced on that machine the inequalities of which are much reduced. The author recently saw a lap, paragraph 
 52, produced on the combined feed, opener, and scutcher of Messrs. Piatt, which was the first made on 
 the particular machine employed, and which was remarkably regular in thickness. The same result 
 has been seen in other cases, and by obtaining a regular sheet at this early stage many advantages arise. 
 Whether an opener be employed in conjunction with a breaker scutcher or not, the formation of a lap is a 
 great help to good work. Where such a combination exists, it is customary to fit pedal regulators 
 immediately before the scutcher beater is reached, so that the inequalities existing in the sheet as it is taken 
 from the first pair of cages are at once corrected. A reference to Figs. 10 and 20 will show this application 
 fitted respectively to the opener feed and the scutcher beater. 
 
 (96) Whatever may be the practice with regard to the opener, the breaker scutching machine is invariably 
 provided with the lap attachment, and the finisher scutcher is fed from laps. A reference to Fig. 22 will show that 
 the machine is fed from three laps F, which are laid upon the travelling lattice apron G. The forward movement 
 of this lattice unrolls the laps and delivers them to the feed rollers, they being prevented from moving forward by 
 
52 
 
 THE SCUTCHING MACHINE. 
 
 the rods through their centres, which press against the vertical projections on the lattice frame. It is often 
 customary to use four laps instead of three, especially in passing them through the last machine. 
 
 (97) It will be apparent on reflection that the laps as produced will vary considerably in weight and substance. 
 When first formed, and taken from the machine, each lap is weighed, and a record kept of its weight. In selecting 
 the laps from which the finisher scutcher is to be fed, regard is paid to these variations. If one or two laps 
 are under weight to a certain extent, while others are over it to a corresponding amount, the machine is supplied 
 with both. As they are all fed at the same time, it follows that to a large extent the irregularity existing in one 
 is corrected by the converse irregularity of another. This is, of course, a matter of degree, but roughly speaking, 
 the correction is an effective one. By this system of doubling, as it is called, and by the regulation afforded 
 by the pedal motion, the lap produced finally has rarely more variation than 5 pet- cent, and in many cases the 
 variation does not exceed 1£ per cent. 
 
 (93) There must be with a machine fed from four laps, as there is even in the opener, a considerable amount 
 of draught existing, for it is obvious that the resultant lap will be no heavier than one of those fed, and is in 
 most cases lighter. That is to say, the lap is elongated so that an equal length of the finished lap weighs less 
 than that of tho33 fed. Thus th3 irregularities of thickness existing in any of the laps fed to the machine are 
 diminished by the draught of the machine, and when this factor is combined with that arising from the treatment 
 of four laps together, the result is found in the regularity stated. It is desirable to get as many doublings as 
 possible, and where very good work is required the material is passed through three machines before the final laps 
 are produced. This part of the subject is so easily understood that it is not necessary to further treat it. 
 
 (99) A point which is almost as important is the necessity for getting even selvedges to the laps when 
 produced. The lap referred to in paragraph 52 had this feature, and there can be little doubt that the 
 regulation of the air current plays an important part in this respect. It is of the highest importance that 
 no thin places shall be found in the selvedges, as their effect is afterwards seen through every succeeding 
 stage in spinning. Messrs. Piatt Brothers have adopted a construction of their various machines, by which a 
 gradually decreasing width is found in each of the series. Thus, if the opener produces a lap 48 inches wide, 
 it will be fed to a scutcher 47 inches wide only, the lap so produced being that width. A similar or greater 
 reduction is effected in the last of the series, the width being correspondingly reduced. In this way a very 
 even selvedge is produced, with the consequent advantages. 
 
 (100) The weight of a lap is determined by weighing one or two yards. If it be afterwards desired to see what 
 " hank " the lap is, the weight of the piece is obtained, and the weight of a pound calculated from it. That is 
 divided into a constant number, obtained as afterwards described, and the resulting decimal gives the hank lap. 
 
 (101) The draught in a scutching machine takes place at the following points : 1st, between the feed lattice 
 and rollers ; 2nd, between the feed and the lap rollers. 
 
 (102) It only remains to be said that by the employment of air trunks and combined machines the finished 
 laps can be produced by the aid of only two or three workpeople. The cotton requires no handling from the 
 mixing room till the first lap is produced, and only then requires weighing and placing upon the finisher scutcher 
 lattice table. 
 
CHAPTER VI. 
 
 THE CARDING MACHINE. 
 
 (103) The scutching process being complete the heavy impurities are practically removed, but there are 
 still to be found in the material the bulk of the lighter ones. The severe treatment of the cotton during 
 scutching adds to the number of broken and short fibres, and also increases the neps. There are also still 
 adhering to the material small particles of broken seed and leaf, which are technically known as "motes." 
 The removal of all of these is part of the duty of the carding engine. In addition to this, it is requisite 
 to arrange the fibres in what is practically parallel order, as only in this way can a strong yarn 
 be produced. This object is attained by attenuating the "lap," and then treating its fibres by a number of 
 fine wire points, so as to comb or card them. The objects of carding are, then, briefly stated, three-fold— 
 the completion of the cleansing process, the parallelisation of the fibres, and the attenuation of the fleece. 
 
 (104) Cotton was originally carded much in the same way that wool was combed, viz., by drawing a 
 hand comb through a mass of it while held on a table or bench. As soon, however, as the manual art of 
 spinning was superseded by a mechanical process, a similar change occurred in carding. The earliest mechanical 
 carding engine was invented either by Paul or Bourne, about 1748, and shortly afterwards Arkwright 
 developed his roller carding engine, which, in its essential features, is identical with many machines of the 
 present day. A full description of the early development of the carding engine will be found in Mr. Evan 
 Leigh's work. The invention of the doffing comb, the revolving flat principle (by Jas. Smith, of Deanston) ; 
 the coiler (by David Cheetham, of Eochdale) ; and the self-stripping card, all form stages in the growth of 
 the machine. Latterly the attention of machinists has been directed to improving the mode of manufacture 
 and the simplification of details, the main principle of the machine having been fixed for some years. All 
 carding engines have a few essential parts which are common, and it will be better to give a general description 
 of these before dealing with the details. 
 
 (105) The perspective view of a revolving flat carding engine, as made by Messrs. Ashworth Bros., given 
 in Fig. 44 (page 63), will enable the description to be easily followed. The lap from the scutching machine is lifted 
 by the iron roller on which it is wound, and the ends of the latter are slipped into the grooves formed in the 
 brackets A. The surface of the lap rests upon a roller C, which is steadily revolved, and is geared with the 
 feed-roller D. The sheet is drawn off the lap from the bottom, and is passed over a polished iron feed-table 
 or plate, which at its inner end is dished. The feed-roller revolves in the curved part or dish of the plate, 
 and is from 2in. to 3in. in diameter, being formed with longitudinal and circumferential flutes along its 
 entire surface between the bearings. 
 
54 
 
 THE CARDING MACHINE. 
 
 (106) The projecting end of the lap, as it is delivered by the feed-roller, is thrust over the nose of the 
 dished plate, and is struck by teeth fixed on the surface of a roller B, revolving at a rapid rate. The 
 direction of the rotation of this roller is shown in Fig. 46 by the arrow. It is called the "licker" or 
 " taker-in," and is made of cast-iron, keyed on a wrought-iron spindle, which revolves in bearings fixed to the 
 framing. It is driven from a pulley on the cylinder shaft by means of a crossed belt. It is usually made 
 8in. or 9in. diameter, and the same width as the cylinder. Its surface is accurately turned, and it is covered 
 when ready for work with a special wire clothing, to which further reference will be made in the succeeding 
 chapter. The licker-in teeth strike off the cotton from the end of the lap, and carry it forward until it comes 
 into contact with the cylinder teeth. 
 
 (107) The cylinder E is made from 40in. to 50in. diameter, and from 37in. to 50in. wide. It consists 
 of a cylindrical shell, strengthened throughout its length by small internal ribs, and having near its edges a 
 flange formed. Its position is clearly shown in Fig. 46, and the way in which it is built in Fig. 51. 
 The inner part of the ends of the cylinder and the face of the vertical flanges are bored out accurately by 
 a specially constructed machine. Into each of these recesses a spider is fitted, consisting of a central boss, 
 arms U, and rim V. The boss is first bored to the size of the shaft upon which it has to fit, and the edge and 
 inner face of the rim are turned to a size corresponding with the recess in the cylinder. The two spiders 
 so prepared are fitted into their places, and are then securely bolted to the cylinder. In this way a firm and 
 accurate fit is secured. A mandrill is fitted into the bosses, and the cylinder is then turned truly on its 
 faoe. After the shaft is fitted In it is sometimes the practice to grind the face of the cylinder, but, if the 
 needful care is taken in turning it, this is not necessary. It is essential that the periphery of the cylinder 
 shall be rigid, but it is equally important that the latter shall not be too heavy. A velocity ranging from 
 140 to 200 revolutions per minute is given to it, and it is clear that lightness and perfect balance are alike 
 important. After the turning is completed the surface of the cylinder is drilled with a number of rows of 
 holes about half an inch diameter, into which wooden plugs are driven, so as to facilitate the " clothing " of 
 the cylinder. As a rule the latter is balanced, or rather tested for its balance, by running it at its working 
 speed in bearings which slide when the equilibrium is disturbed. When working, the direction in which the 
 cylinder revolves is indicated by the arrow in Fig. 46, and the cotton is carried from the licker-in B to the 
 doffer F, being treated on its way thither by a special set of teeth, the arrangement of which will be 
 hereafter described. 
 
 (108) The doffer is a cast-iron roller, 22in. to 26in. in diameter, the same width as the cylinder, and 
 is placed as shown at F. The doffer is constructed and clothed in a similar way to the cylinder. It 
 revolves, as shown by the arrow, in the contrary direction to the cylinder, and at a much slower rate, making 
 usually about twelve revolutions per minute. In this way the carded fibres are transferred from the cylinder 
 to the doffer, and are placed on the surface of the latter in a thin fleece. The removal of the latter is 
 effected by a narrow thin steel blade G, Fig. 44, known as the " doffer comb," which is fixed on the ends of 
 short arms fastened on a shaft carried by bearings at each end. A rapid oscillatory motion is given to the 
 
THE CARDING MACHINE. 
 
 55 
 
 comb by means of an eccentric or cam, driven from a pulley on the cylinder by a cord or band, the number 
 of beats per minute reaching 1,100. An arc of about an inch long is described by it, and in this way a 
 continuous fleece, called the " sliver," is taken off the doffer. 
 
 (109) The sliver is loosely gathered together into a strand by means of a specially shaped plate, and 
 passed through a pair of calender rollers H Fig. 44 by which it is partially compressed. A slight traverse 
 is sometimes given to the trumpet-shaped tube through which the sliver is taken to the calender rollers. 
 After leaving the latter the sliver is taken upwards to an opening in the plate at the upper part of the 
 frame I . This frame forms part of the apparatus known as the " coiler," which is illustrated in vertical 
 section in Fig. 45. 
 
 (110) The coiler consists of a frame I within which is a vertical shaft V driven by means of the short 
 horizontal shaft from the calender rollers. At the upper end of the shaft a second pair of bevelled wheels 
 are geared, which drive the calender or feed rollers placed immediately below the trumpet-shaped orifice in 
 the cover T, which is hinged as shown. One of the rollers is supposed to be removed in order to show 
 the arrangement more clearly. The sliver entering by the orifice in T and, passing the rollers, is delivered 
 into a short tube X forming part of the plate Z. The latter is driven in the direction shown by the arrows 
 by means of the spur wheel Y gearing with a rack formed on the edge of the coiler plate Z. The sliver 
 is thus given a slight twist, and is delivered into the can W, placed on a plate free to revolve and borne 
 in the lower part of the coiler frame. The can is placed eccentrically to the coiler plate Z, and is slowly 
 revolved in the opposite direction to it, as indicated by the arrows. In this way the sliver is laid within 
 the can in coils, which are peculiarly disposed so that they do not become entangled. Often, within the can, 
 a pair of discs, coupled by a coarsely pitched helical spring, are placed, upon which the cotton is received. 
 The object of this device is to relieve the strain upon the sliver, which would otherwise arise if it were 
 unsupported as far as the bottom of the can. As the weight comes upon the upper disc the spring compresses. 
 
 (111) The parts thus described are common to all cotton carding machines, and would remove the major 
 portion of the motes and heavier impurities, but only a partial parallelisation of the fibres would occur ; nor 
 would more than a small portion of the short, broken, or immature fibres or " neps" be removed. It therefore 
 becomes necessary to devise a means by which, while the cotton is on the cylinder, it may be treated so that the 
 completion of the cleansing and the arrangement of the fibres are carried out. In order to do this the fibres must 
 be submitted to a combing process, by which, while held by the cylinder teeth, another set of teeth act upon 
 them. The form of carding engine which first found extensive employment, and which is yet preferred by 
 many spinners, is known as the "roller and clearer card." This machine is illustrated in Fig. 47, as made 
 by Mr. John Mason, in perspective, and in Fig. 46 diagrammatically. After the cotton has been taken from 
 the licker-in B by the cylinder E it is carried past a roller J, known as a dirt roller. The diameter of 
 this is from 5iu. to 6 in., and it revolves at about eight revolutions a minute. When the fibres are 
 taken up by the cylinder wire, they are partially embedded in the interstices of the clothing, but the motes 
 remain on the surface, from which they are easily removed. The dirt roller J takes these up, and, 
 
56 
 
 THE CAEDING MACHINE. 
 
 being covered with a coarser pitched wire than E, the motes become fixed in the former, from which they 
 can be stripped. This can be effected by a hand comb at rfgular intervals, or by an oscillating comb 
 suitably operated in the way made by Messrs. John Hetherington and Sons, as illustrated in Fig. 48 (page 60). 
 In this case the dirt roller A is driven by a side shaft by means of the worms B and D, the latter gearing 
 into the wheel E, which is keyed on the dirt roller spindle. A cam F fixed on the first working roller 
 gives a reciprocating motion to the rail G by which the comb H is operated, the roller J being thus 
 stripped. An iron tray I is fixed, as shown, into which the strippings fall. 
 
 (112) After passing the dirt roller the cotton is treated by the teeth on a smaller roller, K, known as a 
 " worker " roller, which revolves in the direction of the arrow. Each worker has a smaller roller, L, placed in 
 contact with it and called a "clearer." The teeth on the worker have an inclination which is the reverse of those 
 on the cylinder, aud any cotton which is not fixed in the wire surface of the latter, or which is flung up by the 
 centrifugal action of the cylinder, is seized by the worker teeth and removed. The worker revolves at a slower 
 speed than the cylinder, its surface velocity being about 20 feet per minute, and varies in diameter from 5 to 6 
 inches. The clearer, which is 3 or 3| inches in diameter, has its teeth set in the same direction as its motion, and 
 its surface speed being about 400 feet per minute, it takes the cotton from the worker and again transfers it to the 
 cylinder. As the surface velocity of the latter is higher than that of the clearer, the cotton is struck by its teeth 
 and is drawn off the clearer and carried forward to the next pair of rollers. It should be pointed out that, 
 although the cotton on the cylinder passes the clearer before it reaches the worker, the inclination of the 
 clearer teeth is such that they cannot take up the fibres ; while, on the other hand, the worker teeth are so 
 set that, as previously pointed out, they take up the fibres from the cylinder. Again, the different velocities 
 
THE CARDING MACHINE. 
 
THE CARDING MACHINE. 
 
 59 
 
 off the workers, clearers and cylinders cause a series of condensations and attenuations of the fleece to occur. 
 The short fibres and " nep " are laid hold of, and are either sufficiently loosened to be thrown off as " fly," or 
 aire embedded in the teeth of the workers and clearers, which, in consequence, require periodical stripping, 
 tlhis being usually effected manually. The setting of the rollers must be such that they do not approach the 
 
 | J.N. 
 
 Fig. 45. 
 
 cylinder too closely, but simply deal with the fibres thrown up by the revolution of the cylinder. The lighter 
 t":he carding, provided cleanliness is achieved, the better for the cotton, as with too heavy carding considerable 
 dlamage is done to the material. 
 
60 
 
 THE CARDING MACHINE. 
 
 (113) The rollers and clearers are fitted with spindles, projecting beyond the cylinder and framing, and 
 sustained by suitable bearings. On the projecting ends of both worker and clearer rollers, pulleys, with grooved 
 peripheries, are fixed, over which an endless belt or rope is passed, deriving its motion from a pulley on the 
 cylinder shaft. The worker driving pulleys are on one side of the machine, and those of the clearers on the 
 other. The setting of the rollers is important, and it is necessary to make special provision for it. Fixed on 
 the framework of the machine, forming the base S, Fig. 46, is a semicircular frame, which is known as the 
 "bend." On this are fitted a number of brackets, the centre lines of which are radial to the cylinder centre, 
 each forming a bearing for one end of the roller spindle. Mr. John Mason employs a special form, which is 
 produced by planing the soles or feet of two of the frames, bolting them together and turning them on the edge. 
 
 Fig. 43. FlG « 49 - 
 
 They are reduced to the required diameter to permit of the necessary setting, and when separated form half a 
 circle. Each of these is bolted to the upper edge of the frame, S, which is planed to receive them, and 
 thus a firm and accurate surface is provided for the roller brackets. The latter are constructed so that one 
 portion of them can be set radially, or the whole bracket may be moved, if desired. Semicircular ribs are 
 formed on the side of the bend, through which setting screws, locked on each side of the rib by nuts, pass,. 
 In this way the necessary setting can be easily obtained. As the machine is worked the wire points wear, 
 and, when they are sharpened, the relative distance of the centres of the cylinder and rollers is not disturbed. 
 In other words, the space between the points of the teeth on the rollers and those on the cylinder remains 
 unaltered. It is absolutely essential that a definite distance shall be preserved, and means of setting the 
 
THE CARDING MACHINE. 
 
 61 
 
 rollers and clearers readily are imperative. This subject is treated at greater length at a later stage, when 
 the revolving flat-card is described. A bracket made by Messrs. Lord Bros, is shown in Fig. 49, and it will 
 be seen that ample provision is made for both lateral and radial adjustment. 
 
 (114) The whole of the worker and clearer rollers are covered by a case, as are also the doffer and 
 licker-in. The emission of fly into the room is thus prevented, and its production materially diminished by 
 the reduction of the disturbance of the air set up by the rapid rotation of the cylinder. The roller and 
 clearer machine is often made with two cylinders, being then known as a " double " card. The cotton, after 
 passing all the rollers placed above one cylinder, is transferred to the second by means of a small drum, 
 similar in construction to a doffer, and known as a "tummer." The second cylinder bearings are fastened 
 to the framing of the machine, which is made continuous, thus giving great solidity and strength. Double 
 carding is undoubtedly effective in producing a good sliver, and is used in some cases where yarns of a good 
 quality and as fine as 60's are spun. There has been, and still is, a controversy going on as to the respective 
 merits of the various systems of carding, about which a good deal coul I be said. In the meantime 
 it is sufficient to note that many spinners continue to put down roller cards in preference to some of the 
 newer types. 
 
 (115) At the present time the "revolving flat" machine is the favourite one, and is being widely adopted. 
 The peculiarity of its construction consists in the employment of a number of T shaped bars or ' flats" 
 extending across the top of the cylinder, and sustained at each end by the bend, or a plate attached to it. 
 They are coupled by an endless pitched link chain, by means of which they are slowly traversed at a rate 
 of about an inch per minute, in the same direction as the revolution of the cylinder. Referring now more 
 particularly to Fig. 44 it will be seen that during the passage of the cotton from the licker-in to the doffer' it is 
 carried below the flats N, each of which has its underside covered with wire clothing. The chain passes round 
 carrier pulleys, one of which is arranged to drive it, being itself driven at a regular speed in the manner shown. 
 Each flat is thus carried over a certain portion of the circumference of the cylinder, and is then turned with its 
 wire face upward. When this happens, an oscillating comb P strips the teeth, and they are then brushed out by 
 the brush Q, usually formed with spirally arranged bristles, and sometimes made of wire. The flats vary in 
 number from 89 to 110, of which there are from 40 to 50 always working. As they are specially constructed, it 
 will be as well to describe the method of doing so at length. 
 
 (116) The flats are made of a T section for the greater part of their length, but have flat surfaces formed 
 at each end, as shown in Fig. 51. On these surfaces they travel, and are sustained in their course by the 
 bend. The width of each flat is usually from l^in. to lfin — the narrower ones being generally preferred — 
 and the length varies with the width of the cylinder. The underside of each flat is made quite level, in 
 order to afford a surface from which the various mechanical operations can be conducted. As the wire clothing 
 is fastened to this face it is obvious that, by making it the base of all subsequent treatment of the flat, a 
 decided advantage is obtained. The first operation is that of milling two surfaces at the upper side of each 
 end of the flat, at the same time trueing up the faces of the ears to which the chain is attached. A double- 
 
62 
 
 THE CARDING MACHINE. 
 
 ended machine is used, fitted at each end with an instantaneous grip chuck, at the bottom of which is a steel 
 face on to which the ends of the flat are placed, the flat having been previously stretched and straightened. 
 The flat is then cramped down, and the cutter brought into operation. The flat is placed on the faces thus 
 formed in the next machine, which is constructed with chucks at the end of two long radius arms. A cross 
 spindle has a worm fitted on it, which gears with a segment at the end of the arms, and by revolving which 
 the flat is brought under the cutters, and has a hollow cut into it of the desired radius. The flat is then 
 chucked edge up and milled by a cutter on its upper side at the ends, so as to provide the necessary clearance 
 for the chain. The next operation is to cut out, by means of a similar machine to the one with the long 
 radius arms, the under surface of the flat end, which had been treated by that machine, so as to leave two 
 surfaces on which the flat travels, the radius arms in this case being shorter. These surfaces have two 
 objects — to lessen the friction when the flat is travelling, and to allow of the flat having the necessary heel 
 given to it. The flat is then cramped down on the surface thus formed, and the snugs are drilled by a 
 double-ended machine fitted with an automatic motion for withdrawing the drill. By the same machine the 
 hole is tapped, the tap reversing when it has gone the requisite depth. After drilling the flat along the 
 edges in order to enable the clothing to be fastened, it is complete so far as its treatment by machines is 
 concerned. 
 
 (117) There are one or two things to notice in respect to the operations just described. The first is, that 
 all the faces are formed from that on which the wire clothing is subsequently placed, and that consequently 
 the flat when traversing is provided with working surfaces which ensure it being parallel to the cylinder all 
 across, provided the bends are correctly set. This is, as will be seen, an important point. Again, the whole 
 of the surfaces to which the chains are attached are true with the flat ends, so that there is no tendency to 
 pull the flat askew. Having thus constructed, by the means indicated, the flat as perfect as is possible 
 by machine, it is necessary to put the "heel" in, and also to correct any twist which may have arisen by 
 the spring of the flat whilst being milled. There are two methods of testing this point, one mechanical and the 
 other electrical. As will have been noticed from the description of the method of milling the flats, two 
 parallel surfaces are formed at the upper and lower side of each end of the flat. It will be evident that, if 
 the flat is placed upon either of these surfaces and tested by a suitable apparatus, the other surface should 
 be as nearly as possible parallel with the first. In order to see that this is so, the flat is placed face 
 downwards on two steel faces perfectly parallel with each other. At each end of the table carrying these faces 
 is an indicating apparatus consisting of a graduated scale and two pairs of compound levers, so arranged that 
 a slight inaccuracy is multiplied to a large extent. If, therefore, the flat is laid on the blocks and the points 
 of the levers are allowed to fall on the four surfaces left after the flat is milled by the long and short radius 
 machines, the setter can see at a glance if the surfaces are accurately formed. In practice, the two ridges or 
 surfaces at the front of the flat — that is, the edge nearest to the doffer end of the card — are reduced somewhat 
 by hand, thus throwing up the back edge. This is what is known as giving the " heel " to the flat, and its 
 object is to leave a slight space between the wire points of the flats and cylinder at the back of the 
 
THE CARDING MACHINE. 
 
 63 
 
 flat, while at the front these are as close as possible together without touching. The object of this is to 
 prevent a rolling up of the strippings and cotton fibre, which has been found to exist where the wire at the 
 back or " toe " of the flat nearly approached that of the cylinder. The heel having been given the flat is then tested 
 by the apparatus described, but instead of all the fingers corresponding, this only occurs with the two which 
 are in contact with the same surfaces on each edge of the flat. One pair registers the variation caused by 
 the heel and should correspond, while the other pair registers the position of the untouched surface and must 
 also correspond. This device is the one most commonly used, and gives very accurate results. Messrs. 
 
 Fig. 44. 
 
 Howard and Bullongh adopt an electrical test which is also said to give good results. Similar devices are 
 used in some cases to set the bends accurately with the cylinders ; in others a simple scriber or pointer being 
 used and set down, so that a small slip of steel can be easily moved across the bend under its point. As 
 the latter is carried in a bracket fixed to the cylinder the bend can easily be tested all round. Messrs. 
 Howard and Bulluugh use an electrical scriber, contact with which rings a bell, and thus indicates the point 
 requiring adjustment. The use of the graduated indicators as shown in Fig. 60 enables this to be easily made, 
 and delicacy of adjustment attained. 
 
64 
 
 THE CARDING MACHINE. 
 
 (118) As the function of the flats is to remove by means of the wires attached to them the short fibre 
 and nep, the more accurately the distance between the wire clothing on them and the cylinder is preserved, 
 the better will be the effect produced. In order to attain this object it is necessary that the flats should 
 be specially constructed and carried. A reference to Fig. 51 will show the construction of the flat, which is 
 so finished (as was explained in paragraph 116) that the faces upon which it travels are parallel with the face 
 upon which the wire is fixed. Thus, if the flat is borne upon a surface which is couceutric with the surface 
 of the cylinder, but so far from the centre of the latter as to compensate for the length of the wire on both, 
 and provided that the two wire surfaces are accurately and evenly ground, it will be clear that over the 
 whole of the surface there will be the same distance between the points of the wires. This is the coudition 
 which is absolutely the best for carding, but its constant maintenance is the problem. The flat course may 
 be either formed on, or attached to, the frame O, and in either case is technically termed 
 the "bend." This phrase is often very indifferently used, and is sometimes applied to the framing O 
 when the latter is acting as a support for the fiats, and sometimes to the surface attached to or borne by it 
 for the same purpose. It ought, however, to be insisted on, for the sake of clearness and definiteness, that 
 the phrase "bend" should only be applied to that portion of the mechanism upon which the flats actually 
 travel. If it be assumed that a machine is in condition for starting for the first time, that the surface of 
 the flit end upon which it travels is set back from the flat wire surface \ inch, aud that the wire projects 
 \ inch beyond the cylinder surface, there is a necessity for a circle with a radius of 26 inches. It is, of course, 
 perfectly easy to form a track on the edge of the frame O, which should be accurately machined so as to be 
 quite concentric and of the radius required, in which case the required distance between the two wire surfaces 
 could be perfectly established. But, during the operation of the machine, the wire points become blunted and 
 no longer deal with the cotton as efficiently as they ought. This necessitates their re-sharpening by grinding, 
 which involves a reduction of the size of the circle described by the points of the cylinder wire, and an 
 enlargement of that described by the covering of the flats. As has been pointed out, it is better that the 
 two wire surfaces should approach one another as closely as possible without touching, the most effective results 
 being obtained in this way, and it therefore becomes necessary to find some method of lowering the flats in 
 order to re-establish these conditions. This is precisely the difficulty which has to be overcome. It is perfectly 
 clear that any flat course formed on the frame O cannot be so adjusted, and it is essential that some other 
 adjustable surface sustained by O shall be found. If for a minute or two the work to be done is considered 
 it will be seen that there is a very difficult problem to solve. If a circle is struck 51 inches in diameter, 
 and at the same time a second circle 52 inches in diameter is described, from the same centre, some idea can 
 be obtained of the actual conditions of the case. Supposing that the circle 51 inches diameter is reduced to 
 50£ inches (this representing the extreme variation in size arising from grinding), it will be at once observed 
 that the dropping of the 52 inch circle in a radial line will be followed by the destruction of its concentricity 
 with the other. In the case thus supposed the smaller circle represents the surface of the wire on the cylinder, 
 while the larger one represents that of the ring upon which the end of the flats traverse. Now, while the 
 
THE CABDING MACHINE. 
 
 65 
 
 former is reduced with ease by grinding, the latter is not so easily reduced, and the action of moving it 
 nearer the centre, without its reduction, simply means that its centre is moved to the same extent, while the 
 centre of the ground surface remains constant. In other words, the concentricity of the two circles is 
 destroyed. As the concentricity of the flat course with the cylinder is absolutely essential, in order to get 
 that close approach over the whole of the wire surfaces which has been shown to be necessary, it follows 
 that its destruction implies ineffective and bad carding. 
 
 (119) The arc occupied by the flats in their traverse varies from 120 to 150 degrees, speaking roughly, so 
 that in some way or other a flat course of that length, capable of adjustment, requires to be provided. By far 
 the most common method of providing this is to fasten to the side of the machine at the upper edge of the frame 
 O a flat plate, shown in Fig. 50, with its upper edge forming a segment of the circle required. This arrangement 
 is the invention of the late Mr. Evan Leigh, and has been widely adopted. The shape of this plate, so far as its 
 depth is concerned, is so arranged that it can be sprung or compressed into a smaller circle with the minimum 
 amount of difficulty and strain. This is what is known as a "flexible " bend, and is in wider use than any other form. 
 It is attached to the frame side by bolts, slots being formed in the bend casting at each end through which the bolts 
 pass. It will be seen that the slots allow of a considerable range of movement in the bend, which is made use of 
 
 Fig. 50. 
 
 in setting it after the wire has been ground. The setting is effecled by springing the bend by means of screws, 
 until a circle is formed equal to that required to enable the wire surface of the flats to be concentric with the 
 wire surface of the cylinder. As a matter of fact, the setting is done by the carder by sound and by the use of 
 a gauge, the combination of which permits him to ascertain fairly accurately that the flats are in a good working 
 position. When the bend is set, it is locked against the frame by the bolts, and stops, which are placed midway 
 between the points of support, are brought up to the under edge of the bend. The object of these is to uphold 
 the bend, so as to avoid deflection from the weight of the flats. As the cylinder, which weighs 9 or 10 cwts., 
 revolves always in one direction at a steady rate of 140 to 170 revolutions per minute, and as the pull of the 
 driving strap is usually towards the front, it will be perceived that a tendency, at least, will always exist towards 
 wear in the brasses at their front side. Thus it is possible that in addition to the necessity for providing for the 
 lessened circle, it may be also requisite to take into account the movement of the centre in a horizontal direction. 
 The latter difficulty, however, has been to a large extent overcome by the elongation of the bearings, which are 
 now much longer in proportion to the diameter than was the case formerly. The special construction of the 
 bearings in order to resist the action of wear or to afford means of setting will be treated at a later stage in this 
 chapter, 
 p 
 
66 
 
 THE CARDING MACHINE. 
 
 (120) It has been the ordinary practice to place the flexible bend outside the framing, but it is becoming 
 the practice to decrease the width of the cylinder, and consequently the length of the flat. The cylinder 
 is now ordinarily made 37in. wide when fed from 40in. laps, the lap being narrowed as it approaches the 
 feed roller by specially placed and designed guides. By diminishing the length of the flat, the tendency to 
 deflection is also lessened, and, in addition to this, an improvement occurs in the selvedge of the sliver. It 
 will be seen that in diminishing the width of the lap 3 inches, it is only possible to do so by squeezing in its 
 edges or folding them over somewhat. Thus any thin place on the edge of the lap is thickened, and the 
 sliver when produced has a better selvedge. This advantage is partially derived by the means mentioned, 
 but there is a further cause of ragged selvedges, to which a good deal of attention has been given. Usually 
 between the edge of the cyliuder and the bend a space has been left, through which, when the cylinder is 
 revolving, a current of air is induced. As the cotton is held in the wire clothing, which comes right up to 
 the edge of the cylinder, the suction thus caused draws it out and causes ragged places. Messrs. Ashworth 
 Brothers remedied this defect by the employment of a circular shield about the height of the cylinder wire, 
 which is ; fixed to and revolves with the cylinder. This gap is now entirely closed by all makers. 
 
 (121) Messrs. John Hetherington and Sons adopt the plan shown in Figs. 51 and 52, which are cross 
 sections of the cylinder, bends, and flats. Fig. 51 represents the old method of construction. The flat T is 
 sustained by the flexible bend Z, which is controlled by the setting screws W, and is attached to the 
 
 Fios. 51 and 52. 
 
 framing Y by the bolt shown. The cylinder V in this case is 40in. wide, and between it and the fixed bend 
 a space is left, which is filled up by the introduction of the wood packing X. The latter is fastened to the 
 fixed bend Y by screws as shown. The new plan is shown in Fig. 51. In this case the flexible bend Z is 
 fastened on the inside of the framing Y, the setting screw W being placed as shown. It will be seen that 
 the ed<*e of the cylinder V comes close up to the bend Z, and no induced air current is possible. The cylinder 
 
THE CARDING MACHINE. 
 
 67 
 
 is reduced to 37in. wide as previously mentioned. The same firm adopt a very good method of dealing with 
 the flexible bend, which is shown in Figs. 53 and 54 in transverse section and side elevation respectively. 
 On the cylinder shaft a segmental rack V is fixed, which is driven by means of worm gearing, and the bands 
 W U from the pulley X placed on the shaft. This also drives a spindle Z, borne in frames attached 
 to the cylinder, on each end of which is a milling cutter. The cutters are kept in contact with the 
 flexible bend Y, which is made a little larger than is necessary, and is bolted in its place after being 
 accurately set. It is weighted with suspended weights R T, together equal to the weight of the flats when 
 
 J.N. 
 
 Figs. 53 and 54. 
 
 resting upon the bends, and attached to the bends at points midway between those at which they are set. 
 In this way the actual conditions of working are established as nearly as possible before the mechanism is 
 started. On commencing operations the milling cutters are at one end of the bend, and the cylinder is slowly 
 revolved so as to traverse them over its surface. In this way it is accurately shaped to 
 suit the conditions of the case, and is as true as a fixed bend could be made. Of course, as soon as the 
 bend requires to be reset it is necessary to adopt the ordinary plan, but the treatment described undoubtedly 
 facilitates subsequent setting. 
 
 (122) The plan adopted by Messrs. Piatt Bros, and Co. Limited is shown in Figs. 55 and 56, the former 
 being the new, and the latter the old, method. A perspective view of this machine fitted with the new bend is given 
 in Fig. 57. Dealing with Fig. 56 first, the cylinder A is separated from the framing B by the distance shown, this 
 being filled up by the wood packing G. The flexible bend C is fastened to the framing on the outside, and is set 
 by the screws shown. The cylinder in this case is 40 inches wide, and it will be noticed that the arms of the 
 cylinder are level with its edge. In Fig. 55 the cylinder A is recessed so that it projects beyond the arms 
 
68 
 
 THE CARDING MACHINE. 
 
 sufficiently to permit the bend B to come within the recess. The flexible bend C is attached in the manner 
 shown to B, and is fulcrumed on the pin in its centre. The setting is obtained by means of the screws, as in the 
 previous case. The clothing on the flit is secured at the ends by the clip or plate F, shown separately in side 
 view and plan, and a thin plate E is fastened to the cylinder by which means the ingress of air is quite prevented. 
 There is also a reduction in th? widths of the cylinder and machine, in the latter case about 8 inches, so that a 
 machine fed from a lap 45 inches wide occupies only the same space as a machine made on the old principle 
 with a 40 inch lap. 
 
 Fig. 57. 
 
 (123) Before leaving this point there is one thing to be noticed which is important. A reference to either 
 Fig. 52 or 56 will show that the chain is attached at the end of the flat immediately over the bend, whereas in 
 Figs. 51 and 55 it is further from it. The former method is best, as being less likely to deflect the flat, and is 
 being adapted to the new construction by both the firms named. 
 
 (124) The construction of machines with flexible bends, in spite of many objections which are continually 
 being alleged, continues to be large. It is held by some spinners and machinists that the necessity for adjusting 
 the flexible bend manually from three points is faulty, and that it is better to provide mechanism whereby the 
 
THE CARDING MACHINE. 
 
 69 
 
 setting can be made by positive means and from one point. Several patented arrangements with this view have 
 been made, and illustrations of most of them are given. In most cases a flexible bend— somewhat differently 
 constructed — is used, although it does not always have that name given to it. 
 
 a 
 
 J.N. 
 
 Figs. 55 and 56. 
 
 (125) In Figs. 58 and 59 the arrangement used by Messrs. Dobson and Barlow— to which the name 
 " Simplex " is given— is illustrated. Fig. 59 is a side elevation of that portion of the machine where the 
 bend is applied. Fixed to the framing Q of the machine are four brackets P, O, M, L, the last three of which 
 are specially curved on their upper edge, while P is shaped to a curve on its inner surface. Fixed in the metal 
 strip K— which is practically the flexible bend— are four pins, each bearing an anti-friction runner, which are kept 
 in contact with the edges of O, M, and |_, and with the inner surface of the bracket P respectively. 
 Attached to K, at the opposite end to P, is the crank S, oscillating freely upon a pin fastened in the frame Q. At 
 the end of the bend K, where it is controlled by the bracket P, and, on its inner edge, a toothed rack is formed, 
 with which a small spur pinion engages. The pinion is fixed on the axis of a worm wheel R, rotating on a pin 
 fastened in the framing Q. With the wheel a worm R 1 gears, and this can be rotated by a handle to any desired 
 extent. When the bend K is moved by means of the rack in the direction of the arrow, it is put into tension, and 
 
70 
 
 THE CARDING MACHINE. 
 
 the anti-friction bowls are drawn down on to the surfaces of the various branches. A glance at the detached 
 sectional view given will show that the various brackets overlap the bend K, which slides between them and the 
 frame Q. The position of the bend is arranged so that between it and the edge of the cylinder there is no open 
 space left. 
 
 (126) Having thus described the actual mechanism a few words can be said about Fig. 58, which is a 
 diagrammatic representation of it. The circle A B is that formed by the edge of the bend or plate K when 
 it is at its highest position-that is, when the wire is unworn. The circle D E is that described by the 
 edge of K when it has been drawn down to allow the flats to come nearer the cylinder. The small black 
 dots represent the pins fixed in the bend K. When the latter is moved by the action of the rack and 
 pinion, the end of the crank S follows the path of the circle described by it, moving from B to E during the 
 time the entire depression of the plate is made. The anti-friction bowls in the same period travel in the 
 paths shown, and it will be noticed that each of the curves is differently shaped. If the inner circle F G 
 be supposed to represent that occupied by the edge of K after the crank end has travelled from B to G-a 
 half circle-the curves L M O P would, if prolonged, be of the shape shown. Having obtained them in the 
 manner thus described on paper, they are actually reproduced on the brackets by a milling machine fitted 
 with a copying arrangement. By forming an indicator scale on the worm wheel R the amount of movement 
 of the bend K can be regulated as desired to any degree of accuracy. The proportions of the worm, worm 
 wheel, pinion, and rack, are so arranged that the advance of the wheel ^th inch will raise or lower the bend 
 
 k 2oW tn inch - This method is ver y sim P le and effective - 
 
 (127) The arrangement adopted by Messrs. Howard and Bullough has the central idea of the employment 
 of inclined surfaces, by withdrawing one of which the other can be lowered. It is shown in front elevation 
 in Fig. 60 and in section in Fig. 61. The fixed bend has formed on one side of it a broad flange, which 
 
 Fig. 60. 
 
 is turned to a true circle on its upper edge. Upon this a segment of a ring A is placed, which can 
 be slid in or out by means of the screw B and lock nuts. The back nut is riveted to the index 
 
Figs. 58 and 59. 
 
THE CARDING MACHINE. 
 
 73 
 
 disc E, which is divided into 36 spaces, the front lock nut securing the arrangement after setting. In front of the 
 dial plate E an indicator finger D is fitted, which points out any alteration of the circular dial plate E. Upon the 
 upper surface of the ring A a second ring C of a smaller section is placed. C is accurately turned on its inner side 
 to correspond with the inclination of the upper surface of A, and on its outer edge is horizontal, so as to form 
 a course for the end of the flat. The ring C is pressed down upon A by the weight of the chain of flats 
 as they pass over it. The action of this mechanism is easily understood. By withdrawing the segmental 
 
 Fig. 61. 
 
 ring A, by means of the screw B, the flats are lowered, the degree of their depression being sufficient to 
 preserve the necessary distance between their wire teeth G and those F upon the cylinder H. The 
 adjustment can be made in either direction, and the graduation of the dial E enables it to be finely made. 
 In this case also, as shown in Fig. 55, the gap at the end of the cylinder is closed by bringing the flange 
 of the fixed bend close to the edge of the cylinder. 
 
 (128) In Figs. 62 and 63 a plan invented by Mr. Thomas Knowles, of Bolton, and made by Messrs. John 
 Tatham Limited is illustrated. This consists of the employment of a wedge-shaped segmental ring, which 
 
 Fig. 62. 
 
 rests upon the upper edge of the fixed bend, and can be drawn along it by means of the screw shown. 
 The ring is pierced by a number of holes of decreasing diameter, and a small slit is made through the web 
 
74 
 
 THE CARDING MACHINE. 
 
 left between the lower part of the hole and the inner surface of the ring. The latter is thus rendered 
 easily flexible, and the mere weight of the flats is sufficient to make it accommodate itself to its supporting 
 surface. The ring is shaped so that the inner edge forms part of a spiral curve, shown diagrammatically 
 in Fig. 63, and with its outer edge levelled so as to bear the flat. In like manner the edge of the fixed 
 bend is shaped to the spiral curve, both of these being obtained by the use of a circular milling machine 
 fitted with the necessary shaping mechanism. The spiral curve to which the two surfaces are formed would, 
 
 if continued far enough, terminate in the centre of the cylinder, so that if it were possible to traverse the 
 ring far enough it would actually cross that point. The action of setting this mechanism is simple. The 
 ring is drawn downwards by the screw, and its outer edge thus moves nearer the centre of the cylinder to 
 an extent corresponding with that of its traverse. Any adjustment desired can thus be given in either 
 direction. 
 
 (129) The machine made by Messrs. Ash worth Bros., of which a perspective view was given in Fig. 44, 
 is based upon an entirely different principle. Before passing on to describe it, it is only fair to say that to 
 this firm belongs in great measure the great advance which has been made in the construction of this form 
 of machine. They recognised the importance of accurate mechanical construction, with the result that they 
 produced a machine which could be run at much higher velocities than had hitherto been thought possible. 
 Referring now to Fig. 64, on the top of the fixed bend B, a number (about 15) of thin steel bands E are 
 placed, being held at one end by the stud G and kept in tension by the screw C, thus being firmly drawn 
 into position. The bands are of various thicknesses, from ^-th to T ^th inch. The end of the flat traverses 
 on the top band F, and any of them can be removed and replaced by a thiuner one. Thus the concentricity of 
 
 Fio. 63. 
 
THE CARDING MACHINE. 
 
 75 
 
 the flat course is preserved, provided that the amount of wear to be taken up corresponds with the difference 
 between the thickness of the band taken out and that replacing it. It may happen that the amount of 
 wear to be provided for is not enough to justify the removal of the band, which, on account of the necessary 
 labour involved, takes some little time. In order to afford a ready means of making the correction, and at 
 the same time avoiding the replacement of the bands, the makers have adopted the bold but ingenious plan 
 of forming the cylinder bearing so as to be adjustable vertically. Referring now to Fig. 64 it will be 
 noticed that the engine bend and the pedestal are cast in one piece, bolted on to the lower frame. The 
 pedestal cap is fastened by means of set screws, but the bottom brass can be lifted by means of the 
 vertical screw shown in dotted lines. This screw is fitted into the pedestal, which is tapped to correspond, 
 and has at its lower end a ring which is divided into 100 parts on its circumference. An indicator finger 
 is fitted so that the ring can set to any of the divisions as desired, and when so set the screw can be 
 
 Fig. 64. 
 
 locked by a lock nut. B3 7 proportioning the pitch of the thread it is clear that any desired lift can be 
 obtained. The pitch adopted being ^th of an inch, a revolution of the screw one division on the ring- 
 would mean a vertical movement equal to T xnro" tn °f an m °h- Now it is quite true that in a sense any 
 vertical movement of the cylinder destroys the concentricity of the flats, but this, after all, is a relative 
 matter. If reference is made to a drawing showing the arc occupied by the flats in various positions, it will 
 be seen that with a total fall of fths of an inch the difference between the ends and centres of the arcs 
 described does not amount to a great deal. Therefore if the cylinder was raised by the screw about ^th inch 
 it would not amount to an inaccuracy of any magnitude. But as the thickest band is only g^th of an inch 
 thick it would be most likely that instead of lifting the cylinder anything like ^th inch a band would be taken 
 out and the wear thus compensated for. The raising of the cylinder ^th of an inch would practically 
 mean that the setting of the flats would remain unaltered. 
 
76 
 
 THE CARDING MACHINE. 
 
 (130) In Fig. 65 is given a side elevation of one side of a carding engine, in which the bend is made 
 in an entirely different manner to any previously described. This is really a revival of a plan which was 
 suggested many years ago by James Smith, of Deanston, but which was dropped on account of certain 
 difficulties in adjustment which are now overcome. The machine as illustrated is made by Mr. Samuel 
 Brooks, and is nearly the latest form put on the market. The pedestal A has a circular flange formed on 
 it about midway of its length, to which a bush C can be bolted by the three bolts M. The bush is 
 placed over the inner boss of the pedestal, and can be set in its proper position, which may be ascertained 
 
 at any time by the pin J, passing through a hole in the pedestal flange and one in the bush when the 
 latter is quite concentric with the cylinder, and only then. On this bush a wheel D, with a flat periphery, 
 is fitted and revolves. The periphery E of this wheel sustains the flats F, the traverse of which cause it to 
 rotate at precisely the same circumferential speed as that of the flats. The friction of the flat ends is in this 
 way avoided, which is claimed as one of the important features of the new arrangement. When the machine 
 is new the diameter of the wheel D is of the exact size needed to sustain the flats, and keep the wire points 
 the requisite distance apart, theoretically, T xroo tn ^ nc ^- But wnen the wire has worn and has been re-ground, it 
 
THE CARDING MACHINE. 
 
 77 
 
 is, of course, necessary to reset the flats. This is effected by means of the milling cutters G, placed as 
 shown, which can be set in by the arrangement shown in side elevation in Fig. 66, and in partial section 
 in Fig. 67. The cutter G is fixed on a shaft borne by the bracket F, which is attached to the bend, and 
 is moved inwards in a radial line by the screw H, the latter being arranged on the micrometer principle. 
 The screw is threaded 25 to the inch, and the worm wheel I has 20 teeth. The rotation of the latter one 
 tooth implies a corresponding movement of the cutter G ^j^th mcn - By subdividing the disc K on the spindle 
 carrying the worm |_, as much as desired, the cutters can be moved in or out to a very slight but 
 ascertainable degree. A similar arrangement is fitted to the bush C, by which when unlocked it can be 
 lowered as desired. 
 
 Figs. 66 and 67. 
 
 (131) In setting, or, rather, in lowering the flats — because that is practically all that can be done by 
 this arrangement — the bush is unlocked and the pin J taken out. It, with the wheel, is then lowered until 
 the wires on the central flat and those on the cylinder can be heard to click. A careful note is taken of 
 the amount which the bush has been lowered, and it is again raised to its central position and locked. 
 Suppose that the amount was ^l^th incn — a ver y extreme supposition — then the distance the flats have to be 
 lowered is that distance less TT jVtfth incn > tne standard distance between the wire teeth, or ^^th inch. The 
 disc K is therefore revolved 1 J times, which moves the cutters G inward to that extent, and, in consequence, 
 the diameter of the wheel D is reduced, so as to provide a course for the flats of the exact size required. 
 The cutters G are driven by a band from the cylinder shaft, and the wheels C are traversed as usual during 
 the process of reduction. This arrangement is a novel one, but it is clear that, if successfully carried out, 
 it provides a perfectly concentric flat course. 
 
 (132) Before proceeding further, and dealing with another form of machine, a few words may be said on 
 the subject of setting the flats. It has been shown that in many cases a delicate indicator and micrometer 
 
78 
 
 THE CARDING MACHINE. 
 
 screw is fitted, by which it is claimed the most exact settings can be made. There can be no dispute as to 
 the power to do this which is thus provided, the only question is whether the circumstances of the case call 
 for it, and whether in actual work any such accuracy is obtained and maintained. There are four points 
 where adjustment is required in a carding engine. These are between the dish feed plate and licker-in • 
 between the licker-in and cylinder ; between the cylinder and flats or rollers ; and between the doffer and 
 cylinder. Messrs. Piatt supply three guages, respectively "013, -Oil, 007 of an inch thick. The finest of 
 these it will be seen is youths of an inch thick, so that in this case at least the theory as to setting to 
 xinnyth i s disregarded. In adjusting the flats, by far the commonest plan is to do so during the time the 
 mill is standing, when everything is quiet. The bend is then dropped until the guage which it is intended 
 to use can be pushed between the two sets of teeth. If it is afterwards desired to get very fine setting, 
 the bend is lowered until the slow revolution of the cylinder produces a "click," which shows that the 
 teeth of the cylinder and flats are in contact. A little elevation is given to the bend so as to leave a 
 space between the teeth. A skilful setter can tell at any time by the "touch" of the teeth if they are 
 too closely set, but the vibration existing during working hours may disturb his observation. When an 
 indicator is used the practice is to establish the clicking point, and then turn back the screw until the fiats 
 are raised the desired distance. 
 
 (133) It is questionable whether it is possible to maintain so accurate a setting during actual work 
 over a long period after wear has begun. It is hardly likely that many machines continue to work with 
 this close setting. The practice is rather the other way. Wider spaces than Oil are common, and it is 
 unreasonable to expect anything else. The function of the wires on the cylinder being to seize by means 
 of their points the fibres of cotton and bring them under the influence of the flats, it is obvious that the 
 question of efficient carding turns very largely upon the charge of cotton in the wire. If light carding is 
 taking place — that is, if little cotton is passing over the cylinder during a fixed time — the delicate setting ia 
 both possible and desirable, as it would result in the cotton fibres being thoroughly combed from end to end. 
 But if the cotton is fed rapidly, so that the cylinder becomes highly charged and its surface covered with a 
 comparatively thick fleece, a too close setting would result in considerable damage to the fibre. As the 
 prevailing practice is generally based upon commercial considerations, the last is the more usual condition 
 existing, and extremely close setting is in this case both impracticable and undesirable. 
 
 (134) Even if this extra fine setting named were adopted there is nothing to show that it cannot be attained 
 with the flexible bend. True, the setting of the latter iuvolves a little more labour, but is it quite demonstrated 
 that it is not necessary labour 1 The construction of flexible bends is now such, as has been shown, that their 
 flexure, fths of an inch, is made with absolute ease and accuracy by means of the setting screws. There is an old 
 adage that " the proof of the pudding is in the eating," and no candid person will contend that carding engines 
 made with flexible bends of the Leigh type produce either worse slivers or make more waste than others. On the 
 other hand, it is only fair to say that the converse of this proposition holds true, and that good slivers are obtained 
 from machines made with indicators and special setting appliances without more waste being made than in the 
 
THE CARDING MACHINE. 
 
 79 
 
 case of flexible bend machines. It is, however, more than probable that the system of setting by the ear is adopted 
 in every case of successful carding. 
 
 (135) A further consideration in connection with this question is the problem of adjustment after the cylinder 
 bearing has worn so as to alter the position of the centre of the cylinder. In this case the cylinder can be 
 followed by the flexible bend and concentricity re-established, whereas, in the case of other arrangements which 
 are based upon an unyielding surface attached to the framing, no such practice is possible. In this case it is 
 necessary to provide a means by which the cylinder centre can be restored to its original position. The methods 
 of doing this will be touched upon at a later stage. 
 
 (136) Before leaving the question of setting, it may be stated that the distance between the licker-in and the 
 dish feed-plate is regulated according to the quality of cotton treated. Ordinarily the thickest guage 013 is used by 
 Messrs. Piatt, but if the cotton is deficient in strength the distance is increased by the thickness of the medium 
 guage, or in all is made '024 inch. The licker-in is set by the medium guage "Oil, which is slipped easily between 
 the licker-in teeth and those on the cylinder. The space left between the doffer and cylinder teeth is smaller, the 
 finest guage '007 being employed in this case. 
 
 (137) In paragraph 132 it was stated that setting was mainly conducted by means of a guage and by ear. It 
 is often desirable to ascertain during work how the flats and cylinders are set relatively, and it is highly desirable to 
 do this without disturbing the flexible bend. Up to quite recently this could only be done by guaging at each end 
 in the ordinary way, and in the centre by the ear. Messrs. Piatt Brothers and Company have, however, devised a 
 method by which the setting of the flats can be instantaneously ascertained, and power is thus given to a spinner 
 or overlooker to check the setting. In the flexible bend, at four points, narrow oblong slots are formed by casting, 
 and are made of such a width that the carder's guage can be easily slipped between the cylinder and flat teeth, 
 whatever may be the condition of the wire. The slots are, during work, stopped by plugs, which can be instan- 
 taneously withdrawn. The makers state that they have made careful tests to ascertain whether the presence of 
 the slots affects the deflection of the bend, but do not find any ill effects. This is an extremely simple but very 
 valuable improvement, and affords an opportunity of checking the setting, which cannot but be beneficial. 
 
 (138) The third form of carding engine is that known as the "Wellman," or "Self Stripper." It is 
 extensively employed on the Continent, and in the United States. It is the direct descendant of Paul's 
 machine, inasmuch as it is based upon the principle of the employment of fixed flats superimposed upon the 
 cylinder. In the early days of carding machines the flats surrounded a certain portion of the cylinder, and 
 when they became charged with fly were lifted and stripped by hand. This practice was found to be very 
 inconvenient, and a method of raising the flats automatically was therefore welcomed. For the finer counts 
 of yarn cards on this principle were extensively employed in England, but the improvement of the revolving 
 flat card has displaced it, and in this country at least it may be looked upon as an extinct type. The 
 mechanism of the Wellman is ingenious, but for the reasons stated only a brief description of it will be 
 given. Students who are interested in the subject can study it in the works of Mr. Evan Leigh in 
 English, Mr. Neiss in German, or in one or two French books. 
 
80 
 
 THE CARDING MACHINE. 
 
 (139) The self-stripping card as made by Messrs. Dobson and Barlow, is shown in side view in Fig. 68. 
 The flats A cover the surface of the cylinder for about the same extent as in the revolving flat card. They 
 are, however, stationary, and rest upon brackets B, each of which is capable of separate and delicate 
 adjustment. On the cylinder shaft C an arm or lever D is placed, which is free to oscillate as required, 
 its position being regulated by a pinion engaging with the rack E. The motion is driven from a grooved 
 pulley, fixed on the cylinder shaft, which gives movement to a wheel behind the catch plate or wheel F. 
 A sliding jaw traverses in the long slot at the top of the arm D, and is raised by a cam fixed on the 
 spindle of the wheel F. When this upward movement of the jaw takes place the flat is lifted and held 
 tightly between it and a fixed jaw formed on the arm D. While in this position the lever G, hinged at 
 
 Fig. 68. 
 
 its lower end to D, is drawn inwards, and as it carries a wire stripping brush H it causes the teeth of the 
 latter to pass through those of the raised flat, and thus remove the diit and short fly. Immediately one 
 passage is made the brush returns, and the flat is at once lowered into its position above the cylinder. By 
 an extremely ingenious arrangement of mechanism the flats are not stripped consecutively, but are arranged 
 to be stripped oftener near the licker-in than at the doffer end. The reason of this is obvious. By virtue 
 of their position the earlier in the series of flats retain more dirt, and therefore require stripping oftener. 
 
 (140) From the mechanical point of view, the Welhnan card and its predecesors will repay careful study, 
 but as stated in paragraph 138, it has ceased to be used in England, and does not, therefore, come under the 
 
THE CARDING MACHINE. 
 
 head of " modern " machinery. Yet there are principles involved in the Wellman which are of high merit and 
 importance, and a system of carding is possible on this machine which is not possible on any other. To begin 
 with, the distance of the flats from the cylinder may be varied at will, and instead of each flat being 
 concentric with the latter, the circle described by the series may have another and distinct centre. That is 
 to say, the flat at the feed end could be £th inch away from the cylinder, while the one at the doffer end 
 approached with in 5 q 0 th inch, all the intermediate ones being set proportionately. Again, the pitch of the wire 
 teeth upon the various flats can widely vary. Those at the feed end may be, and often are, much coarser 
 than those at the delivery end, a proportionate gradation of pitch occurring throughout the whole series. It 
 will be at once seen that the conditions prevailing in a revolving flat machine are entirely contrary to this 
 practice. In that machine the setting of all the flats is devised so as to make them equidistant from the 
 cylinder centre, and every flat must of necessity be covered with wire clothing of the same counts. 
 
 (141) The effect of the peculiar setting referred to is, that, as the cotton is carried round by the cylinder, 
 the fibres are gradually straightened by a series of combs which are at once nearer to the cylinder surface 
 and finer in pitch, as the doffer is approached. Supposing, for instance, the pitch of the teeth on the first 
 flat was £th inch and their distance from those on the cylinder also the same, it would follow that the fibres 
 flung up by the rotation of the cylinder would be at most only lightly treated. If, however, the pitch of 
 the teeth and their setting became gradually finer, until the latter was reduced to ^ n th inch, it is easy to 
 understand that the fibres would be, by a series of grades or steps, carded or combed. This treatment, on 
 account of its gradual nature, results in the fibres beiug drawn out very straight, and is, when properly 
 conducted, the nearest approach to combing which has been attained on a continuous carding machine. For 
 the longer stapled cottons the use of a machine by which settings of gradually increasing fineness are obtained 
 is especially suitable, and it was for these that the machine was mostly employed. Of course, the figures 
 given above are merely hypothetical, and are used only to illustrate the point at issue. 
 
 (142) The defect of the Wellman machine in modern eyes is principally its slow velocity. The great 
 weights which are now obtained from revolving flat cards cannot, or at any rate have not, beeu obtained from 
 the self-stripper, and, in consequence, the latter has become discredited. But it must not be forgotten that 
 the former machine has had an amount of mechanical skill lavished upon it which has been absent from the 
 latter. This does not mean that the Wellman has not been well made, but it has not been so well constructed 
 as the revolving flat type has during recent years. It is quite within the bounds of possibility that the 
 self-stripper may have a revival, when its undoubted capability for good work may be combined with great 
 productive power. It is often combined with a roller machine and used as a finisher carding engine, and is 
 in other cases fitted with two or three rollers before the flats are reached. 
 
 (143) Reference was made in paragraph 105 to the use of a dish-feed. In Fig. 69 illustrations are given of 
 this part of the mechanism, as made by Messrs. Dobson and Barlow, this being a reproduction of an illustration 
 contained in a pamphlet on "Carding," by Mr. B. A. Dobson. It will be seen that the feed-roller A revolves 
 in the curved portion of the plate C, and that the nose of the latter is specially shaped to suit various 
 
 G 
 
82 
 
 THE CARDING MACHINE. 
 
 classes of cotton. The principle involved here is precisely that referred to in paragraph 94 in dealing with the 
 scutcher feed. The shorter the staple the more acute the surface from which it is struck can be without 
 damaging the fibre. While a long fibre will permit of bending round a roller or lever end of large size, the 
 shorter stapled varieties will simply be dragged downwards and crushed with precisely the same treatment. 
 A close examination of the three views marked K, G, and R will illustrate this point, these being respectively 
 for Surat, American, aud Egyptian cotton. The adoption of the dish-feed is one of the most important of 
 the minor improvements made in the carding engine, and leads to the straightening out of the lap end, owing 
 to the exactitude of the rate of feed which can be attained. For the full success of this appliance it must 
 be used in conjunction with the saw tooth on the licker-in, a description of which is given in the next chapter. 
 This is a description of tooth which does not become charged or choked with dirt, nor does it require grinding, 
 so that it is always in condition to deal effectually with the cotton. The action of this class of tooth is 
 very graphically shown in Figs. 70 and 71, two reproductions of photographs in Mr. Dobson's paper above 
 referred to, of a lap end before and after the licker-in has acted upon it. They very clearly demonstrate the 
 enormous effect produced by the licker-in teeth, and show how effectually all dirt and motes are removed. 
 
 (144) Again referring to Fig. 69, it will be seen that below the dish C two blades or "mote knives" 
 are placed, which can be readily adjusted so as to present a sharp edge to the cotton as it is flung down 
 by the licker-in, and so scrape off the "motes" from its surface. The object of these knives is similar to 
 that of the leaf extractor used in a scutcher, and described in paragraph 77. Beneath the licker-in and 
 beyond the knives a casing E is placed. These are usually made of tinned iron, and form a sort of grid 
 through the interstices of which the droppings can fall. From their position they are known as "under 
 casings." The exact setting of these is a matter of high importance during working, and should be 
 ascertained by observation when dealing with different classes of cotton. It has been found that the use of 
 under casings with the licker-in has been attended with considerable economy. They are also used beneath 
 the cylinder, and should be as carefully set as is the case with those under the licker-in. In determining 
 the distance, regard should be had to the quality of cotton used and its length of staple, as, if the fibres 
 actually strike the bars of the grid, they may adhere to them and partially choke the latter. On the other 
 hand it is found that too wide a setting is followed by increased waste. It is both possible and advisable 
 to find the golden mean by observation. Messrs. Piatt Brothers and Co., Limited, have a special way of forming 
 the uudercasings, the bars of which are secured to turned wrought iron segmental rings, the position of 
 which can be regulated from outside the machine by special setting screws. They also attach the licker-in 
 casing and mote knives to the cylinder under casing, so that they are all set in combination, and an 
 alteration of the position of the licker-in leads to a readjustment of all its attachments. The three guages 
 mentioned in paragraph 132 are combined, and the casings set sufficiently far from the cylinder to permit 
 of the introduction of the three guages. That is to say, the space left is "031 of an inch, which is found 
 to be generally ample, but this is subject to the remarks previously made. 
 
 (145) In addition to the necessity for under casings, covers are required for the licker-in, cylinder, 
 and doffer. As the circles described by the teeth on these three parts approach each other, as shown in 
 
THE CAKDING MACHINE. 
 
 83 
 
 Fig. 46, it is desirable that the covers used should go as near to the point of approach as possible. 
 If any space is left the fly and dirt speedily fills it, and from time to time drops upon the doffer, 
 causing a thick place in the sliver. The arrangement used by Messrs. Dobson and Barlow is shown in 
 Fig. 72, and it will be seen that the cover goes close down into the space left between the cylinder and 
 doffer, and effectually prevents any accumulation of dirt. The cover is in three parts, and is hinged so as 
 to permit of the surface of either cylinder H cr doffer F being stripped or ground as desired. Setting 
 
 J.N 
 
 Fig. 6 P. 
 
 arrangements are provided, by which the cover can be maintained in an accurate position during the whole 
 period of work, although it may be necessary to set the doffer in towards the cylinder. The shape of the 
 centre portion is specially designed to permit it to receive the strippings from the flats. Again referring 
 to Fig. 69, it will be seen that similar arrangements are made for the licker-in and flats, the space between 
 the flats and the cylinder wire being filled as shown, as is also the space between the licker-in and cylinder. 
 The cover F over the cylinder and licker-in can be set up as desired, as can also the filling piece L below. 
 
84 
 
 THE CARDING MACHINE. 
 
 All the covers are arranged to fit closely to the bend at the edges, so that there cannot be any blowing ont 
 at the side of the cylinder. 
 
 (146) The driving of the cylinder is obtained from the line shaft by means of a fast pulley fixed on the 
 cylinder shaft, a loose pulley adjoining it to facilitate stoppage. The licker-in is usually driven from the cylinder 
 by a crossed strap, and the doffer from the licker-in by a similar strap, which passes over a pulley mounted on a 
 stud fixed in a lever. The pulley has a pinion on its boss, which engages with the doffer wheel U, and so drives 
 it. The pinion, or "barrow- wheel," can thus be easily thrown out of gear, as desired. The feed-roller is driven 
 
 Fig. 72. 
 
 by a side shaft from the doffer shaft, placed on the other side of the machine to the main driving and the 
 doffer comb by a cord passing over a grooved pulley on the cylinder shaft. The calender rollers are driven 
 from the doffer, and the coiler shaft from the spindle of the calender roller. 
 
 (147) The pedestal is constructed with an extra long bearing, the shaft being 3| inches diameter and 
 the bearing 7 inches long. The bush lining the pedestal is usually made of phosphor bronze, or some equally 
 good material, in order to resist wear. It was pointed out in paragraph 119 that it is essential that the 
 position of the centre of the cylinder shall be continually maintained, and it is therefore desirable to guard against 
 
THE CARDING MACHINE. 
 
 85 
 
 its movement. If it is considered, it will be understood that the centrifugal action set up by the rotation of so 
 heavy a body as a carding engine cylinder will cause it to endeavour to roll forward, and thus induce wear in the 
 front of the cylinder bearing. This is aided by the pull of the strap, which is usually towards the front. The 
 provision of some ready means by which the wear can be taken up and the position of the cylinder centre 
 restored, is, therefore, of great service. It is not practicable to employ the conical bearings often used in 
 other classes of machines, as the wear not being equal, a tightening of the bearing would not take it up. 
 
 (148) Messrs. Howard and Bullough adopt a plan by which the pedestal is fitted upon two wedges, or 
 inclined metallic surfaces, placed one above the other. By setting one or both of these wedges in either direction, 
 the pedestal is so adjusted that the cylinder centre can be moved either laterally, vertically, or angularly, as is 
 required. Another plan, adopted by Messrs. Ash worth Bros., consists of the formation on the pedestal of three 
 projections, or claws. The inner surface of these is bored concentrically with the pedestal bearing, so that when 
 the cylinder is in its true position, a cylindrical template, bored to correspond with the diameter of the shaft; 
 and turned on its outer surface the same size as that to which the projections are bored, can be easily pushed up 
 to the face of the pedestal. Unless this can be done the cylinder is not concentric, and the adjustment of the 
 bearing must be made accordingly. Messrs. Dobson and Barlow employ the device shown in Fig. 73, which 
 consists of two eccentric bushes, X Y, surrounding the bush in which the shaft Z revolves. The eccentricity of 
 each of the bushes is equal, and thus by moving one or both the position of the centre of the cylinder can be 
 adjusted at will, either laterally, vertically, or angularly. To facilitate the adjustment, two screwed rods, U V, 
 are attached respectively to lugs formed on the bushes X Y, and pass through brackets formed on the pedestal. 
 By means of nuts placed at each side of the brackets the adjustment of the position of the eccentric bushes 
 can be made at will. 
 
 (149) In order to diminish the evil effects of the pull of the strap, as mentioned in paragraph 119, the plan 
 shown in Fig. 74 has been adopted by Messrs. Ashworth Bros. Instead of keying the fast pulley on the shaft, 
 it revolves on a hollow boss C, which has a flange or plate attached to the pedestal F. The pull of the 
 strap on the fast pulley A is therefore taken by the bush or hollow boss C, and not by the shaft. Fixed 
 on the shaft is a coupler D, which is formed with two arms engaging with corresponding recesses in the 
 centre of the boss of the pulley A, something similar to the ordinary driver used in turning. By these 
 means the shaft is rotated without there being any pull upon it, and one fruitful source of forward wear is 
 thus removed. 
 
 (150) The three points which it is necessary to bear in mind in regard to carding were indicated at the 
 opening of this chapter. These were the cleansing, parallelisation, and attenuation of the lap, and a few words 
 may be said about each in that order. The velocity with which the teeth of the licker-in strike the end of 
 the lap causes the fibres to be effectually loosened, and shakes a good many of the motes out of the cotton. 
 Others are left on the surface of the fibres held by the licker-in wire, and are removed by the mote-knives 
 as described, while some enter the spaces of the licker-in covering, from which they are easily thrown. On 
 passing to the cylinder, the short fibres are largely thrown off as fly, or when they are subjected to the combing 
 
86 
 
 THE CARDING MACHINE. 
 
 action of the wire teeth on the rollers or flats they are removed, and become fixed in the spaces in the covering. 
 The "neps" are in a similar way taken out of the fleece, and from this cause periodical stripping i3 desirable 
 of both rollers and flats. By reason of the centrifugal action of the cylinder many short and nepped fibres 
 are driven into the roller or flat wire, but a certain proportion also remain in the cylinder wire, which also 
 requires stripping periodically. 
 
 (151) It is somewhat difficult to define the exact action of the wire points by which the crossed and 
 tangled fibres in the lap are laid in approximately parallel order. There is little doubt, however, that the speed of 
 the cylinder plays an important part. The fibres are by the action of centrifugal force thrown out, so that, 
 while held at one end by the cylinder wires, they are rapidly drawn through the wires on the rollers or 
 flats. If the grip of the fibre is slight, as in the case of a short fibre, it will be removed, but, if it is 
 sufficient to hold, it follows that the fibre would be combed by the superimposed wire teeth. In this way 
 the thickuess of the fleece on the cylinder plays an important part in determining the amount of parallelisation 
 the fibre receives. If this is thin, each fibre, in all probability, receives its due treatment, while, if it is 
 thick, the fibres are dragged — so to speak — through the wire teeth above, and would be likely to be injured, 
 besides which their arrangement is more difficult. For this reason, the lighter the carding — that is, the less 
 the weight of cotton passing at a given time — the better, provided that this is not pushed so far as to be 
 uneconomical. It has been pointed out that the setting of the flats in the self-stripper lends itself peculiarly 
 to effective combing, as the pitch of the wire teeth and the distanci between them and the cylinder teeth 
 cxn be gradually made finer. In the case of the roller card the fibres are lifted off the cylinder, and, if well 
 held, would be drawn straight in the process. In their transfer by the clearer to the cylinder the fibres are 
 further dealt with, but it is problematical whether the alternate raising and return of the fibres from and to 
 the cylinder, results in a parallel order being obtained equal to that by other machines. A good result arises 
 from the use of a roller card as a breaker, and a self-stripper as a finisher card, and this arrangement is 
 often adopted. 
 
 (152) The attenuation of the lap is one of the most important functions of the carding engine, because 
 it is the first stage in the formation of a thread, by reason of the easy condensation or collection of the thin 
 film into a strand. Assuming that the feed roller is 2| inches in diameter and makes one revolution per 
 minute, it will deliver 7*854 inches of lap. The licker-in being 8 inches in diameter, and revolving at a 
 speed of 400 per minute, is capable of delivering 10053-12 inches. As it cannot get this length of lap, it 
 follows that in its revolution the teeth remove a small portion of the cotton continuously, and thus produce 
 a layer or fleece, which is increased in length and diminished in thickness. The ratio of this increase is that 
 just given, being equal to 1,280 : 1. When the cotton is transferred to the cylinder a further reduction 
 takes place. The cylinder, being 50 inches in diameter and revolving, say, 150 times per minute, is capable 
 of delivering 23,562 inches of cotton, or 2-34 times as much as the licker-in. Thus, up to this stage, the 
 lap is elongated 3,000 times, as compared to its thickness when passing the feed roller. If the lap is ^ inch 
 thick the fleece on the cylinder, if spread out, will only be i^Voo inca thick. It will be easily seen by a 
 
THE CAEDING MACHINE. 
 
 Fig. 74. 
 
88 
 
 THE CARDING MACHINE. 
 
 reference to the sizes of the cotton fibres that this is much thinner than the smallest diameter of individual 
 fibres, and it follows, therefore, that if there was only this amount of cotton on the cylinder there would be 
 many bare places. As the work of carding proceeds the cylinder becomes charged with cotton, but is 
 never so full that the fibres cannot be carded thoroughly and individually, unless the rate of feed is excessive 
 or largely increased. As the fleece is deposited on the doffer the reverse process occurs, as the doffer, being 
 24 inches diameter and revolving only 12 times per minute, would only deliver 90478 inches, or ¥ \-th of 
 that of the cylinder. Thus, the sliver, when collected, would be about x i T th of the thickness of the lap. 
 These figures are, of course, only approximations. As was previously shown in paragraph 112, the rollers and 
 clearers in a roller card revolve at a much slower speed than the cylinder. The cotton is therefore subjected 
 to a series of condensations and attenuations as it passes round the machine. 
 
 (153) An enlarged view of the sliver as it leaves the doffer is given in Fig. 75, and shows 
 that the fibres, although not in parallel order, are arranged so that a slight additional pull is 
 sufficient to straighten them. This the sliver receives partially between the calender rollers and the coder, 
 but it is in the drawing frame that the greatest effect is obtained. The draught there exercised speedily 
 causes parallel order to be attained in the sliver, which is in good condition for this action. The draught 
 in a carding engine takes place between the feed rollers and licker-in, between the licker-in and cylinder, 
 and between the calender rollers and coiler, the total draught being reckoned between the feed roller and 
 coiler. The question as to the speed of the doffer turns upon the amount of condensation required and the 
 weight it is desired to get through the machine. There is a distinct relation between the speed of the 
 cylinder and that of the doffer, but it has never yet been practically fixed, and carders vary in their speeds 
 considerably. 
 
CHAPTER VII. 
 
 CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 (154) As was shown in the preceding chapter, the cylinder, dofter rollers, &c, of carding engines are 
 covered with a wire clothing, the proper construction of which is of high importance. It forms a sort of 
 wire brush, in which the points are fixed in a special matrix, or " foundation," as it is called. Formerly it 
 was the universal practice to make the foundation of leather, but various considerations have led to its 
 abandonment, except in the case of woollen cards where an oily or greasy material requires dealing with. In 
 lieu of leather three specially prepared materials are now employed, one being what is called a cotton-wool- 
 cotton, another cotton, and the third a natural rubber foundation. The first of these consists of two 
 thicknesses of cotton cloth specially woven with a wool fabric cemented between them. The rubber foundation 
 consists of a thin sheet of natural indiarubber imposed upon and securely cemented to a back of cotton and wool. 
 Great care is taken that the india-rubber shall be pure, and in some cases the manufacturers of card clothing 
 also produce their rubber sheets. The object aimed at in each case is to obtain a foundation which shall be 
 strong enough to hold the wires securely, and at the same time be possessed of some elasticity, so as to 
 aid the wires to recover their position when bent during work. 
 
 (155) It was at one time the practice to make the cards in sheets four inches wide, and long enough to 
 cover the width of the machine, but this has been abandoned in favour of a plan by which they are made 
 in long strips or "fillets," These are long enough to completely cover the cylinder, on which they are wound 
 in a way which will be hereafter described. Having obtained the fillet for the foundation, the next step is 
 to introduce the wires. These are produced from a reel of specially drawn steel wire, which is frequently 
 hardened and tempered by a continuous process. It is essential in conducting the latter that the wire should 
 be free from scale, and, in the great majority of cases, this is attained. In fixing the wires into the foundation 
 the preliminary step is to cut off from the wire carried on a reel a sufficient length, and bend it up into the 
 form of a right angled staple, having two parallel arms joined by the third side. The extremities of these 
 arms constitute two of the points to be fixed in the foundation, so that it will be seen these are always 
 introduced in pairs, and not singly. In order to facilitate their passage through the foundation, two holes, 
 pitched to correspond with the distance of the two points apart, are pierced in it, and immediately on the 
 withdrawal of the piercer the staple is pushed in, and forced up to its place. Almost simultaneously with 
 this operation it is set — that is, is bent to an angle as shown in Fig. 85. After one pair of wire points are 
 fixed the fillet is traversed, so as to introduce another pair at the required distance from the last one. When 
 the width of the fillet has been filled with teeth it is moved a little lengthways, far enough to begin the next 
 
92 
 
 CAKD CLOTHING, GRINDING, AND STRIPPING. 
 
 line, and the direction of the carriage is reversed. It is highly important that the wire points should be set 
 equidistant over the whole of the surface, so that when the cylinder is clothed, the regularity of the carding 
 points will be unvarying. The whole of the operations of feeding, cutting, and bending the wire, piercing the 
 fillet, forcing in the teeth, traversing and reversing the carriage, and traversing the fillet longitudinally, are 
 automatically performed by a machine of great ingenuity, originally invented by Mr. J. C. Dyer. It is one 
 of the best examples in the whole range of mechanics of the power of the cam, and works with great rapidity, 
 being capable of fixing over 300 pairs of wire points per minute. 
 
 (156) The teeth can be set in the foundation in three ways — either plain, twilled, or ribbed, these settings 
 being shown in Fig. 76, the dots representing the wire points, the back of the teeth being shown by the dotted 
 lines. In the first case the teeth are in straight lines; in the second they are, as the name implies, set 
 diagonally ; while in the third they are in straight lines, but set so that they are in sets of three, each of 
 which overlaps its predecessor. Generally, plain setting is very little used, fillets being commonly made ribbed, 
 except in the case of the flat covering, which, when mild steel wire is employed, is usually twilled. In 
 
 Fig. 76. 
 
 manufacturing cards for covering the flats it is common to commence with a large sheet equal in width to 
 the length of the flat. The teeth are then set for a space equal to the width of the flat, when the sheet 
 is rapidly traversed longitudinally until Ihe point for starting a new flat strip is reached. These strips are 
 cut out of the sheet, and thus leave the necessary margins for fastening to the flat. In America twilled 
 setting is preferred, but, in this country, it is objected that spaces are left between each lap when fixed on 
 the cylinder, which is very objectionable. This fault does not occur where ribbed fillets are used, and it is 
 now almost the universal practice to use this setting for cylinder and doffing coverings. However the teeth 
 are set in this respect, they vary also in their distance from each other, and this variation depends on the 
 "counts" of the wire. This phrase is used to indicate the fineness of the pitch of the wire teeth, and the 
 method of counting is based on the number of teeth in the width of the sheets formerly made. Thus, if 
 there were 100 teeth in a sheet four inches wide, the counts were said to be 100's, the same rule being applied 
 to-day. Longitudinally, the pitch of the teeth was ten " crowns," or points, to the inch, this being also retained 
 as a standard of measurement. In this way it is possible, by knowing the counts of wire, to calculate easily 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 93 
 
 the number of teeth per square inch. Thus, in the instance named, there would be 100 x 10 = 1,000 teeth 
 in the four inches of width by one inch in length, which is equal to 250 teeth in every square inch. 
 
 (157) In clothing the various parts of the machine experience has shown that there can be wise variations 
 made in the kind used. Every spinner has ideas of his own, and as there is a wide difference in the class 
 of material treated no rule can be laid down. In clothing the licker-in, a tooth which is known as the 
 "Garnett" is universally used. An illustration of this is given, in full size, in Fig. 77, the finer tooth shown 
 being used when no undercasings are fitted, and the coarser when they are. It will be noticed that the 
 former is a little more hooked than the latter, which enables it to carry round the cotton without flinging 
 it below the licker-in. The presence of an undercasing obviates much of the necessity for this carrying power, 
 and the tooth is only required to beat off the cotton from the lap and thus throw down the motes, etc. In 
 covering the cylinders of roller carding engines, where medium counts of yarn are being spun, clothing with 
 90's to 100's wire is used, the rollers being covered with the same counts, the clearers with a finer wire, and 
 the doffers from 100's to 120's. These, of course, are sizes which are commonly employed, and indicate the 
 usual limits, but, as has been observed, practice varies considerably in this respect. In revolving flat carding 
 
 KKKKKKKKKKK, J 
 
 J.N. 
 
 Fig. 77. 
 
 engines the cylinders are covered with 110's, and doffers and flats with 120's for medium counts of yarn. 
 It may be generally stated that the finer the counts of yarn spun, all other things being equal, the finer 
 the wire clothing employed ; but it can only be settled by practice what are the best counts to use in any 
 individual case. 
 
 (158) As has been observed, the wires are, in the process of setting, bent to an angle, or, rather, a double 
 angle, after leaving the foundation. A reference to Fig. 85 will show that they leave the foundation at an 
 angle in one direction, and afterwards bend sharply in the opposite direction. The diagram given in Fig. 78 
 illustrates this construction. The foundation is shown by the letter D, to which the line A B is perpendicular, 
 leaving the upper surface of D at E. The tooth is indicated by the line AC E B 1 , and it will be noticed 
 that the point of the tooth at A is perpendicular to the point E where it leaves the foundation. This is the 
 correct setting, or nearly so, for the following reason. Some makers, it may be stated, prefer to let the point A be 
 a little behind the perpendicular line A E. In working, the wire point is pressed by the material and is sprung 
 backward, in which case it — when set as shown — will radiate round E and move in the circle shown by the 
 letters FAG. Thus, if another set of wire points are imposed upon the lower ones, the flexure of the 
 
94 
 
 CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 latter, in either direction, is followed by their recession from the former, and no danger exists of any inter- 
 locking, which, if it occurs, is injurious to both sets of teeth. As the relative positions of the upper and 
 lower teeth are of the character described in the previous chapter, the adoption of the method of setting the 
 teeth indicated is of considerable importance. It is, of course, possible to vary the angularity or "keen" as 
 desired, and the more acute the angle E C A the more fibre caught and retained. Thus the proportion of 
 waste made in a machine during work is largely dependent on the angular setting of the wires, and this is a 
 point specially worth noting. The essential element is the approximate perpendicularity of the point A of 
 the wire to that (E) where it leaves the foundation. 
 
 (159) With regard to the shape of the tooth a good deal can be said. Ideal carding would be obtained 
 by the use of fine needle points closely set, as will be seen in dealing with the combing machine, but it is 
 manifestly impossible to employ teeth of this description in a carding engine. Although they might be 
 inserted and used in new clothing, as soon as they became blunt it would be impossible to restore their 
 points owing to their position in the clothing. But the principle remains; and, failing the employment of 
 needle points, the attention of makers has been directed to the production of a wire which will present to 
 the cotton what is practically a needle — or more accurately — a knife edge, which can easily be renewed after 
 wear. To Messrs. Ashworth Brothers belongs undoubtedly the credit of this important step, which brought 
 in its train many changes in the general construction of the machine. They use a wire which is round in 
 section, but which they grind at the side so that above the foundation it becomes oblong, thus presenting 
 a sharp edge to the fibres while preserving all the necessary strength in the portion fixed in the foundation. 
 Various other sections have been employed, such as double convex, triangular, and oblong, and by a special 
 system of grinding the same kind of edge is produced. The teeth when fixed in the fillets are ground on 
 their edges by thin emery disc wheels formed with bevelled edges, which pass between the teeth and grind 
 them to a sharp edge. A pair of teeth of this character, magnified 13 times, are shown in Fig. 79, which 
 is from a photograph lent by Messrs. J. Whiteley and Sons. It will be noticed that the line of the tooth 
 is gradually tapered until the point, which assumes very nearly the character of a needle point, is reached. 
 
 (160) The question as to how far this "plough" grinding is a good thing is one which it is worth 
 while dealing with at length. It is undoubtedly true that steel wire carefully hardened and tempered will, 
 under equal conditions, wear longer than a softer variety, but it is sometimes argued that the advantage 
 thus derived is counterbalanced by the grave faults often existing after a surface of this kind has been 
 side ground. The idea of a needle point is the right one, but it is worse than useless unless the wire 
 remains smooth. There are two evils to be guarded against — the barbing or hooking of the wire points and 
 the striation of the sides of the teeth. Both of these faults are often produced in side grinding, this fact 
 having been fully established by a number of investigations made by various observers. 
 
 (161) It is apparent that the abrasion of a wire surface by means of an emery wheel is sure to 
 produce a certain degree of roughness. If any student of the subject will take the trouble to examine 
 newly-ground clothing by the aid of a glass magnifying from 10 to 20 times, the scratches caused by the rotation 
 of the emery wheel are easily seen. It requires very little reflection to show that this is sure to be 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 95 
 
 detrimental. Mr. B. A. Dobson, of Bolton, who has gone very extensively into the subject, published with 
 an address delivered by him in America an interesting series of photographic representations of side ground 
 teeth. These were enlarged a number of times, and were then reproduced. Striated sides and barbed points 
 are common in this series. Now the inevitable effect of such a tooth is to break or destroy the fibre, or 
 remove from its surface a portion of the waxy covering. This leads to an increased waste in the subsequent 
 processes, although that produced in the carding machine may be less. It is hardly worth while discussing 
 
 A 
 
 Fig. 78. 
 
 the point further, but there is one fact which speaks volumes as to the general opinion on the subject. It 
 is agreed that the treatment of the teeth by those of a wire burnishing brush has a very beneficial effect 
 upon them, and the carding afterwards carried out is much cleaner and better. This is one reason why 
 the brush used to strip the flats is occasionally made of wire. As the action of a burnisher is to remove 
 scratches previously made, its use is a confession of their existence. 
 
 (162) The roughening of the wire teeth is not, however, inevitable. In Fig. 80 is shown a side view 
 of a plough ground tooth magnified 32 diameters. In this the striations are most marked, and there needs 
 no comment to demonstrate their existence. In Fig. 81 a similar tooth ground in a special manner, and 
 similarly enlarged, is shown. The surface of this is so much smoother than the other, that practically it is 
 perfect. At any rate it is so much better than the one shown in Fig. 80, which is ground in the usual 
 way, as to be an entirely different article. Both of these photographs are supplied by Messrs. John Whiteley 
 and Sons, and the system of grinding by which the tooth shown in Fig. 81 was obtained, is now in regular 
 use by them. The objection is not to needle or chisel shaped teeth side ground, but to these plus striation, 
 and if the addition can be removed, many of the objections rightly entertained will be obviated. 
 
 (163) When the clothing has worn it is desirable to grind it frequently but lightly. The practice of 
 allowing the tooth to become very blunt prior to grinding is very objectionable, as it leads to heavy grinding 
 and there is a danger of hooked teeth. It is impossible to state a general rule on the subject, as the periods 
 of grinding depend so largely on the class of cotton treated, but it is better to give a light grinding to the 
 wire every few weeks. 
 
96 
 
 CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 (164) In the last chapter, in paragraph 107, it is pointed out that the cylinder is drilled with a number 
 of holes arranged in straight lines across its periphery, in which wooden plugs are tightly driven. These are 
 intended to aid in fastening on the fillets, and before clothing the cylinder or doffer, it is desirable to mark 
 the centre of each line of holes on each edge, and to set out the position of each hole in one line on a staff. 
 In this way, when the surface is covered, the exact position of each plug can be ascertained, and the tack 
 inserted without damaging the wire. As the cylinder surface is quite level, the fillets are in some cases 
 wrapped on the bare face, but there is some danger of the clothing slipping, especially if made with a rubber 
 foundation. To obviate this serious defect, the surface of the cylinder is covered with a specially woven 
 cotton cloth, or with brown paper, the former being preferable. This covering is put on without any puckers 
 or creases — a very essential thing — and is attached to the cylinder by a special kind of cement or paste. Oil 
 a surface prepared in this manner rubber foundations will not slip in working. With fillets in which the 
 foundation is a woollen one, these precautions are not necessary. If it is intended to employ rubber 
 foundations, great care must be taken before proceeding to clothe the cylinder. The fillets must be kept in 
 a room heated to the same, or a little higher, temperature than the card room in which they have to work. 
 This treatment causes the fillet to expand to a certain extent, and should be continued for some hours prior 
 to their being used. Thus when the fillets are fixed in their position they do not expand as they would do 
 if kept in a cold room before being used. Woollen foundations do not expand by heat, and can, therefore, 
 be used and fixed without the preparation named. For this reason they are suitable for employment in places 
 where the direct sunlight can fall on them. Oil being detrimental to india-rubber, fillets with that foundation 
 should never be used where oil is likely to fall on them. A certain disintegration of rubber foundations 
 occurs in some cases in hot climates, but they are largely used in England. 
 
 (165) Having prepared the fillets for wrapping on, the operation is completed. Formerly they were wound 
 on manually, but this is now almost invariably done automatically by a machine made by Messrs. J. Whiteley 
 and Sons, which is illustrated in Fig. 82. One end of the fillet is securely fixed, and the cylinder is then 
 started. The cross slide K is fixed on the frame of the machine, or on a special frame if preferred, when 
 the dofFers are being clothed, and the apparatus is then ready for work. On the slide K a carriage is 
 fitted which is traversed by a screw, on the end of which is a chain wheel L, by means of which the 
 necessary movement can be given from the chain-pulley O automatically, or it can be manually given by 
 the handle R. The carriage bears a drum mounted on a cradle hinged to the carriage. The angular 
 position of the drum is regulated by the tension screw, and the tension put upon the fillet, in pounds, is 
 registered by a finger moving over a graduated scale. The card fillet is taken from the basket through the 
 trough D, thence over the drum, from which it is taken to the cylinder. The cylinder is revolved by means 
 of the handle R, and the card clothing is slowly wrapped on, the traverse of the carriage being arranged 
 to be at the required speed. In lieu of the drum Messrs. Dronsfield Brothers use a stepped cone, which 
 gives a similar result. Thus, cylinder fillets, when made of hardened and tempered wire, can be 
 wound under a tension of 2701bs., while doffer fillets of the same quality only require one of 1751bs., and 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 97 
 
 Fio. 81. 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 101 
 
 for roller fillets, which are only 1 inch wide, 1201bs. is sufficient. What is required is to so wrap the fillets 
 that, without straining them, they adhere closely to the surface of the cylinder or doffer ; . and do not, after 
 working, rise in places or "blister," as it is called. After the cylinder is covered the fillet is fastened at its 
 free end, and is then allowed to rest for a few hours, so that it adjusts itself throughout its length. It is 
 necessary to shape the fillet at each end so that, when wound, no break in the carding surface occurs; and, 
 for this purpose, it is usually cut to a shape which permits the first and second coils and the last two to lie 
 close together. It is then tacked on in the way previously described, a special tool being used to drive the 
 tack and avoid damaging the wire. 
 
 (166) In fastening the clothing upon the flats several methods are pursued. A reference to Fig. 83 
 shows two of these. In A, which is 2 inches wide, and B, which is If inches wide, the edges of the flats 
 are drilled with small holes, and the strip of clothing is similarly punched. One side of the strip is then 
 
 ^iiiin'iiiiQ, 
 
 O 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 o 
 
 Fig. 83. 
 
 J.N 
 
 fastened to the flat by means of lead rivets, and it is then drawn tight along its whole length by a special 
 clip. The other edge is, while the strip is held in tension, riveted firmly in a similar manner. A machine 
 for this purpose, made by Messrs. Dronsfield Brothers, is shown in Fig. 84. Another method is one originated 
 by Messrs. Ashworth Brothers, and is shown in C and D. In this case the strip is attached by means of wire 
 
102 
 
 CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 stitching, the flat being sawn at its edge at regular intervals, as is very clearly shown. A third plan is 
 illustrated in Figs. 85 and 86 in partial perspective and transverse section, this being made by Messrs. John 
 Whiteley and Sons. A clip is passed through the clothing and flat, and is then clenched, as shown separately 
 in Fig. 87. The strip of clothing is then drawn tight, and the second clip fixed in the same way. This 
 method is rapid and effective, and possesses one important advantage. By it the margins of the flat strip are 
 protected from being frayed by the revolving brush used to clean them. 
 
 (167) In dealing with the construction of the flats it has been shown that there is a movement towards 
 the use of shorter ones, for the reason that it is felt to be desirable to prevent any deflection by having a 
 stiff flat. Upon this point the consideration of the advantages of various systems of fastening the clothing 
 largely turns. It is quite clear that any removal of metal, either by drilling or sawing, is likely to weaken 
 the flat. It is, however, not so readily seen which is the most weakening, but actual experiments show that 
 wire sewing is so. Mr. B. A. Dobson, of Bolton, has made a series of tests of flats, both drilled and sewn, 
 to ascertain the deflection during working and grinding positions, and the side deflection. These establish very 
 clearly the superior strength of the riveted flat, which is very considerable. For instance, a flat 45| inches long 
 by If inches wide, with the same thickness in flat and web, gave the following deflections when loaded with a 
 lib. and 21bs. weight respectively. Unclothed, sawn for wire sewing: 1st, when face up, ¥ |^th and ^th 
 inch ; 2nd, when on its side, ^l^th and T £ F th inch j and, 3rd, when face downwards, ^g^th and ^g-th inch. 
 Unclothed, drilled for rivets, the deflections in the three positions named were as follows: 1st, ^ * 0 0 th and 
 xJ^th inch ; 2nd, -jln^ an( * 2TT tu inch ; and, 3rd, g-^th and T |-^th inch. The reason for this is not far 
 to seek. The riveted flat has throughout its length an unbroken metallic surface along its edge, while the 
 sewn flat is broken at intervals to permit the passage of the wire. For the reasons given in paragraph 118, 
 the difference between ^-^-th and ¥ y^th inch is material, especially when the settings of the flats are supposed 
 to be regulated to the yxnnjth inch. 
 
 (168) In Fig 88 is illustrated a plan by which the necessity for piercing the flat either with holes or nicks is 
 entirely obviated. This is patented by Mr. Tweedale, manager for Messrs. Howard and Bullough, and consists in 
 the employment of a metallic clip, which grips the clothing at one side, and is bent round and under a small 
 rib on the underside of the flat. The clip is closed by means of a special machine, which runs rapidly along 
 the flat, the two sides being gripped simultaneously, and the fillet stretched by the same machine and at the 
 same time. With this construction the maximum strength of the flat is preserved throughout all its positions 
 and under all working pressures. A similar arrangement is used by Messrs. Ashworth Brothers, but the shape 
 and construction of the clip and the method of fixing slightly varies from that described. It is to be noted, 
 however, that the width of the flat strip must be rather less in each case than that of the flat, and that the 
 strip must in consequence be stretched so as to cover the surface. It is essential that the clips shall be 
 fixed so as to be in contact with the planed edge of the flat throughout its entire length. The edges of the flats 
 ought to be quite straight, especially if they are closely pitched, as otherwise they would come into contact in 
 places. If, therefore, the clips referred to are not pressed closely against the sides of the flats throughout their 
 entire length the danger of touching is increased. 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 103 
 
 Fig. 88. 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 105 
 
 (169) Messrs. Piatt Brothers and Company have recently devised a fastening of tinned wire, which is bent up by 
 special machinery so as to form a continuous series of staples, the pitch of the points of which is about | inch. 
 The staples are connected at the points, so that a length can be produced sufficient for fastening any fiat. Holes 
 are drilled in the flat through which the staples are pushed, and are pressed downwards and held. While in that 
 position the points are clenched similarly to Messrs. Whiteley's clip, and the clothing thus secured. This 
 arrangement is practically a system of sewing without the disadvantage arising from the sawing of the edge of the 
 flat. A strength equal to a riveted flat is obtained, with the advantage of a continuous grip along the fiat strip. 
 All these arrangements, however, imply the use of special machines to fix them, which is a condition not always 
 attainable in a mill. For these reasons, where it is difficult to return the flats to a machinist for re-clothing, the 
 use of rivets is most desirable. 
 
 (170) No less important than the proper fixing of the clothing in position is the operation of grinding 
 it before starting work and after the points have worn. The licker-in is not ground, as the teeth do not 
 require it, and their shape is such that grinding is impracticable. The cylinder is ground in position, and 
 the question as to which is the correct method is one about which there is a good deal of controversy. In 
 theory it is quite true that the periphery of a cylinder revolving, say, 180 times per minute, will tend to 
 follow a path which is not an absolutely true circle. Further, the vibration set up in working, and the 
 constant tendency from centrifugal action for the cylinder to roll forward, have a certain bearing on the subject. 
 For these reasons there are some persons who contend that during the grinding of the cylinder teeth the 
 cylinder should be run at its normal velocity, and the emery grinding roller be driven at a surface speed 
 approximating to that of the cylinder. While this contention is theoretically correct, the disturbance caused 
 by the high velocity of the cylinder is not of practical moment, and it is found to give the best results to 
 run the cylinder slowly and the emery roller quickly. In all operations in which a true surface has to be 
 established these conditions are found to be the best, and the grinding of a carding engine cylinder forms 
 no exception to the rule. The danger of damage to the wire joints is much less likely, and the high speed 
 of the grinder aids materially in light grinding, which it will be shown is of great moment. It is, therefore, 
 the universal practice to reduce the normal speed of the cylinder to one varying from 7 to 1| revolutions 
 per minute, and several special devices are in the market for the purpose. Before passing on to describe 
 these, it may be said that the cylinder is ground by an emery roller, sustained in special brackets fitted 
 to the machine framing, the position of which is shown in Fig. 44 at R. A similar method of procedure 
 is adopted with the doffer, the brackets being placed at S. 
 
 (171) The most common appliance to obtain a slow motion of the cylinder is that known as Sykes', 
 which is shown in Fig. 89, as made by Messrs. Dronsfield Brothers, of Oldham. This consists of fast and 
 loose pulleys, which are driven by a strap from a pulley on the line shaft. The pulleys are sustained in a 
 frame which also carries a short strap, on which is fastened at one end a bevel and at the other end a 
 worm. The frame is supported by the two legs shown, which can be adjusted to any length. The worm 
 wheel is fixed on the cylinder shaft in place of the ordinary pulley, and is driven by the worm and 
 
106 
 
 , CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 geariug as described. A slow motion is thus given to the cylinder, and at the same time the grinding 
 rollers are driven by bands or cords from grooves formed in a flange on the fast pulley. 
 
 Fig. 89. 
 
 (172) A motion patented by Messrs. John Hetherington and Sons is illustrated in Figs. 90 and 91. In 
 Fig. 92 a side view of a carding engine is shown, with the motion applied to it. On the stud G, which 
 usually carries the intermediate band pulleys, shown by the dotted line I, the boss F of the supporting 
 frame A is fitted. The apparatus is shown in Fig. 90 in section, and consists of the supporting frame named, the 
 
 Fig. 90. Fig. 91. Fig. 92. 
 
 boss A 1 of which forms a bearing for the shaft B, with the eccentric B 1 formed on it. On one end of the 
 shaft the double grooved pulley C is fixed, by means of which it is revolved. An internal rack A 2 is formed 
 on the fixed frame A, and adjoining the latter is the compounded pulley D. D is also formed with an 
 
CA.KD CLOTHING, GRINDING, AND STRIPPING. 
 
 107 
 
 internal rack and a single grooved pulley, and revolves on the outer end of the shaft B, being kept in 
 position by the nut and washer shown. There are thus two racks, each containing the same number of 
 teeth, one fixed and the other free to revolve. Mounted on the eccentric B 1 are two wheels EE 1 , the 
 latter being smaller in diameter than the other, this arrangement being shown clearly in front view in Fig. 91 
 
 (173) The action of this mechanism is as follows : The pulley C is driven by a band K passing over the 
 pulley J on the main cylinder shaft H. In this way C is revolved, and the eccentric movement of the shaft 
 B causes the wheel E 1 to fall into gear with the rack A 2 . This gives a rotary motion to the wheels E E 1 , 
 and the larger diameter of E causes it to revolve at a greater rate than E 1 . The revolution of B, in addition 
 to setting up this rotary motion in the compound wheel E E 1 , also puts E into gear with the rack D 1 , and 
 causes the latter to revolve. The motion of the pulley C is thus communicated to D, but the latter is 
 revolved at a much slower velocity in the direction of the shaft. By proportioning the pulleys and wheels 
 the necessary reduction in speed can be obtained. The revolution of D is communicated to the cylinder by 
 the band L passing over the grooved pulley M. 
 
 (174) In the machine as made by Mr. Samuel Brooks, the motion is compounded with the barrow wheel 
 detaching motion, as illustrated in Figs. 93 and 94. On the same stud as the barrow wheel is a helical 
 wheel C, which is driven from the former by a clutch, and which engages with a wheel D fastened on the 
 
 J.N. 
 
 Fig. 98. 
 
 lower end of a shaft placed at an angle of 97°. On the other end of the shaft a worm F is fixed, and 
 gearing with the wheel G. During grinding the barrow wheel is disengaged by means of the lever in which 
 the stud carrying the former is fixed, and the worm is thrown into gear. The speed of the cylinder is thus 
 
108 
 
 CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 reduced to about one revolution, the necessary rotation of the wheel C being obtained from the pulley on 
 the cylinder shaft. When it is desired to grind the cylinder the strap is thrown on to the pulley, and the 
 necessary rotation given to the barrow wheel B and helical wheel C- The arrangement thus described is 
 always in position, and does not require separately attaching to the machine, as is the case with most of the 
 motions in use. 
 
 (175) Another form of apparatus recently introduced by Mr. Thomas Knowles is the one shown in Figs. 95 and 
 96. In this case the boss of the loose pulley |_ carries a pinion J inside the pulley which gears with |, fixed on a 
 short shaft borne by a central plate. Through the train of wheels H G F E C and B the central pinion A, 
 fastened on the inner boss of the fast pulley M, is revolved. Over the central plate, in which the spindles 
 on which the wheels E F G H and I are fixed, are fitted, a band K is passed. By tightening the latter 
 
 J.N. 
 
 Figs. 95 and 96. 
 
 the plate can be prevented from revolving. In grinding, the strap is moved on to the loose pulley, the band 
 K is tightened, and the revolution of the pulley gives motion to the whole of the wheels, thus reducing the 
 ultimate velocity to the required extent During work the band K is slipped off the plate, and the whole 
 nest of wheels is carried round with the pulleys as they revolve. 
 
 (176) The rollers used for grinding the cylinder and doffer are made in two forms. One of these is 
 shown in Fig. 97. It consists of a light roller made with a thin wrought iron shell secured upon a~shaft, 
 
 Fig. 97. 
 
 running in brackets fixed to the frame side. The driving pulley is fastened at one end, and at the other is 
 a traverse arrangement, consisting of an eccentric rotated by a worm on the shaft. By means of a short rod 
 
ARD CLOTHING, GRINDING, AND STRIPPING. 
 
 109 
 
 the revolution of the eccentric gives a small lateral movement — about an inch — to the roller during the whole 
 time it is in motion. The surface of the roller can be covered with emery in the ordinary manner, and is 
 either made plain or grooved. Another method adopted by Messrs. Dronsfield Brothers, is to wrap round the 
 roller a narrow fillet of emery cloth, either plain or grooved as desired. In covering, one end of the fillet is 
 passed into the slit Fig. 98, and is then secured by the clamp shown. About half of the width of the 
 
 Fig. 98. 
 
 Fig. 99. 
 
 fillet is left projecting, and after it is secured, it is wound on by revolving the roller. As soon as the fillet 
 is wound its loose end is passed into one of the three slits Fig. 99, formed at the other end of the roller, 
 and is secured by the clamps. The ends are then trimmed off, and the roller is ready for its work. The 
 grooved covering is preferred by many carders, as it is found to grind the wire teeth better, and to meet the 
 various requirements of the trade it is made in various degrees of fineness. Three of these are shown in 
 
 Fig. 100. 
 
 Fig. 101. 
 
 Fig. 102. 
 
 Figs. 100, 101, and 102, the coarser of the three being used for mild steel or iron wire, and the finer variety for 
 hardened and tempered wire. All the rollers are carefully made, so as to be evenly and truly balanced, and 
 great care is taken to ensure them having a perfectly true surface on which to wrap the filleting. This 
 method of covering rollers has a good many advantages, the chief of which is the ease with which the 
 operation can be conducted as compared with the older method of covering. 
 
 (177) Another form of roller is shown in Fig. 103, this being a modification of the Horsfall tvpe. It 
 differs from the one previously described, which covers the whole width of the surface to be ground, whereas 
 the Horsfall roller is a narrow roll to which a rapid reciprocal movement is given across the surface of the 
 wire. It consists of a light shaft, in which is formed a straight groove for the greater part of its length. 
 In the bottom of this a zig-zag groove is formed, into which a fork enters. The fork in the roller shown in 
 the illustration is mounted in a plug fitted into the boss of the grinding roller, and can be removed and 
 
110 
 
 CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 replaced without difficulty. Oil pads are fitted at each end of the grinding pulley, and are covered with 
 brass caps, so as to keep them in position. In this way the parts are always efficiently lubricated, while at the 
 same time grit and dirt are excluded. The emery roll or pulley is traversed as described by the engagement 
 of the fork and the spiral groove, and as soon as it reaches either end of the longitudinal groove, it is 
 automatically reversed. This action takes place throughout the whole period of grinding. On the whole, the 
 
 Fig. 103. 
 
 employment of the Horsfall type of roller is not so great as that of the continuous roller shown in Fig. 97. 
 When the latter is used all the teeth are ground in a straight line across the cylinder, while the use of the 
 Horsfall implies the grinding of the teeth in a spiral line over the whole surface. It is quite true that the 
 whole of the teeth are ground in either case, but there is an obvious advantage in treating all those in the 
 same line at one time. 
 
 (178) In grinding the cylinder the cover above the doffer is removed, and the wire surface bared. The 
 cylinder is then stripped in a way which will be afterwards described, and the roller is fixed in brackets R, Fig > 
 44, placed to receive it. The construction of these brackets is a matter of importance. They are accurately 
 planed, and fitted so as to move to and from the cylinder centre in radial lines. They must be so fixed 
 to the bend or framing that they are quite level and parallel with the surface of the cylinder or doffer, as 
 otherwise they would grind more off the wire at one side than the other. This is an essential feature, and 
 it is also required that they should be set so as to grind lightly, otherwise there is a danger of producing 
 hooked teeth, which are very detrimental to good work. Generally, the remarks just made apply also to the 
 grinding of the dofter, which is effected by means of the brackets S, the doffer cover being removed, and 
 the doffer stripped. 
 
 (179) The grinding of the flats in revolving flat engines is usually performed by a roller sustained by 
 the brackets T, which are fitted on the side nearest the cylinder, with a surface against which the flat end 
 is pressed by the weighted levers shown. The accurate grinding of the flats involves a nice problem which 
 is worth a special explanation. As was stated in the last chapter, paragraph 117, the flats are formed with a 
 heel which throws up the edge nearest the licker-in, and thus prevents any rolling up of the fibre. In 
 Fig. 104 a diagrammatic representation of the relative position of the flat end and wire surface is given. 
 The flat end is shown by the letters A B C D, and the wire by C D E F. It will be noticed 
 that the line E F is not parallel with A B, which represents the surfaces on the top of the flat 
 ends, but is parallel with C D, which represents the surface on which the flat travels. It is obvious 
 that if during grinding the flat is held against a prepared surface, by means of its face A B, and traversed 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 Ill 
 
 thereon, there will be a corresponding formation of the face E F of the wire, which would become 
 
 parallel with A B. If this happened, the whole object of reducing one of the faces on the surface 
 
 C D would be destroyed, as while the heel would be in that surface it would be removed from the 
 
 wire face. But if, on the other hand, the flat is sustained on the face C D during its passage under 
 
 Fig. 104. 
 
 the grinding roller, the parallel relation of C D and E F is not altered, and therefore the flat is as fit for 
 its work as before grinding. How to sustain the flat when being ground so as to maintain this parallel 
 position is the problem, which is, however, in a fair way towards solution. The steady, forward movement 
 of the flats during grinding somewhat increases the difficulty, but as it is one of the necessary elements 
 of the case it must be duly taken into account. 
 
 (180) In Fig. 105 an illustration is given of an arrangement patented by Messrs. Knowles and Tatham. 
 The grinding bracket carries a pivot on which the weighted lever F oscillates. The unweighted end of F 
 presses against the top side of the flats as they are successively brought within the sphere of its influence, 
 
 Fig. 105. 
 
 being of course turned upside down at this point. A plate B is fixed in the position indicated, being of 
 sufficient width to engage with the flat end without touching the wire. B is, as shown, formed with a 
 shoulder, the difference in the height of the two planed surfaces, D and E, thus obtained being equal to the 
 
112 
 
 CARD CLOTHING, GRINDING, iND STRIPPING. 
 
 heel of the flat. The grinding roller is indicated by the dotted line, as is also the bearing. The position 
 of the shoulder on B is such that the whole of the wire has been ground before the flat end passes 
 over the shoulder, and the flat is thus kept approximately in correct position for maintaining the parallel 
 relation of the wire and working faces. Before the wire on the succeeding flat begins to be ground, one of 
 the ridges on it passes on to the lower surface E, so that the wire face is brought into a horizontal position. 
 
 (181) In Fig. 106 an arrangement made by Messrs. John Hetherington and Sons is illustrated. The 
 ordinary grinding bracket is replaced by another one, fixed in the same position, which carries at its upper 
 end a slide K. This moves in a bed prepared for it in the bracket, and has the necessary bearings formed 
 
 J.N 
 
 Fig. 106. 
 
 for the roller M. Attached to the slide K and the bracket is a spiral spring T, which always tends to 
 draw K against a stop. The vertical lever L extends upward, and its upper end presses against the inner 
 side of the horn of the slide K, so that when L is oscillated the slide is moved forward. On the same 
 spindle, forming a centre for |_, a lever Q is fixed, which has a vertical tail-piece P. A rib is formed on L 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 113 
 
 hrough which a screw is threaded, the point of which presses against the edge of the tail P, and is> 
 when adjusted, locked by means of a nut. The flats pass beneath a plane surface fixed to the inside of the 
 grinding bracket, and their working faces are pressed against it by means of the weighted lever P. The 
 line of the flat traverse while so pressed is shown by the dotted line U V. When a flat enters upon the 
 surface on the bracket it is pressed upwards, as described, and, while so held, the grinding bracket is moved 
 forward over the teeth by the action of the cam R fixed on the chain roller shaft. The rotation of R 
 depresses the lever Q, and gives the required movement to the lever L and to the slide K. It will be 
 noticed that the slide K is placed at such an angle that it traverses to meet the flat, the 
 object of this being to establish such a line of motion of the grinding roller as corresponds to the 
 inclination of the flat relatively to the cylinder during work. The roller traverses in the opposite direction 
 to that in which the flat moves for a certain distance, when it returns and again passes over the wire surface 
 as that is moving forward. During the reverse movement it moves vertically to the same extent as previously made, 
 so that in both cases it grinds the wire points in the desired plane, and thus maintains the true relative 
 distance of both sets of teeth. By the time the reverse movement has taken place, the flat being ground 
 has moved forward sufficiently to pass beyond the range of the roller, and the latter is then ready to grind 
 the next of the series. In this device the principle of grinding by the movement through an angular plane 
 of the roller axis is the central idea, and there can be no question that this is a very likely method of getting 
 a true result. For it is obvious that if the flats were held stationary, and the roller traversed in an inclined 
 plane, the necessary regularity would be given to the wire surface with great exactitude. A similar 
 result is obtainable by similar means although the flats may be slowly moviug, and this is demonstrated 
 by the motion just described, which has been used with great success. 
 
 (182) In Fig. 107 is shown a side elevation of Edge's grinding apparatus, which is made by Mr. Samuel 
 Brooks. Its essential feature consists of a curved plate B, which is fixed either to the grinding bracket A, 
 or to a fixing attached to it. Over this the flats C traverse, and when they reach the centre the snugs at 
 the back are drawn upon the raised portion B 1 , which is sufficiently long to permit of each flat being in 
 contact with it the whole of the time it is passing under the grinding roller. A plate D is maintained in 
 a position above the flats, and the method of forming it and regulating its position constitutes one of the 
 chief features of this arrangement. The grinding roller G is sustained by a bracket or bearing, in which its 
 axis F rotates. The bracket rests upon a cylindrical stem E 1 , fitting inside a cup, and also in a similar 
 recess or barrel E. The latter has a long boss which forms part of, or is attached to, the plate D, and E 1 
 is screwed and fitted with two cylindrical nuts. Thus, by adjusting the nuts, the distance of the centre of 
 F from the under surface of D can be varied at will, and the pressure of the grinding roller upon the wires 
 fixed. The action of this mechanism is as follows : As the flats C traverse they ride upon the projection 
 B 1 , and their working surfaces are forced against the under side of the plate D. The latter is shaped so 
 that the traverse of the flat causes one side of it to become depressed and the other to be elevated. The 
 peculiarity of this arrangement lies in the fact that the change of position of the plane of the flat faces is 
 
114 
 
 CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 sufficient to ensure all the wire points being presented to the action of the grinding roller in their correct 
 plane. In other words, the effect is nearly identical with that obtained when flats are held separately in a 
 stationary frame, and the grinding roller passed over them. Not less important is the ease with which the 
 position of the setting plate D can be adjusted relatively to that of the grinding roller. This power of 
 adjustment is the chief feature of this mechanism, and as, when it is once made it is constantly maintained, 
 
 Fig. 107. 
 
 each of the series of flats will be so ground that the distance of its wire points from its working face will 
 be identical with that of each of its fellows. Thus a set of thoroughly good flats is obtained, each of which 
 is in the best condition to do its work. A further point which it will, perhaps, be well to mention is, that 
 the power of adjustment, existing by reason of the two nuts shown, permits of the flat ends being subject 
 to the required pressure during grinding, which is afterwards constantly maintained. 
 
 (183) Fig. 108 represents in partial section Higgiuson and McConuell's patent, which has been adopted 
 by Messrs. Dobson and Barlow. It consists of a bracket A fixed as usual to the machine framing, and 
 having at its upper portion C a slot in which the small slide D ia fitted. This slide has its underside 
 shaped to the extent necessary to give the flats the required amount of inclination during grinding, and at 
 the end of this surface is formed with a lip as shown, A spiral spring E is fitted in the slot, and presses 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 115 
 
 against the end of the slide when the latter is in its normal position. The flats G, of which there are 
 only two shown, travel in the direction of the arrow, and when turned face up the chain lugs mount upon 
 the nose of the short lever H. A bell-cranked lever F is fixed on the same shaft as H, its vertical limb 
 having a set screw I fitted, by which its range of movement is limited, while its horizontal arm carries a 
 balance weight. As the flats traverse they alternately mount upon the higher part of H, and are thus 
 pressed into contact with the inclined part of the slide D. Immediately afterwards the flat comes in 
 contact with the lip, which prevents its further forward movement. At this time it is in such a position 
 that the wire surface is horizontal, and while in that position it is passed under the grinding roller B. 
 As it traverses it carries the slide D along with it, gradually compressing the spring E until the wire has 
 been entirely ground. When this has happened the slide makes a little further forward movement — its 
 entire traverse being shown by the two vertical dotted lines — when the chain lugs pass off the nose of 
 H, and the flat falls clear of the slide D. Immediately this occurs the spring E pushes the slide back, 
 
 Fig. 108. 
 
 and it is ready to receive another flat. The chief feature of this motion is the employment of the sliding 
 wedge. When the flat is pressed on to this it is held as though it was on a stationary bed, and is, by 
 reason of the horizontal position of the slot, maintained in a constant plane. Thus the wire surface is 
 presented to the action of the roller in a plane parallel to that of the slot, so that, whatever the 
 variation in the flat end caused by wear, it is not affected. There is another point which is somewhat 
 important. The tension upon the chain links caused by the friction of the flats upon the bend is very 
 considerable, and results in a gradual lengthening of the pitch of the chain. If, in addition to this, 
 the extra friction set up by the pressure of the lever H on the flat, thus causing the latter to be forced 
 against the surface of a plate, be taken into account, this tendency to lengthen will be increased. The 
 extent to which this is to be considered varies naturally with the pressure exerted. Although it is not 
 perhaps great it is appreciable, and it is a matter to be considered. In Higginson and McConnell's 
 motion this friction is slight, as the slide D is arranged to move without much power, although the 
 
116 
 
 CARD CLOTHING, GRINDING:, AND STRIPPING. 
 
 compression of the spring towards the end increases the amount required. As the wedge springs back 
 into position it has to slide over the face of the next of the series of flats, which by this time has 
 passed upon the end of the lever H. Thus, although the flat travels forward without friction, there is 
 a certain amount to be considered as the wedge is passing into position on each flat, the pressure being 
 then exerted as in the case of a fixed plate until the flat presses against the lip, and the wedge begins 
 again to slide. 
 
 (184) In Fig. 109 a side elevation of an arrangement made by Messrs. Piatt Brothers and Company, 
 Limited, is shown. In this case, also, the device of a sliding angular surface is employed. A slide H, 
 which is guided in the upper part of the grinding bracket, and upon which a pull is constantly exercised 
 
 Fig. 109. 
 
 by the balance weight M and chain shown, has affixed to its lower side the angular or inclined surface 
 against which the flat end is pressed during grinding. As in the mechanism just described, the surface to 
 receive the flat is formed with a lip, so that the forward traverse of the flats causes it and the slide H to 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 117 
 
 move in the direction of the arrow. A slight curve corresponding to that of the bend is given to the sustaining 
 surface of the slide, and the fiat is thus held in a corresponding position to its working position. On the 
 axle of the chain wheel by which the fiat chain is driven is a toothed cam plate K, which is shaped as 
 shown, so that it can give a forward movement to the lever L. The latter has fixed in it a tooth or catch, 
 which constantly presses on the surface of the wheel K. The lever or bar L is formed with a slot at one 
 end, with which a pin fixed in the end of the chain wheel axis engages, so that the lever "ban freely slide 
 upon it. The other end of the lever is jointed to a lever B, fixed upon a short shaft on which is also 
 fastened the short lever F and the curved arm D. There is a similar arrangement of. mechanism at either 
 side of the machine, and the two arms D are coupled by means of a round bar E, which acts as a weight. 
 In this way a certain torsion is put upon the short shaft, and a tendency is set up in the lever F to move 
 upwards. In doing so F presses against the slide G placed inside the framing and bend. The upper end of 
 G when pushed up presses against the back of the fiat and forces it against the inclined surface, where it 
 remains until the fiat is ground. 
 
 (185) The action of the mechanism is as follows : When a fiat has passed under the grinding roller 
 completely the rotation of the wheel K causes one of the teeth to push the lever |_ forward, and so 
 oscillate the shaft upon which the lever B is fastened. This raises the arm D, and relieves the slide G of 
 the pressure exerted by the weight E. The fiat I at once falls out of contact with the surface of the slide H 
 which is thus free to fall back into position to receive the next of the series, this being the position shown 
 in Fig. 109. It is essential to notice that, while the backward movement of the slide H is taking place it 
 is out of contact with the fiat, so that, neither during its forward or backward traverse is there any extra 
 tension put on the chain. Immediately the slide has completed its movement the engagement of the catch 
 in L with the tooth in K ceases, and L is free to slide inwards, which it is caused to do by means of the 
 weight E. At the same time the slide G is pushed upwards, and lifts the next fiat into contact with the 
 inclined surface on H. It only requires to be said further that the pitch of the teeth on K ensures 
 the requisite movements being given to G to cause the latter to engage every fiat in its turn. 
 
 (186) The rollers and clearers are ground after removal from their places in the machine. A machine 
 of which Fig. 110 is a perspective view is employed for this purpose, this being the type made by Messrs. 
 Dronsfield Brothers, who have specially devoted themselves to this class of machines. The machine consists of 
 a frame which has bearings formed, in which the shaft of the grinding roller revolves. Affixed to the lower 
 portion of the frame is a counter shaft from pulleys, on which the emery roller is driven at a speed of 300 
 revolutions per minute. The roller to be ground is borne by the two bearings shown, which are slid laterally 
 by the extremities of arms secured to a transverse spindle sustained by brackets fixed to the framing. The 
 two arms are moved to or from the frame by means of a hand wheel which is keyed on a short spindle, on 
 which is also fixed a worm. This engages with a quadrant fastened on the transverse spindle, so that the 
 rotation of the worm in either direction gives a movement to or from the grinding roller. In this way the 
 card roller is brought into contact with the grinding roller equally over its whole surface, the axis of the 
 
 i 
 
118 
 
 CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 bearings in the arms being always parallel with those of the grinding roller. A bonnet is placed above the 
 machine, and the dust is removed by the small centrifugal fan shown. The card roller is driven by a separate 
 strap from the counter shaft. 
 
 (187) The flats of self-stripping machines are removed from the latter, and are secured on suitable 
 bearings formed on the frames of a special grinding machine. The bearings are adjustable, so that the correct 
 position is given to the flat during grinding. The faces of the flats when so held are moved across the 
 grinding roller, which revolves at a high speed. As the arrangement is a very simple one, and does not 
 present any great novelty, it is not necessary to describe it in great detail. 
 
 Fig. 110. 
 
 (188) As the wire clothing on the cylinder, doffer, rollers, and flats becomes filled with motes, neps, 
 and short fibres, it is necessary to remove these periodically. This operation is called " stripping," and it is a 
 very important one. Whatever may be said to the contrary, stripping cannot be dispensed with unless 
 some specific be found for the removal of the impurities as fast as they are taken out of the cotton. The 
 plan formerly adopted for this purpose has fallen into disuse, as it implied the stripping of the card during 
 work, and led to the mixing of the stripping with the finished sliver. It has been shown that a clean wire 
 surface is the best for carding, and it will be easily seen that the filling of the spaces between the teeth 
 will materially reduce the elasticity of the wires. Regular stripping is for this reason advisable; but the 
 ease with which, if so carried out, the dirt can be removed, constitutes a further reason for this procedure. 
 Carding speedily becomes poor in quality unless this is looked to, and all spinners should carefully watch 
 this point. Another matter is, that inasmuch as it is practically impossible to strip all the cards simul- 
 
CARD CLOTHING, GRINDING, AND STRIPPING. 
 
 119 
 
 taneously, the operation should be effected so that there should be an equal proportion of clean and dirty or 
 half dirty machines. These are all little points, but they are of great importance in the effective working 
 of a machine. 
 
 (189) The stripping of cylinders and doffers was usually carried out by a wire hand brush, the teeth 
 of which are thrust into the wire spaces and then drawn downwards, so removing the " strips." This is 
 now entirely superseded by the revolving wire brush, such as is shown in Fig. Ill, as made by Messrs. 
 John Whiteley and Sons. This is a roller on which is wound card clothing made of hardened and 
 tempered wire. It can be revolved by hand or power, and is carried in the grinding brackets. In stripping 
 it should be set so that the teeth finally penetrate about T \th inch into those on the cylinder, but should 
 
 Fig. 111. 
 
 be gradually set in to that depth so as to avoid damaging the wire. A speed of 200 revolutions for 
 hardened and tempered, and 150 for mild steel cards is recommended by the makers, the cylinder revolving 
 slowly in the meanwhile. The fleece of stoppings thus produced is removed from the roller by 
 dividing it along the narrow uncovered space shown, after which it will lift off by slowly revolving the 
 roller. A similar plan is followed with the doffer. The rollers and clearers are usually stripped by 
 hand, and it is hardly possible to adopt a better plan. 
 
 (190) In closing the consideration of the carding engine and its accessories, it is necessary to enforce 
 upon the reader the dictum that good carding is absolutely essential to good work. With it a good 
 even yarn can be made. Without it no such result need be looked for. It is impossible to lay too much 
 stress upon this point, and the care bestowed upon the machine and its clothing will amply repay the 
 spinner. Cleanliness is essential, and it is certain that the want of it often leads to trouble and loss in the 
 subsequent stages of spinning. 
 
CHAPTER VIII. 
 
 THE COMBING MACHINE. 
 
 (191) The process of combing is only carried out when the finer and better qualities of yarn, such as are 
 used for thread and lace purposes, are spun. The production of these is conducted with greater care than is 
 necessary with the ordinary quality, and it is essential that the short fibres and neps shall be removed. This 
 can only be done to the extent required by a process of combing. It was pointed out in paragraph 23 that 
 in Egyptian cotton a good many short fibres are found, and as the better qualities of yarn are spun from 
 that class of cotton there is a great advantage to be derived from combing. Carding, as was shown, is a 
 continuous process, while combing is an intermittent one, in which small portions of the fibre are dealt with 
 separately and successively. The parallelisation of the fibres is very completely effected, and in addition they 
 are, in a sense, sorted, all below a certain length being removed. It is true that the mechanism can be 
 adjusted to treat fibres of various lengths, within certain limits, but once it is adjusted only the fibres which 
 approximate to the fixed length pass onward through the machine. This procedure results, as will be very 
 readily understood, in the production of a strong thread or yarn, as, in any portion of its length, the number 
 of fibres contained in the cross section will be almost always the same. The nearly complete parallel order 
 given to the fibres has the same effect, and tends to the production of a thread in which exists all the 
 conditions of absolute strength. The combing machine is, with the exception of the mule, the most interesting 
 from a mechanical point of view in the whole range of spinning machines. In the form which is mostly 
 used it was invented by Heilmann, about 1845, and is best known by his name. Although many attempts 
 have been made to construct machines on a different principle, they have not been more than moderately 
 successful, and the Heilmann machine remains to-day the most approved one for the purpose. 
 
 (192) The carded slivers intended for use in the combing machine are first treated by a special set of 
 machines, the object of which is to draw the fibres into an approximately parallel condition. It was remarked 
 in paragraph 153 that, although the fibres in the sliver as it left the carding engine were in a more or less 
 crossed condition, they were so openly laid that a slight endwise pull would draw them into a practically 
 parallel order. In spinning ordinary yarns this is done by the drawing frames, which are described in the 
 next chapter. Although the sliver eventually delivered from the combing machine is also drawn, it has been 
 found desirable to commence this action before combing commences, and the result is that a sliver is produced 
 which is exceptionally even and strong. The exact operation of drawing will not at this juncture be described, 
 as it will be necessary to go over the same ground at a later stage. 
 
THE COMBING MACHINE. 
 
 121 
 
 (193) The first machine by which the slivers are treated is known as the Sliver Lap Machine, and as made 
 by Messrs. Dobson and Barlow, is shown in perspective in Fig. 112. It consists essentially of drawing rollers, 
 to the action of which the slivers are fed from the cans. From 12 to 16 slivers are treated at one time, 
 and on their way from the guide plate to the rollers, they pass over the spoons formed at the ends of 
 detector levers, this part of the mechanism being clearly shown. The failure of any one of the slivers causes 
 the machine to be stopped as in the drawing frame, so that any unevenness in the lap is avoided. The 
 slivers in passing the drawing rollers are laid side by side, and are in this way flattened, so that when they 
 are delivered by the rollers, they have assumed the form of a ribbon, which is rolled up into a lap, by 
 means of a specially driven roller. This treatment straightens the fibres-, and prepares them for further 
 treatment. 
 
 (194) This is given on the Kibbon Lap Machine, which is illustrated in Fig. 113. The laps obtained in 
 previous machines are to the number of six, placed behind the drawing rollers in the machine. Four lines of 
 rollers are provided, as in the drawing machine, and the laps are thus reduced in thickness until they become 
 like a thin ribbon. By this time the various fibres of cotton are pulled into parallel order, and are in a good 
 condition for combing. They are respectively guided round the curved plates shown, and are laid flat upon 
 
 Fio. 113. 
 
 a highly polished iron plate. The lap which is delivered at the end of the machine furthest from the 
 driving head is laid upon the plate firsthand all the others are subsequently imposed upon it. The combined six 
 laps are then passed through a pair of calender rollers at the end of the machine, by which they are com- 
 pressed, and the combined lap is subsequently wound into rolls of %\ or 8| inches, wide. These rolls or 
 laps are fed to the combing machine. The chief advantages of this arrangement are those arising from the 
 
122 
 
 THE COMBING MACHINE. 
 
 parallel order of the fibres. These are evenly laid in an uncrossed state, and there is consequently little 
 danger of any rupture of them by the comb teeth. Further, the latter are not strained in the effort to 
 disentangle the fibres, and a fruitful source of breakage is thus avoided. There is another point, to which 
 special reference was made in Chapter V., namely, the equalisation of the thickness arising from the 
 imposition of the laps upon each other. 
 
 (195) The lap being produced is placed upon two rollers, A A 1 , as shown in Fig. 114, which is a trans- 
 verse section through one head of a Heilmann machine, as made by Messrs. John Hetherington and Sons. 
 Enlarged views of portions of the mechanism are shown in Figs. 115 and 116. A combing machine is 
 usually constructed with from six to eight heads, the driving mechanism for all of which is placed at one 
 
 Fig. 115. 
 
 end of the machine. The lap rollers A A 1 are positively rotated at a speed corresponding to that of the 
 passage of the cotton through the machine. The lap as it is unrolled is carried along the trough B, made 
 of its full width, the lower end of which terminates a little distance from the feed rollers C C 1 . The 
 bottom rollers of eachfhead are suitably carried on brackets fixed to the roller beam, being made of steel, 
 and a little longer than the width of the lap. They are fluted longitudinally, and drive the top rollers by 
 
THE COMBING MACHINE. 
 
 125 
 
 frictional contact. The top rollers are also made of steel, being plainly cylindrical and covered with a sheath of 
 cloth and leather, but a porcupine roller is often used instead of a pair of rollers. This, it is contended, opens the 
 lap and decreases the waste. They are weighted by means of hoots on their axes, to which springs are attached. 
 Immediately in front of the rollers the nipper is placed. This consists of two jaws, the upper one, D, 
 being fastened to the lever E, which oscillates on the short shaft F, receiving its motion from a cam at the 
 driving end of the machine through a shaft, short lever, and the connecting rod G. The lower jaw, H, is 
 also made of steel, being rounded at its outer edge and covered with smooth leather. As the upper jaw is 
 peculiarly fluted, as shown, the contact of the two establishes a nip of the cotton at the points of the 
 
 n 
 
 ]■ 
 
 ii , i i 
 
 J,N. 
 
 Era. 116. 
 
 flutes. The lower nipper blade, H, is fixed to two levers, I, which rock upon the shaft J. The spiral 
 springs, K, are attached to the tail ends of the levers, I, and ordinarily keep the lower jaw in the position 
 shown in Fig. 116, but also permit of it making a slight receding motion when pressed by the upper jaw 
 after the nip is created. 
 
 (196) The foregoing portion of the machine constitutes what may be called the feed part, there being 
 three distinct operations in the process — feeding, combing, and detaching. In front of the nipper the top 
 comb, L, is fixed, being attached to the lever M in such a way that the necessary adjustment can be made. 
 Below the nippers the comb cylinder N is placed, being constructed with a barrel or " comb stock," to which 
 
126 
 
 THE COMBING MACHINE. 
 
 is attached the comb needles. Of these there are seventeen rows, fixed in a metallic bed, or piece, known 
 as the " half lap." These should be accurately shaped, so as to be readily renewed or replaced when required, 
 and are fastened to the comb stock by screws. The width of each row of combs is a little greater than 
 that of the lap, and each row is parallel to the others. The needles are set at different pitches, beginning 
 with one of ^th inch in the first row and terminating with one of ^th inch in the last. On the 
 opposite side of the barrel a segment N 1 is fixed, which is fluted longitudinally. A circular brush, O, is 
 fixed so as to clear the needles as they revolve, and can be easily set up so as always to be in touch 
 with the combs. This brush revolves between the comb stock and the doffing cylinder P, and running 
 at a higher velocity than the latter, it removes the waste taken from the cylinder and transfers it to the 
 doffer, which is clothed with a metallic brush surface. An oscillating comb removes the waste from the 
 doffer and beats it into a receptacle formed to receive it. 
 
 (197) The detaching portion of the mechanism consists of the three rollers Q S and T, but the fluted 
 segment N 1 also aids in this portion of the work. The roller S is known as the "steel detaching" roller, 
 and receives an intermittent motion in both directions from a cam at the end of the machine. The roller Q 
 is known as the "top detaching" or the "leather" roller, and is covered with leather, being borne by levers R> 
 to which the necessary oscillation is given by a cam and the connecting rod R 1 . The heads of the levers R 
 are arranged with a block and setting screw, by which the period of contact of the roller Q and segment N 1 is 
 regulated. The movement of Q is round the detaching roller towards the comb cylinder until it comes in contact 
 with the fluted segment N x , after which it is again returned to its original position. The top roller T is made 
 brass-covered, having longitudinal flutes, and is of sufficient weight to nip the sliver firmly. It, of course, 
 receives its rotary motion from the detaching roller, and is carried in a lever known as the " horse tail." After 
 passing the rollers S T the combed sliver is carried along a trough through a trumpet-shaped guide to the 
 calender rolls U V, which deliver it on to a highly-polished plate. It is thus guided to a draw box at the 
 front of the machine, in which are drawing rollers, and is then passed into a coiler, as in the carding engine, 
 being delivered into similar cans. 
 
 (198) Having thus described the mechanism employed, its method of action can now be explained. The 
 lap, being passed to the feed rollers, is delivered by them intermittently in short lengths corresponding to 
 that of the staple. This intermittent rotation is obtained by the use of a star wheel, which is revolved by 
 a train of gearing from the cylinder shaft. The extent of the forward movement is regulated by the length 
 of the fibre, the roller making such a portion of a revolution as causes its surface to move that distance, 
 usually from |th to y^-th of a revolution. The roller being one inch diameter, the relative distance its 
 surface would travel, and the length of fibre delivered in each case, would be -39 or -31 inch. The nipper 
 jaw D, while this movement is being made, is open, and the top comb L is dropped. As soon as the rotation 
 of the feed rollers ceases the nipper closes and grips the fibre. The downward movement of the top nipper 
 blade D is, however, continued beyond that point, and the lower jaw H receives a further downward movement 
 which puts the helical springs K into tension. In the ordinary position of the nippers the comb needles in 
 
THE COMBING MACHINE. 127 
 
THE COMBING MACHINE. 
 
 129 
 
 their revolution would pass the cotton, but the recession of the nipper, as described, brings the uncombed end of 
 the lap into the path of the needles, which accordingly pass through and comb it. It may be here explained 
 that after the process of combing the combed and uncombed parts of the lap are separated, and that, 
 after the free end of the latter is combed, a small portion is pulled away from it, and joined to the previously 
 combed portion in the manner about to be described. For convenience it will be as well to refer to the 
 uncombed cotton as the lap, and to the combed cotton as the sliver. 
 
 (199) The circular combs having passed, the continued revolution of the nipper cam allows the nipper to 
 again move forward, and to carry the combed end of the lap into a position in which it can be dealt with 
 by the fluted segment N 1 . The top comb L drops into the lap at a point in advance of the uncombed 
 portion, and the leather roller Q at the same time is moved round the detaching roller S. As the fluted 
 segment N 1 comes under the cotton the leather roller engages with it, and the continued revolution of the 
 former causes the two to act as a sort of revolving nipper. The nipper D has been previously opened and a 
 tuft of cotton is drawn away from the lap, partially by the action of the segment and leather roller. To the 
 latter a peculiar motion is given by a cam, which acts through special mechanism. It is not enough that 
 the combed tuft should be detached from the lap, but it must also be attached to the sliver. In order to 
 effect this the detaching roller moves backward to the amount of one-third of a revolution, previously to the 
 engagement of Q with N 1 . This, of course, carries a corresponding length of the sliver with it, and lays 
 the free end of the combed tuft on to the free end of the sliver, to which it is at once attached by the 
 pressure of the leather roller Q. The backward motion of the detaching roller commences after the combs 
 have passed through the lap end, before which it is stationary. The piecing being complete, the segment 
 N 1 and leather roller Q recede from each other, and the detaching roller makes a forward movement 
 of two-thirds of a revolution. This results in the complete attachment of a tuft of cotton, the uncombed 
 part of which is drawn through the top comb, this preventing the passage of short fibres and nep, which 
 are retained in the lap, and removed by the next passage of the rotating combs. The attachment having been 
 accomplished the detaching roller becomes stationary, the top comb is raised, a fresh portion of lap is fed, 
 and the process is recommenced. 
 
 (200) There are thus three distinct stages in combing, viz., the feeding, combing, and detaching, and in 
 the course of the operation the tuft of cotton is completely separated from the lap, and joined to the sliver. 
 It is, of course, absolutely necessary in a machine the movements of which are so delicate, to establish and 
 maintain a very accurate setting. For this reason ample provision is made by which the adjustment of the 
 various parts can be accurately effected, as a reference to Fig. 114 will show. Although the motion given by 
 the cams is of necessity a positive one, and its range fixed to suit the material, the timing of the movements of the 
 different portions of the mechanism is secured by the facilities named. The full importance of this power will be 
 appreciated when it it is stated that from 80 to 95 " nips " or beats are made per minute. Without the 
 most delicate setting it would be impossible to ensure successful work, and this explains the reason for the 
 many adjusting screws shown in Fig. 114. 
 
130 
 
 THE COMBING MACHINE. 
 
 (201) In treating of the carding engine it was explained that the production of an even sliver was of 
 high importance. This is equally so in the combing machine. It has been explained that the cotton is held 
 by the nipper jaws, while the projecting end of the lap is combed, and it will be readily understood that 
 this action will tend to widen or flatten it a little. This result is also produced by the action of the 
 feed and detaching rollers. Thus a sliver is produced with uneven edges, which is very undesirable. 
 In order to remedy this, Messrs. John Hetherington and Sons have adopted the device which is 
 shown in front elevation and section in Figs. 117 and 118. In this case the lower nipper jaw, 
 or cushion plate A, has attached to it at each side a guide plate, which has two projecting pieces C D, 
 one at the front and the other at the back of the nipper. D is curved so as to allow the jaw B to descend 
 
 O.N. 
 
 Fig. 117. 
 
 Fig. 118. 
 
 without difficulty. The two guiding portions C and D are coupled by a connecting piece E so as to form 
 one casting. The nipper plate is cut away, as shown at F, to clear the front guide, which is arranged so 
 as to be in contact with the front edge of the cushion plate A. By this arrangement it is practically 
 impossible for the fibres to escape sideways as the lap is nipped. The length of the nipper plate is sufficient 
 to hold all the fibres firmly, thus ensuring their perfect combing. The fibres are prevented from lifting 
 during the descent of the nipper by a small projecting piece and by the back guide D. The cylinder is also 
 formed with a flange to obviate spreading. By these arrangements a wider lap can be used than would 
 otherwise be the case, and the amount of cotton passed is therefore greater. In addition to this the 
 selvedge is much more even, and the sliver produced in better condition for drawing. 
 
 (202) In Fig. 119 a perspective view, and in Fig. 120 a sectional view is given of Messrs. Dobson and 
 Barlow's Heilmann combing machine. In the main it is similar to the machine previously described, but 
 there are some alterations in detail which require explanation. One of these is shown in elevation and plan 
 in Figs. 121 and 122, and is an improvement in the mode of working the detaching rollers, which it was 
 shown have to revolve a little distance in each direction alternately. This motion is placed at the end of 
 the machine, and consists of a large cam F, which is suitably driven and with which a bowl fastened in 
 
THE COMBING MACHINE. 
 
 133 
 
 quadrant C engages. C is formed on its outer edge with a toothed rack, which engages with the pinion B, loose 
 and sliding upon the spindle of the detaching roller C 1 . B is part of a toothed clutch, as shown at E, and 
 has a ring groove formed on its boss, with which a claw at the end of the lever G engages. The sliding 
 
 J.N. 
 
 Figs. 121 and 122. 
 
 half of the clutch is usually drawn inwards by the spiral spring shown in the plan, so that the normal 
 tendency of the two parts is to engage. At the end of the lever G a pin carrying a bowl is fastened, the 
 latter being constantly in contact with a cam surface fixed on the shaft on which the cam F is secured. 
 
134 
 
 THE COMBING MACHINE. 
 
 The action of this mechanism is easily understood. The cam surface which actuates the lever G at the 
 moment when the detachment of the tuft of cotton is completed, allows the clutch to become engaged. 
 Simultaneously with this the cam F causes the quadrant to make its stroke, and thus rotate the detaching 
 roller C 1 as much as is required when the lever G is moved, so as to disengage the clutch, and the detaching 
 roller is free to revolve. The advantage of this motion is principally its simplicity, which causes it to be 
 easily worked at a high speed without endangering its positive action. It can readily be adjusted to suit 
 different staples of cotton, without any change pieces. 
 
 (203) Referring now more particularly to Fig. 120, it will be noticed that a change is made in the construction 
 of the nippers. In the machine as usually constructed, the lower blade H is used as a cushion, being 
 covered with leather, an operation which is a somewhat delicate and difficult one. In Messrs. Dobson's 
 
 Fig. 120. 
 
 machine the lower nipper blade H is made a somewhat blunt V shape, while the upper blade or knife D is fitted 
 with a narrow strip of india-rubber or leather. The nip is obtained between these surfaces, and owing to the 
 yielding nature of the strip, an efficient grip is always established. As a corollary of this the lower nipper 
 
THE COMBING MACHINE. 
 
 135 
 
 blade D is fixed, and does not yield as in the ordinary mode of construction. The cam for working the nipper is 
 shown at K, and its motion is communicated through the lever and rod G. Its shape is such that it works 
 easily and smoothly without any difficulty, at a speed of from 80 to 95 nips per minute. 
 
 (204) In order to avoid misapprehension, it may be as well to say at this point that the mechanism 
 employed being similar to that in the ordinary machine, the various parts are all marked with the same 
 reference letters in each case. The cotton is marked Z and its passage through the machine can be clearly 
 followed. This will avoid any special reference to the mechanism common to both machines. The leather 
 roller Q is in this case carried at the ends of two levers R, which are coupled directly to the lever W, 
 which receives the necessary reciprocal motion, and the joint X at the end of W is so arranged, that it can be 
 very readily set. The setting is very easily made, and as the operation of the "leather" or " piecing " roller 
 is one of the most delicate in the machine, any means by which this can be more readily adjusted is of 
 importance. The top roller T is made of a large size, so as to press well down upon the detaching roller, 
 and not to vibrate, however high the speed of the machine may be. A minor improvement is made by arranging 
 that as the bristles of the cleaning brush wear, they can be driven at a quicker speed. 
 
 (205) Although the Heilmanu machine has been in use for about 40 years, it is a singular fact that no other 
 machine for the same purpose has had anything like the same success. A machine, invented by Mons. Imbs, has 
 been used to a certain extent on the Continent, but it has not been adopted except in a small percentage of the 
 cases in which the Heilmann has been used. A machine, which is extremely ingenious in its mechanism, and 
 which has been a little used for short stapled cotton, is the joint invention of Messrs. Piuel, Lecceur, and 
 Hetherington. In this machine the principle of a revolving nipper is adopted. A long pipe forms the main 
 moving piece of the machine, and is of sufficient length to constitute six heads, its circumference being divided into 
 three parts. For each head three longitudinal slots are cut in the pipe equal in length to the width of the lap. 
 Three sets of nippers are fitted to each head, the fixed jaw of each coming up to the edge of the slot, which, when 
 the nipper is closed, is covered by the loose jaw. When the nipper is open the slot is exposed. Between each 
 pair of nippers is placed a comb segment with thirteen rows of needles. A feed nipper presents the end of the 
 lap to the needles, the pipe then revolving at its highest speed. When the end of the lap has been combed the 
 revolving nipper comes opposite the feed nipper, which is stationary, and the pipe revolves at a slower speed to 
 allow the combed end of the lap to be drawn into the nipper. This is effected by the suction of an air current 
 induced by a fan connected to the tube. This operation being completed, the revolving nipper closes on the lap 
 and the feed nipper allows a short length of lap to be taken through. The separation of the tuft is then made, 
 and its other end is combed by being drawn through a top comb as in the Heilmann. The pipe then continues to 
 revolve, and while the next in the series of nippers is taking its feed, the one holding the combed tuft opens 
 slightly on arriving at a table placed at the front of the machine. By the aid of a pusher the fibres are superposed 
 on those already on the table, a continuous fleece being thus made which is taken forward by two pairs of draw 
 rollers. The sliver is made exactly as in the Heilmann. The Lecoeur machine is not suitable for long stapled 
 cotton, but it will comb very effectively the short Indian and American staples. Of these it will produce 4001bs. 
 
136 
 
 THE COMBING MACHINE. 
 
 p3r week, with a par centage of waste of from 16 to 20. It is only in special cases that the combing of this class 
 of cotton is remunerative. 
 
 (206) The waste from the combs, which varies from 15 to 17 per cent, is carried away by the brush, 
 which in turn is stripped by a comb, and the strippings fall upon a lattice. By this they are carried to a 
 calender roll and made into a lap which, as it contains fibres of good quality, but of insufficient length for 
 the ordinary combed yarns, is used up in the manufacture of coarser qualities. The waste from the 
 combing machine being considerable, its utilisation is important. 
 
CHAPTER IX. 
 
 THE DRAWING MACHINE. 
 
 (207) The slivers produced on the carding engine, although, as previously noted, composed of approximately 
 parallel fibres, are not perfectly laid in that way. If, however, they are subjected to a pull in a longitudinal 
 direction they easily assume the parallel position. Even slivers produced on a combing machine, in which 
 the fibres are, as has been observed, in much better order than when treated in a carding engine, are 
 improved by being subjected to this drawing action. The net result of the process is an improvement in the 
 strength of the resultant thread. Not only is it essential to improve the parallelisation of the fibres in the 
 sliver, but it is equally desirable to produce a sliver of even weight and thickness. As it leaves the carding 
 or combing machine the sliver is not so regular in weight as is requisite, and if this irregularity were allowed 
 to go uncorrected a yarn of varying thickness would eventually be spun. It is true that the variations are 
 not serious in amount, but they are of sufficient importance to render it desirable to correct them. Again, 
 it is necessary to reduce tbese irregularities in order to facilitate future manipulation, and, generally speaking, 
 the proper conduct of the drawing process is of prime importance to successful spinning. v 
 
 (208) The essential feature in a drawing machine or frame is, of course, the mechanism by which the 
 extension or drawing of the sliver is effected. As it is necessary to pass the material continuously through 
 the machine while reducing it to parallel order, the use of rollers becomes imperative. These are arranged 
 in pairs, one above the other, and there are four pairs arranged in parallel lines with each other, as shown 
 in Fig. 124. That illustration is a transverse section of the drawing frame as made by Mr. S. Brooks, 
 Figs. 123 and 125 being respectively end and front views of the same machine. The lower rollers are borne, 
 as shown, by brackets B fastened to a longitudinal beam C, known as the "roller beam." They are made 
 in sections and are coupled throughout the length of the frame, so as to form four continuous " lines," which 
 are driven from one end of the machine. Each set of four lower and four upper rollers constitutes a "head," 
 and there are usually from two to four heads in a machine. The lower rollers are made of a special class 
 of wrought iron, very fine and clear in the grain, and are accurately turned throughout, being formed with 
 two or three bosses to each head. They are also fluted with fine flutes in a longitudinal direction, great 
 care being taken to ensure the flutes being smooth and quite free from anything likely to catch the cotton. 
 The upper rollers are made of cast-iron, and are placed on the top of the lower lines, against which they are 
 constantly pressed by means of the hooks D and weights E, the former passing over the arbors of the 
 rollers. The arbors of the top rollers engage with grooves in the roller brackets, and the rollers are thus 
 prevented from moving laterally, although they have freedom of vertical movement. Bars forming caps 
 
138 
 
 THE DRAWING MACHINE. 
 
 for the arbors of the top rollers are fitted, being known as "cap bars." It is the practice to form the 
 top rollers with as many bosses as there are on the bottom rollers in each head, and of a length corresponding 
 to that of the latter. Thus if, in each head, the bottom rollers had three bosses the top rollers would be 
 formed to correspond, and the slivers to be drawn would be passed between them. In this case the head 
 would be said to be one of three "deliveries," and a machine is usually described as being one of so many 
 heads of a certain number of deliveries. It will be easily understood that the top rollers are not positively 
 driven, but derive their motion by frictional surface contact with the lower set. The top rollers are accurately 
 turned, and are usually covered with a specially-prepared soft leather, formed into a sheath, which can be drawn 
 
 Fig. 126. 
 
 over the boss of the roller. Special care is taken in forming these coverings, so that they have no extra thickness 
 at their joints, and, after they are drawn on to the rollers, the latter are subjected to a rolling and pressing action, 
 which beds the leather firmly and ensures the roundness of the roller. The mode of preparing the rollers will be 
 described in full in Chapter XIV. It is now almost the universal practice to use the loose boss top roller invented 
 by the late Mr. Evan Leigh, and illustrated in Fig. 126 in longitudinal section and elevation. Its advantages are 
 many, and arise from the lessened friction consequent upon the more perfect lubrication, which is also obtained 
 with a smaller quantity of oil. 
 
 (209) The rollers are driven from the end of the machine in the way shown in Fig. 123 in end elevation. 
 They may be arranged with all their driving wheels at one end of the frame, or may be — as is the case in 
 Messrs. Howard and Bullough's machine— driven at both ends. That is to say, the driving of the first and 
 fourth rollers may be effected at the gearing end of the machine, while that of the intermediate lines is 
 obtained at the other end. It will be, perhaps, as well to say that the first line here means the back 
 rollers, and the fourth the front. Whatever be the system of driving adopted, the front roller is always 
 the primarily driven one, and for this course there are good reasons. The thickness of the emerging sliver 
 is determined by the relatively superior speed of the front roller, which runs at a faster rate than any of 
 the others. Thus it becomes an easy matter to reduce the speed of the remaining rollers, and this course 
 is preferable to using a slow running wheel as the driver from which higher velocities are to be obtained. 
 
THE DRAWING MACHINE. 
 
 139 
 
 Fig. 125. 
 
THE DRAWING MACHINE. 
 
 141 
 
 Between the driver and driven roller a series of wheels are interposed, which are nsed as change wheels, so 
 as to allow of an easy adjustment of the relative speeds of the whole series. 
 
 (210) The proper construction of a drawing frame turns largely upon the consideration of a number of 
 small points. In this, as in all other machines used in the preparation of cotton, due regard must be had 
 to the material which is being treated. Especially is this the case in drawing. The " staple " here plays 
 an important part. If the distance between the centres of each line of rollers exceeds that of the length 
 of the "staple" it is quite clear that no drawing worthy of the name will take place. To draw anything 
 one end of it must be firmly held, and if the fibres could lie between two pairs of rollers without being 
 gripped by either it is obvious they would not be drawn. Thus the distance between the centres of the 
 rollers must be regulated to suit the material being treated, and the roller bearings are arranged to permit 
 of that adjustment. This leads to the necessity, where very short slivers are drawn, for the reduction of the 
 diameter of the rollers so as to permit of their being set in together more closely than could otherwise be done. 
 Thus East Indian cotton is best dealt with by rollers of a small diameter set closely ; while Sea Island or 
 Egyptian can be drawn by larger rollers set wider apart. The principle underlying this practice has been 
 indicated, but may be formally stated. The necessity exists for the fibre being drawn to be held at one 
 end by one roller, while it is subjected at the other to the pull of a faster running roller. It is therefore essential 
 that the distance between the centres of the rollers shall be such that the fibres are sufficiently drawn 
 without being subjected to overstrain, by which a liability to rupture is incurred. 
 
 (211) It is the universal practice to effect the major part of the drawing between the third and fourth 
 rollers, the increase in speed prior to that having been comparatively small. The exact speeds at which 
 the various lines run depend largely upon the material treated, but a common acceleration is as follows : 
 Assuming the first or back roller to revolve at 100 times per minute, the second line would run at 125, 
 the third at 175, and the fourth at 275. The attenuation of the sliver between the first and second line 
 is only 25 per cent; that between the second and third 40 per cent; and between the third and fourth 57 
 per cent. Putting it in another way, assuming one foot of sliver to have passed through the back rollers, 
 it would become 15 inches long after passing the second roller; 21 inches as it leaves the third roller; and 
 33 inches as it finally emerges from the front roller. Thus, although the 'percentage of increase between 
 the third and fourth is not largely in excess of that arising between the second and third rollers, the actual 
 increase is exactly twice as much. These proportions are approximations to those which are actually 
 employed, but, as was said, much depends on the character of the material which is being treated. In 
 dealing with a soft elastic fibre like Sea Island cotton, light weighting and an easy draught is possible, while, 
 if a harsh strong fibre is subjected to the same treatment there would be little effect produced. It is therefore 
 necessary to put additional weight upon the rollers and thus increase their grip. A severe treatment of this 
 character, which would be fatal to a weak or fine cotton, is beneficial to the coarser varieties, which can easily 
 be subjected to a coarser draught. All these are points which require attention in practice, and careful 
 observation will do more than many instructions in giving the knowledge of the right course to pursue. 
 
142 
 
 THE DRAWING MACHINE. 
 
 (212) Another point requiring close attention is the preservation of absolute cleanliness. All cotton in its 
 passage through the machines used, gives off a certain quantity of loose, short fibre, to which the name of " fly " 
 is given. This is found all over the machine, and it adheres to the rollers in considerable quantity. Unless it is 
 removed in some way it is apt to collect into thick pieces, or "slubs," which attach themselves to the sliver, 
 and thus cause thick places. These, of course, are perpetuated in every subsequent stage, and the removal 
 of the fly, therefore, becomes of great importance. To accomplish this desirable end appliances known as 
 " clearers " are fitted. These are flannel-covered surfaces, either flat or cylindrical, which rest upon the rollers. 
 One common form is a plain, wooden cylinder covered with rough flannel, which is placed upon, and rests 
 between, two of the lines of rollers, the rotation of which causes it to revolve. The rougher surface of the 
 flannel licks up the fly from the rollers, and a periodical stripping is sufficient to keep the clearer effective. 
 A simpler and also a common arrangement consists of a strip of flannel stretched within a cover and resting 
 on the whole of the top rollers. A third modification is known as " Ermen's revolving clearer," and is an 
 endless band of flannel passed over two rollers fixed in the cover. The lower part of the band rests upon 
 the top rollers, and the clearer is slowly traversed, so as to remove the fly and convey it to the upper part 
 of the case when the band is turned up. Here an oscillating comb is placed, and scrapes up the 
 fly into small rolls, which can easily be removed periodically. A further form of clearer is made by Messrs. 
 Dobson and Barlow. It consists of two wooden rollers sustained in a frame which is hinged at one end. 
 One of the rollers which presses upon the back rollers is suitably driven so as to take up the fly from the 
 first and second pair. The other roller is loose upon its spindle, which is much smaller than the bore of 
 the roller, so that the revolution of the front rollers causes it to rotate at a speed somewhat below that of 
 the rollers. Both of the wood cylinders are covered with flannel, and thus take up the fly with very great 
 ease. It was found by practice that the positive driving of the back clearer effectually cleaned the first two sets 
 of rollers, while a similar procedure with the front clearer did not lead to the same result. By allowing the 
 latter to be frictionally driven, the rollers can be kept clean without difficulty. To strip the clearers they 
 only require raising, when the fly can be readily removed. 
 
 (213) A reference to Figs. 123 and 125 will show that extending along the frame is a shaft having a 
 hand-wheel at the end, and a number of worms keyed on it. The latter gear into w r orm wheels, on the axes 
 of which cams are fixed by which a bar — through which the weight-rods pass — is lifted. As the rods have 
 a loop at their upper end which cannot pass through the holes in the bar, it is clear that the elevation of 
 the latter will also raise the weights. In this way the pressure on the rollers is relieved. This is of value 
 when the frame is stopped for any prolonged period, as the maintenance of the pressure during that time 
 results in the formation of flat places on the rollers, which are detrimental to good work. It is undesirable 
 to put on or take off the weight suddenly, and some makers prefer to use a simple lifting appliance by which 
 each weight can be released singly. 
 
 (214) The important features in connection with the roller portion of the mechanism are — first, their 
 perfect finish; second, the adoption of such diameters and distances as are suitable for different lengths of 
 
THE DRAWING MACHINE. 
 
 143 
 
 staples ; third, their effectual cleansing ; and, fourth, the regulation of their velocity so as to suit the material 
 being dealt with. 
 
 (215) It was pointed out in paragraph 207 that there are certain irregularities in the size of the slivers, 
 
 as obtained from the carding engine. Up to the present the machine has been considered as though each 
 
 sliver was treated separately, a course which would result in the delivery of a sliver longer than, but possessing 
 
 the same defects as, the original one. That this must be so is apparent, unless some provision is made for 
 
 the acceleration of the speed of delivery when a thin place was passing, or its retardation when a thick place 
 
 occurred. It therefore becomes necessary to find a method of rectifying these defects, and it is obtained by 
 
 passing several slivers through the machine simultaneously. Reference is now more particularly made to 
 
 Fig. 123, which shows the mode pursued clearly. A number of full cans from the carding engine — up to 
 
 eight — are placed behind each delivery, and the slivers they contain are combined and passed through the 
 
 rollers together. Before passing on to consider the exact effect of this arrangement, a few words may be said 
 
 as to the method of feeding the cans to the machine. As each can contains approximately the same length, 
 
 it follows that, the rate of passage being the same throughout the machine, they would all become empty 
 
 at practically the same time. This implies the necessity for the attendant to remove the cans and piece up 
 
 the new slivers all along the frame almost simultaneously. This is practically impossible, and it is therefore 
 
 highly desirable that there should be an arrangement adopted which would enable the cans to be substituted 
 
 at different times along the frame. In a little but valuable work, " Progress in Cotton Carding," the late 
 
 Mr. F. A. Leigh, of Boston, U.S.A., makes the following remarks: "If there are 10 pounds (or 1,000 yards), 
 
 say, in a full can, instead of putting them all up full at first, it is better to put them up at back of drawing 
 
 in four sections, say : — 
 
 4 or 6 cans 4 or 6 cans 4 or 6 cans 4 or 6 cans 
 
 2£lbs. 51bs. 7£lbs. lOlbs. 
 
 After that replace with the full 10 pounds (or the 1,000 yard) cans, and they will continue to empty in 
 rotation, all full cans having the same length. The tender [minder] will know exactly where to find them." 
 
 (216) The diminution of the irregularities in the slivers is most important. The plan pursued is to 
 pass several slivers through the same set of rollers, and deliver the combined sliver at the front of the 
 machine. The number of slivers which are combined varies considerably according to the practice of different 
 spinners, but is not more than eight. Now, if it be assumed that an irregularity of 40 per cent existed in 
 one sliver, and that it was drawn simultaneously with five others in which that irregularity did not exist, 
 the latter would be reduced to one-sixth, or 6f per cent. It is, however, the custom to " put up," or feed, 
 the slivers so obtained to another head of the machine, and subject several of them to a second or even a 
 third drawing. Assume, therefore, that four of the partially drawn slivers were fed and again drawn. The 
 irregularity would be reduced to If per cent, and a further drawing would again reduce it. The figures 
 given are hypothetical, and it is not likely, of course, that only one sliver would be irregular in thickness, 
 but the example serves to show the principle. The number of " doublings " given to the sliver is arrived at 
 
144 
 
 THE DRAWING MACHINE. 
 
 by multiplying the number of ends passed through at each drawing. Thus, in the case stated, the doublings 
 are 6x4x4 = 96, and it can be easily seen that any difference in substance which existed at first 
 would be very speedily rectified, and would not be of much moment by the time the finished sliver 
 was produced. 
 
 (217) The number of times the material is passed through the machine and the draught to which 
 it is subjected varies, as was shown, with the class of cotton treated. Thus, the harsh, wiry varieties 
 of cotton stand more drawing, but if well drawn will spin fairly well into weft, which does not receive 
 so much twist as warp, and should be full bodied. How much any class of cotton should be doubled and 
 drawn is a matter to be determined by practice only, and even then great variations in the course 
 pursued will occur. The one thing which must be remembered is that as soon as an even sliver is 
 produced further drawing is unnecessary, and only results in a diminution of the strength of the spun 
 yarn. 
 
 (218) A necessary corollary to the process of doubling slivers is the provision of means whereby the 
 passage of all the combined slivers is ensured throughout their entire length. Assuming, for instance, that 
 eight ends were being passed through the machine, and one of them from some cause failed, it is clear that 
 the delivered sliver would be diminished in thickness one-eighth. Of course the attendant would rectify this 
 at the earliest moment, but, in the interim, a large amount of the thin sliver might have been produced. 
 In order to avoid this serious evil, it is the practice to fit all machines of this class with a detector motion, 
 which operates on the failure of any of the ends. Referring now to Fig. 123, it will be seen that, after 
 passing through the guide-plate F, the sliver is conducted over the end of the short lever G, which oscillates 
 on a knife-edge bearing. The end over which the sliver passes is hollowed out, and is highly polished, while 
 the other end — which is slightly heavier — is beneath a curved guide-plate, shown in section. The lever G is 
 balanced so that the pressure of the sliver during its passnge is sufficient to keep the spoon-shaped end . down, 
 while, on the breakage or failure of the sliver, the lever oscillates on its bearing. A reference to Fig. 124 
 will show that a shaft H, driven from the main shaft, as shown, has on it an eccentric, to which the rod I 
 is attached. This rod is attached to a bell crank lever J, on the shaft K, which is oscillated, and thus 
 gives a reciprocal movement to the levers L, carrying a square bar. A bell crank lever M is also placed 
 upon the shaft H, and ordinarily engages with a snug on the stop rod N. The latter has a helical spring 
 attached, which always tends to pull it longitudinally, and when it is released, to throw over the strap from 
 the fast to the loose pulley. 
 
 (219) Assuming now that one of the slivers has failed, its spoon lever will oscillate and its weighted end 
 will fall. It thus comes in the path of the reciprocating bar in the lever |_, which is prevented from 
 completing its traverse. The result is that the lever M is oscillated and the stop rod N released, so that 
 the spring named at once throws the strap on to the loose pulley and stops the machine. As the reciprocations 
 of L are very rapid, no considerable length of the sliver can pass without causing the stoppage of the machine. 
 The attendant is compelled to piece up the broken end, and "single" is thus prevented. 
 
THE DRAWING MACHINE. 
 
 145 
 
 (220) The sliver may, however, fail between the drawing rollers and the delivery can, and it is therefore 
 necessary to provide a means whereby the machine can be arrested in this event also. In its passage to the 
 can the sliver is collected by a trumpet-mouthed tube and carried over another spoon lever O, balanced and 
 borne exactly as the lever G. The failure of the sliver is followed by the fall of the inner end of O, which 
 comes in the path of the lever P, to which a lateral reciprocal motion is given from the shaft H, as shown. 
 This results in the stoppage of the machine exactly as in the case of the back stop-motion. 
 
 (221) After passing the detector lever, the sliver goes through another tube and is compressed by the 
 calender rolls Q, driven as shown in Fig. 124. These give the sliver more cohesion, and slightly flatten it, 
 after which it is treated by the coiler head R, which is of the same construction as that employed on the 
 carding engine, and is driven by the gearing indicated in Fig. 123. Some makers provide a full can stop 
 motion, which operates when the can gets quite filled with cotton. There is a danger, if the attendant is 
 careless, of it becoming jammed under the coiler plate and serious damage occurring. In order to obviate 
 this, a thin plate is fitted below the coiler plate, thus forming a sort of false bottom This is weighted 
 suitably for various strengths of slivers, it being desirable to press the sliver to a certain degree in order to 
 get as great a length in each can as possible. The amount of this pressure is, of course, variable, and care 
 must be taken not to make it too great. When the loose plate is raised it lifts a vertical stop which comes 
 in front of a lever coupled to the front end of a lever corresponding to P, in Fig. 124, and the motion of 
 the latter is arrested as before, with the same result. This is the arrangement used by Messrs. Piatt Brothers 
 and Co., Limited. 
 
 (222) It sometimes happens that a sliver in coming out of the can will be formed into a knot, or loop, 
 which, when it comes into the guide plates, F, cannot pass through the holes in the latter. The result is, 
 that the sliver is broken and requires re-piecing. Now, it is desirable to prevent the breakage of the sliver 
 when possible, and the case named is met by Mr. Brooks by the use of the motion shown in detail 
 separately. The bar fixed in L oscillates under a catch lever S, which is balanced by the plate F, so as 
 to be raised above the path of 1_. When, however, a knot occurs, the plate F is drawn inward, 
 and the catch lever S brought in the way of the bar in L, the oscillatory movement of the latter being 
 arrested. The machine is thus stopped, as in the cases previously named. In order to make this move- 
 ment more sensitive, the plate F is balanced by the weighted lever fixed on the same rod on which F 
 oscillates, the weight being adjustable to suit different strengths of sliver. 
 
 (223) Messrs. Howard and Bullough have for some years made an application of electricity to this 
 machine for the purposes of stop motions. Their arrangement is shown in Fig. 127, in transverse section. 
 The machine is practically divided into two pieces, which are joined together, but have pieces of some 
 insulating material introduced into the joint. One half of the machine thus constitutes one pole, and is 
 connected to the battery, or dynamo, by the rod R ; and the other half being the other pole, also coupled 
 to the battery by the rod O. The sliver, as it passes to the back roller, goes between two rollers S T, 
 which are coupled to the positive and negative poles respectively. The lower roller is fluted and is the 
 
146 
 
 THE DRAWING MACHINE. 
 
 full length of the machine, while the upper roller is only long enough for two slivers. Failure of an end 
 is followed by the contact of the two rollers, thus establishing the circuit and causing a current to pass 
 through the magnet X, which attracts the catch Z. The latter engages with a constantly revolving cam 
 and thus stops the latter, this being followed by the release of the knocking-off lever. The lapping of 
 a sliver in passing through the drawing rollers causes the top front roller H, which is coupled to one pole, to 
 engage with a pin |_, connected to the other, and so stop the machine. The breakage of the sliver before 
 
 Fig. 127. 
 
 reaching the calender rollers N K, is followed by the establishment of contact between them, with the usual 
 result. Over filling of the can lifts the tube plate in the coiler O, and completes the circuit with the same 
 result. The use of electricity in this connection has greatly simplified the machine, and has proved to 
 be a great success. 
 
 (224) It only remains to be said that the diameter of the front roller is from 1 inch to If inches, 
 according to the work required, and the speed at which it is run, from 290 to 450 revolutions 
 per minute. 
 
CHAPTER X. 
 
 SLUBBING AND ROVING MACHINES. 
 
 (225) The sliver as left by the drawing frame consists of a number of fibres arranged in a parallel 
 order, and contains a little twist introduced by the coiler. It is not practicable to carry the parallelising 
 process much further, as the drawn slivers are so attenuated that very little more draught would pull 
 the fibres asunder. As, however, it is essential, in order to produce a yarn of the requisite fineness, that a 
 further reduction shall be effected, it is the practice to gradually introduce into the sliver a small amount 
 of twist. This is done by stages, and at each stage the partially twisted fibre is subjected to the action of 
 drawing rollers. The machines about to be described, therefore, have a dual action, and, in most cases, 
 are three in number, known respectively as slubbing — second slubbing or intermediate — and roving frames. 
 While this is the rule, it is not the universal practice. In spinning coarse counts, for instance, only the 
 first and third of the series are sometimes employed, while the production of very fine yarns is aided by the 
 use of a fourth machine, known as a "jack" frame. Whatever may be the number of steps by which 
 the process is completed the object is the same — to reduce the sliver to an even round thread of such 
 proportions that it can be readily twisted into yarn of the requisite diameter. The introduction of a 
 slight twist binds the fibres together, and enables them to be drawn as required without breakage. 
 The thread finally produced is technically known as a " roving." The various machines being practically 
 identical in their details, varying only in correspondence with the increasing fineness of the thread, it is only 
 necessary to give a description of one of the series. 
 
 (226) In Fig. 128 a front view of a slubbing frame, and in Fig. 134 a back view of a roving 
 frame, as made by Mr. John Mason, are shown. The sliver is brought from the drawing frame in the 
 cans in which it is coiled, these being placed at the back of the slubbing machine. It is drawn from 
 the cams over a guide roller, and is then conducted to the drawing rollers. After being treated in 
 the slubbing frame the bobbins produced are placed upon wooden pegs, pointed at both ends, which are 
 sustained in bearings in the light frame S shown in Fig. 134, this being known as a "creel." The bobbins 
 are borne in an almost vertical position, and revolve easily as the slubbing is being drawn off. There 
 may be two or three rows placed in the creel, which is described as a one, two, or three height creel 
 accordingly. In either case the material is conducted as in the slubbing frame to the drawing rollers. Of 
 these there are usually three, but sometimes four lines, their construction being generally similar to 
 those used in the drawing frame, the back set of top rollers being ordinarily heavier than the front ones. 
 The rollers are carried in brass bearings, fixed to the roller beam, and are weighted as in the drawing 
 
148 
 
 SLUBBING AND BOVING MACHINES. 
 
 frame. Top clearers are fitted above the rollers, which are quite covered by polished cast-iron covers. 
 The bottom rollers are kept clean by the aid of a revolving clearer kept closely pressed against them by a two-armed 
 spring, the ends of the arms being grooved to form bearings for the axes of the clearer roller. The " under clearer " 
 spring is attached to the roller beam, and is usually made of flat steel, stamped out of a sheet. A better form, 
 made from round bright wire, has been recently introduced by Mr. C. H. Pugh, of Birmingham, which has 
 the great merits of catching less fly and being more easily cleaned. As was said in the previous 
 chapter, the absolute cleanliness of the rollers is essential, as otherwise the sliver will adhere to them — 
 this being known as "licking" — and will be wrapped round them, thus producing "roller laps." 
 The drawing action having been fully described in the preceding chapter, it is not necessary to go over 
 the same ground. The diameter of the front rollers in the slubbing frame are about 1^ inch, and 
 in the roving frame 1^ inch. The weights are heavier in the slubbing frame, and in all the series 
 the back rollers are more lightly weighted than the front. Thus the weights used for the front, 
 middle, and back lines in the slubbing frame are respectively 18, 14, and lOlbs; in the intermediate 
 frame 14, 10, and 81bs. ; and in the roving frame (with single bossed rollers) 10, 8, and 61bs; and (with 
 double bossed rollers) 18, 14, and 121bs. 
 
 (227) The mode of constructing the spindles A, is illustrated in sectional elevation in Fig. 129. The 
 spindles are made from round steel from y J g- inch to f inch diameter, and are arranged in two rows, 
 one behind the other, with their centres alternating thus This arrangement permits of more 
 spindles being fitted into the space at liberty. Usually the distance from centre to centre of adjoining 
 spindles denotes the "guage" of a machine, but in the series of machines now being dealt with, the peculiar 
 setting of the spindles prevents this. The " guage " in this case is denoted by the number of spindles in 
 a defined number of lineal inches. Thus, to take an illustration from actual practice, a slubbing frame 
 may have 4 spindles in 17| inches, that being its guage; an intermediate, 6 in 19^ inches; or a roving 
 frame 8 in 20£ inches. The spindles are accurately ground so as to be quite round, and vary in length 
 from 28 to 42 inches. At the " foot " the diameter of the spindle is reduced, and the extreme 
 lower end or " toe " is conical, being borue by a brass footstep fixed in a longitudiual rail. Immediately 
 below the bobbin is an upper bearing or bolster, fixed in a similar rail. On the top of the spindle a 
 flyer B is placed, this being of the shape shown, and constructed of steel. The legs are oval in section, 
 and may be either tubular or solid, being made as light as possible. At the centre of the bridge connecting 
 the legs is a circular double boss C, which is bored throughout, the hole so formed being carefully rounded 
 and polished at its upper orifice. At a point near the top a hole is bored penetrating to that in C, and 
 being also well rounded and polished. The lower portion of C constitutes a socket, into which the upper 
 end of the spindle fits, the latter passing above the point at which the bridge is attached to the boss. A 
 slot is cut across the upper end of the spindle, and a round pin, engaging with the slot, is fixed in 
 the socket of the flyer, which is thus positively driven. 
 
 (228) Attached to one or both legs of the flyer are two snugs or projections D D 1 acting as bearings for 
 pressure fingers or "pressers" E. The latter are round rods, hooked at their upper ends and'beut at right 
 
SLUBBING AND ROVING MACHINES, 149 
 
SLUBBING AND ROVING MACHINES. 
 
 151 
 
 angles at their lower ends. The hooked portion can be dropped into a socket in the upper snug D, and 
 the presser thus oscillates freely on the centre of the bearings D D 1 . The inner end of the finger E is 
 flattened and curved so as to correspond with the surface of the bobbin F, being formed with a guide-eye, 
 as shown. It is made of such a length as always to press upon the surface of the bobbin daring the 
 
 Fig. 129. 
 
 rotation of the flyer, which it is caused to do by the centripetal action set up by the latter. The amount 
 of pressure exerted depends entirely on the rate of the revolution of the flyer, and the practical effect is 
 that the roving is more tightly wound on the body than it would otherwise be. It was at one time 
 
152 
 
 SLUBBING AND ROVING MACHINES. 
 
 customary to use two pressers with each flyer, but it is more generally the practice now to employ one only. 
 Great care is taken to balance the flyer, and, when single pressers are used, one leg is made solid and the 
 other tubular, the presser being fitted to the latter. The sliver, after leaving the rollers, is passed through 
 the upper part of the boss C, emerging by the small hole referred to, being then wrapped round the 
 presser two or three times, and finally conducted through the guide-eye in the finger to the bobbin F. 
 Both the inner and outer surface of the flyer must be absolutely smooth, as otherwise it catches the fibre 
 and forms " fly." For this reason, steel, as a constructive material, has entirely superseded the fine iron 
 formerly used. 
 
 (229) The spindle is borne, as was shown, by a bolster and footstep. In order to give steadiness and 
 reduce friction it is the practice to fit in the former a collar or tubular bearing. This is either " short " 
 or "long." Formerly short collars were the rule, these merely acting as a somewhat longer bearing, the 
 bobbin in its vertical movement sliding upon the spindle. Mr. John Mason then introduced the "long" 
 collar which is shown in Fig. 128. The collar 1 is of sufficient length to extend from the bolster, bearing 
 upwards through the bobbin to a point within the flyer. It is recessed internally, so as not to bear the 
 entire length, but simply to be in contact with the spindle at two points. The latter is thus sustained 
 high up, in addition to being borne, as usual, at the two lower points. The effect is that a much less 
 amount of vibration is set up, and the flyer revolves with greater steadiness. This has an important 
 bearing upon the operation, as it diminishes considerably the risk of breakage. 
 
 (230) Another method which, in many respects, is superior to any other, is that shown in Figs. 130 and 131 
 in vertical section and elevation. This is the plan previously adopted by Messrs. William Higgins and Sons, and 
 now made by Messrs. Crighton and Sons, and Shepherd and Ayrton. In this case the spindle A is carried in a 
 long tube I, which extends downwards until it is" formed, as shown, into a footstep for the spindle toe. In short, 
 the spindle is sustained in a kind of tubular cradle, being to a certain extent entirely free of the fixed bearing rails 
 J K. To these the tube I is attached by swivel joints, so arranged that they are universal, thus allowing the 
 spindle A and flyer B to adjust themselves as required to compensate for any unevenness of balance which may 
 exist in the bobbins or flyers. The tube 1 is recessed for a certain part of its length, So as to form an oil chamber 
 and reduce the friction set up during work. The advantages arising from this arrangement are that, even when 
 the spindle is running at high velocities, any untrueness in the balance of the spindle merely causes it to find its 
 true centre of gravity, and thus avoid vibration or wear. Spindles constructed in this manner can be worked for 
 many years without showing any wear which is at all detrimental, and on this account higher velocities are 
 attainable with ease than can be reached with the ordinary methods of construction. 
 
 (231) The spindles are positively driven as shown in Fig. 130, by means of bevel wheels fastened near the 
 foot. In the arrangement shown in these drawings the spindle pinions F are formed with square holes, into which 
 the spindles, similarly shaped, are fitted. This allows the spindle to be easily lifted out when required for 
 examination. Usually the pinions F are fastened to the spindle by means of a set screw. In either case they 
 engage with a bevel wheel G fastened on a shaft H, carried in brackets fixed to the framing, and extending 
 
SLUBBING AND ROVING MACHINES. 
 
 153 
 
 longitudinally along the frame. The spindles being set zig-zag, as described, there are two lines of them, and 
 consequently there must be two shafts H to drive them, and in order to distinguish between the two, they are 
 supposed to be shown in position in Fig. 131, and the back wheels are marked F 1 G 1 . The shafts H are geared 
 so as to revolve at the same velocity, but in opposite directions, and, as it is imperative that the spindles shall 
 
 Figs. 130 and 131. 
 
 revolve in the same direction, this is attained by gearing the pinions F F 1 on different sides of the centres of the 
 wheels G G 1 , as clearly shown. To enable this to be done, the teeth of the wheels are cut at a special angle or 
 " skew " to suit. 
 
 (232) The bobbin L rests upon a flange of the bevel pinion M placed on the collar, and driven by the wheel 
 N. The pinions are, as shown in Fig. 129, fixed in the " bobbin rail," or, as in Fig. 130, carried on the top of a 
 
154 
 
 SLUBBING AND ROVING MACHINES. 
 
 bearing sustained by the swivel joint. The upper flange of each pinion has formed on it oblong " snugs " or 
 projections, which take into corresponding slots made in the bottom of the bobbins. The wheels N are keyed on 
 the shafts O, which also extend the whole length of the machine, and are suitably borne by brackets fastened to 
 the underside of the bobbin rail. Thus the latter sustains both the driving shafts and the bevel pinions which, as 
 in the case of the spindles, are driven by wheels gearing at different sides of the centre. 
 
 (233) This mode of construction lends itself very easily to the formation of the bobbin or spool of roving, 
 which, at its completion, is of the shape shown in Fig. 128, cylindrical with conical ends. In order to wrap the 
 yarn upon the bobbin L it is necessary to give the latter not only a rotary but a vertical movement. It is, of 
 course, possible to give this motion to the spindle and flyer and not to the bobbin, but this is not a convenient 
 method in the case of machines like those under notice, for many reasons. The rail, therefore, which carries 
 the bobbin pinions and bobbin, known as the "bobbin rail," receives a vertical traverse to an extent which is 
 determined by the class of material to be dealt with. This traverse is a reciprocal one, and is technically known 
 as the "lift," a machine being said to have a lift of so many inches according to the extent of the vertical 
 movement of the bobbin rail. This varies from 10 or 12 inches in the case of the slubbing frame to 5 or 6 inches 
 in the roving frame, and is obtained in a manner which will be presently described. While it is taking place the 
 bobbins are slid upon the spindle, the presser eye continuing to revolve in the same horizontal plane. From 
 this it follows that any yarn drawn through the eye by the rotation of the bobbin is of necessity wound upon a 
 fresh portion of the surface of the latter. It only remains now to point out, before proceeding to deal with the 
 machine in detail, that it has been shown the spindles and bobbins are driven independently, and may, if desired, 
 rotate at various and different speeds ; and that provision is also made for the maintenance of the vertical 
 position of the spindles and flyers while permitting that of the bobbin to be altered. These, added to the regular 
 delivery of sliver by means of the rollers, constitute the essential features of these machines, but the effective 
 manipulation of them gives rise to a number of interesting mechanical problems. 
 
 (234) It has been pointed out that the action of the rollers in attenuating the sliver is identical with that 
 of those in the drawing frame, so that no special description need be given of them. But these machines are the 
 first in which the process of twisting is carried out, and the rollers form an important part of the mechanism for 
 this purpose. In introducing twist into any 3trand or sliver it is necessary that one end of it should be held, 
 while the other is also held and turned at a higher or lower speed. If this is done the strand will be twisted, 
 and the amount of twist is strictly defined by the number of times it is turned.. In actual working it is not 
 practicable to continue so to twist the strand without at the same time submitting it to the action of the 
 spindles continuously. Unless it was so delivered it would be broken because of the shortening which takes 
 place during twisting, and it is therefore necessary to furnish a fresh portion of the sliver to the action of the 
 twisting mechanism. For this reason the sliver, while being firmly held by the nip of the front rollers, is also 
 delivered by them at a definite rate, which depends on their size and rate of revolution. Now, assuming that 
 no such delivery takes place, and that a length of sliver of 10 inches is turned 100 times, there would be in each 
 
 nch of it 10 turns or twists. Suppose, now, that another 10 inches was delivered and the same number of turns 
 
SLUBBING AND ROVING MACHINES. 
 
 155 
 
 made, a similar result would be obtained. It does not matter whether the delivery is constant or intermittent, 
 provided only that the ratio of the length delivered and the number of revolutions of the twisting mechanism 
 remain the same. Intermittent delivery would, however, be very inconvenient in practice in producing rovings, 
 and thus it is requisite to provide for a steady and regular delivery of yarn, as well as a uniform speed of the 
 spindle and flyer. Granting the attainment of these conditions, it is easy to define the amount of twist put into 
 any thread, it being in the same ratio as the number of revolutions made by the twisting mechanism during the 
 delivery of one inch of sliver or roving. Twists are always defined as being so many " turns" per inch, and are 
 arrived at in the way just indicated. As a matter of fact there is a little slip in the rollers, which does not, 
 however, to any large extent modify the rule enunciated. The constants in a machine of this kind are therefore 
 the rate of revolution of the spindles and front rollers ; and, generally speaking, the amount of twist increases 
 as the roving becomes finer. This can be attained by an increase of spindle speed or a decrease of that of the 
 rollers, as will be readily understood, but considerations of a mechanical nature generally lead to the latter 
 course being pursued. The spindle speeds in a slubbing intermediate, and roving frame, dealing with the same 
 class of roving, would be approximately 700, 800, and 1,100 revolutions per minute. A table of productions, 
 speeds, etc., is given on page 174, which will throw some light on this point. 
 
 (235) It has been already noticed that the bobbin receives a vertical traverse, while the spindle is 
 vertically stationary, and that, in consequence, the yarn is wrapped upon the bobbin in spiral coils. The 
 speed of this traverse is carefully regulated so that each layer is quite free from any overlap, while, at the 
 same time, no space should be left between the coils. When the bobbin has wrapped round it for the 
 whole of its length one layer of roving, its diameter is increased by an amount equal to double the thickness 
 of the roving. Thus its circumference is enlarged, and every revolution it makes requires a longer length 
 of material to cover the surface than it did when it was bare. This extra amount must either be fed to 
 the bobbin, or its speed must be reduced, and as the rollers deliver at a constant rate, the latter is the 
 course pursued. Further, the length of roving wrapped upon the bare bobbin during the whole lift is, of 
 necessity, less than that which would be wrapped upon it after a layer has been wound on if the lift were 
 constant. It is essential that the length of each complete layer should be as nearly as possible equal, and 
 for this reason the traverse of the bobbin is shortened slightly after each of its reciprocal movements. The 
 amount of the diminution in lift is in exact correspondence with the excess of length which would be taken up 
 if it remained constant. The increase in the diameter of the spool has thus an important bearing on the 
 lift, and it is of equal moment in relation to another function of the machine. 
 
 (236) A reference to Fig. 129 will show that the flyer and bobbin rotate round the same centre, and 
 the roving delivered by the rollers is passed on to the bobbin through the presser eye, as pointed out. If 
 it be assumed that the yarn passes on to the bobbin at some imaginary point in the circumference of the 
 latter, and that this occupies during its rotation a definitely relative position to that of the flyer eye during 
 its revolution in a concentric circle, it follows that no roving can pass from the flyer to the bobbin. A 
 little thought will make this clear, but Fig. 132 will serve to illustrate it. In this figure, A is the 
 
156 
 
 SLCJBBING AND KOVING MACHINES. 
 
 spindle, B the circumference of the bobbin, and C the path of the flyer eye. Now, as A and C are 
 attached in the manner previously described, they must of necessity revolve at the same speed. On the 
 other hand, the rate of rotation of B is capable of variation by reason of its independent driving. Let D 
 and E represent respectively the points at which the yarn leaves the flyer C and passes on to the bobbin 
 B. It is obvious that if the relative position of D and E remain unchanged— that is, if they travel at 
 equal speeds, so that the line between them is always alike — there can be no passage of roving from D to 
 E ; or, in other words, there can be no winding. But if the point E makes a complete revolution in less 
 time than D does, or vice versd, winding will take place. In the first case the quicker motion of E would 
 result in the bobbin B taking up roving from D ; and in the second the greater velocity of D would 
 cause it to wrap the roving round the bobbin. To make this clear, suppose the lines A D and A E to 
 
 Fig. 132. 
 
 Fig. 133. 
 
 represent radial lines drawn through the points D E at the commencement of winding, and that at the 
 termination of say three revolutions, the position of these lines relatively is the same. It is perfectly clear 
 that the line D E will have remained unaltered, and no passage of the roving will have occurred. But now 
 assume that the flyer C had moved so much faster than the bobbin B, that the radial lines through D 
 and E were in the position shown in Fig. 133. It will at once be seen that C will have drawn forward a 
 certain length of roving corresponding to its gain, and that the portion of its circumference between the 
 point where the material from D passes on to it and the point E will be covered by the roving. In 
 the event of B moving faster than C, the effect is identical with that described, although it is obtained in 
 an entirely different way. 
 
 (237) This statement of the general principle is sufficient to show the conditions under which winding 
 is successfully effected. The gain either of the bobbin or flyer upon the other is technically called the 
 "lead," and thus a frame is said to be constructed with a bobbin or flyer "lead." The determination of 
 the amount of lead is very simple, and is fixed by the speed of the rollers, it being manifestly impossible 
 to take up more yarn than is delivered. It follows, therefore, that the excess of the surface speed of the 
 bobbin or spool at any stage of its development must accurately correspond with that of the front rollers. 
 If this condition be departed from, either by the lead given being too great or too little, the result will be 
 
SLUBBING AND ROVING MACHINES. 157 
 
 broken yarn ; in the first case by stretching, and in the second by the production of slack places which 
 become entangled and broken. It may here be stated that it is now almost universally the practice to let the 
 bobbin lead, as, with the flyer leading, a certain amount of stretch is put into the yarn, which is very injurious. 
 This defect is especially noticeable in starting the frame, and it is entirely remedied by giving the lead to the 
 bobbin. 
 
 (238) Assuming, then, that the bobbin leads, it is necessary to consider the effect of the gradual increase in 
 the size of the bobbin, caused by the winding on of the yarn. This difficulty is rendered acute by reason 
 of the positive driving of the bobbin. In flyer frames, used for spinning or doubling, the bobbin has a little 
 slip which can be easily adjusted, but which is not obtainable in this case. The slip of the bobbin is caused 
 by the drag of the yarn, a procedure which at this stage is practically impossible. Every traverse of the 
 bobbin rail is, as has been seen, accompanied by an increase of the circumference of the bobbin corresponding 
 to the diameter of the roving. Thus, to take an extreme case, assuming the diameter of the empty tube 
 to be 1£ inch, it would take up at each revolution 4*7 inches of yarn. If the yarn was £ inch thick, the 
 diameter of the bobbin would be If inch after one layer, and each revolution would take up 5-5 inches of yarn. 
 This is, of course, assuming that the flyer is absent, and that the bobbin was winding. As the surface 
 velocity of the bobbin and front roller must correspond, and no more sliver is delivered at one time than at 
 another, it follows that the rate of revolution of the bobbin must diminish in exact proportion to the increase 
 of its circumferential speed. It is, therefore, easy to calculate the exact amount of retardation at each 
 traverse by a knowledge of the diameter of the yarn, or the number of layers to be wound on any spool. 
 
 (239) It is thus easy to see that with the bobbin leading it should gradually diminish in speed, and it is 
 consequently the practice to run it at a much higher speed at the beginning than at the termination of winding. 
 For instance, an empty spool 1 inch diameter takes up per revolution 3-1416 inches of roving, while one 3 inches 
 diameter would take up 9-42 inches. It thus becomes imperative to reduce the speed of the bobbin wheels, and 
 these being constantly geared with their driving wheels, it is necessary to reduce the velocity of the bobbin shafts. 
 These are driven, as described hereafter, by a train of gearing from the main shaft, and special means are adopted 
 to compass the reduction. The spindles are running at a constant speed, and it follows, in consequence, that the 
 bobbin must run at the same rate, plus the number of revolutions necessary to take up the length of yarn 
 delivered in any given time. If, for instance, the spindles made 100 revolutions while 10 inches of yarn was 
 being delivered, the bobbin must revolve 100 times plus the number necessary to take up the 10 inches of yarn. 
 
 (240) When the flyer leads, the application of this principle is not quite so clearly seen at first sight, but a 
 little reflection will make it understood. In this case the winding is effected by the excess of the speed of the 
 flyer over that of the bobbin. This is exactly the reverse of the practice when the bobbin leads, 
 but the essential condition is, as before, the preservation of the relative surface speeds of the 
 bobbin and roller. Suppose that, iu starting, the diameter of these two are the same, then 
 the bobbin must lag behind the flyer to the extent of one revolution for each revolution of the roller. 
 But as the bobbin increases in diameter, it requires more yarn to cover its surface, and a less 
 
158 
 
 SLUBBING AND KOVING MACHINES. 
 
 difference in speed is needed, as, if the bobbin continues to lag one revolution, the difference between the 
 speed of delivery and that of winding become so great as to stretch and break the roving. Instead of wrapping 
 it round, for instance, a circumference of three inches it has eventually to be wound on one of six inches, and it 
 is obvious that if the speed of the bobbin remains constant the roving will be drawn and broken. It is, therefore, 
 necessary to gradually increase the speed of the bobbin so that for every inch of yarn delivered, an inch of the 
 circumference will be covered by it. The difference between this and the former case consists in the fact that the 
 roving is wrapped on a concentric surface, revolving in the same direction at a slower speed, while, with the bobbin 
 leading, the surface on which the roving is wound, moving in excess of the speed of the flyer, draws the roving 
 through the flyer eye at a rate equal to that of its delivery. In other words, it is in one case wrapped on by the 
 excess of the flyer speed or the drag of the bobbin, while, in the other, it is drawn on by the excess of speed of 
 the bobbin. The conclusion is thus arrived at that when the flyer leads, the bobbins must start at their slowest 
 speed, and gradually increase ; while, when the bobbin leads, it must begin at its highest speed and gradually 
 diminish. 
 
 (241) Having thus explained the principle of the machine, it now remains to describe the mechanism by 
 which it is carried into effect, referring for this purpose to Fig. 134. The driving, or "jack," . shaft 
 A has a fast and loose pulley on its outer end, and has fastened on it two spur wheels. One 
 of these drives, by means of a carrier wheel, a wheel fixed on one of the spindle shafts, and motion is 
 given to the spindles in the way previously described. The speed of the spindles, being independently 
 obtained, can be changed without reference to the other motions. The pinion C is known as the " twist wheel," 
 and is made as large as convenient. It drives, by the intervention of a carrier wheel, a pinion D fixed on the shaft 
 on which the cone E is also keyed. The shaft carrying D has also fastened on it, within the framing, a pinion 
 which directly gears into a wheel fixed on the roher axis. Thus the twist wheel C drives the cone E and the 
 rollers, so that if it is replaced by a smaller wheel, both of these revolve at a lower speed, or vice versd. This is 
 important, because as the speed of the rollers and that of the bobbins are both regulated from the twist wheel, 
 the alteration of their velocities is made simultaneously. 
 
 (242) This part of the mechanism is easily understood and involves no difficulty, but the driving of the 
 bobbins gives rise to a complex problem which necessitates the employment of some ingenious mechanism. 
 The upper cone E drives, by means of a strap or band, the lower cone E 1 . The circumferences of each of 
 these cones are accurately turned to corresponding, but converse, parabolic curves, one cone being convex 
 and the other concave. They must be exactly the same in their largest and smallest diameters, and are 
 .turned in lathes fitted with " former " plates, by which the slide rest is guided in its correct path. The lower 
 cone is carried in bearings B, formed in two arms connected by a tubular stay, oscillating on a shaft (M, Fig. 134), 
 on which is the pinion H. This arrangement is shown separately in plan and elevation in Figs. 135 and 136. 
 A pinion G is fixed on the spindle of the lower cone, and gears with a spur wheel F fastened on the shaft 
 named. Thus, when the cone E 1 is raised or lowered, the pinion G rolls round its engaging wheel F, 
 being always fully in gear. This arrangement is utilised to keep the strap tight, the lower cone being 
 
SLUBBING AND ROVING MACHINES. 
 
 159 
 
SLUBBING AND ROVING MACHINES. 
 
 161 
 
 coupled by an adjustable connecting rod or chain I to a disc fixed on the cross shaft shown, the former being 
 preferable. By revolving the shaft J, the cone E 1 can be raised or lowered, and the tension on the strap 
 can be regulated by means of a right and left-handed nut which couples the two parts of the connecting 
 rod I, Fig. 134. Motion is given to the pinion H, as will be easily understood, from the cone E\ and from it to 
 
 Figs. 135 and 136. 
 
 the shaft K by the carrier pinion which gears with H 1 on K. On K also is fixed a spur pinion L 1 
 driving the plate wheel L, and the worm which engages with the worm-wheel on the upright shaft M, The 
 latter is thus revolved, its precise function being explained hereafter. 
 
 (243) The wheel L forms a part of the ingenious winding, or, as it is sometimes called, "the 
 differential motion," invented by Mr. Henry Holdsworth. This is one of the class of epicyclic wheel trains, 
 of which many instances are known and which are very interesting. Fig. 137 is a drawing on an enlarged 
 scale of this motion, the reference letters, with the exception of L and N, being used for this figure specially. 
 Upon the shaft A a fixed cast-iron tube is placed, upon which the wheel L and the compound wheel D N 
 revolve. The jack shaft A revolves in the tube, and on the shaft is fastened a bevel wheel B which gears 
 with similar pinions C and E. These are carried in bearings formed in the wheel L at equal distances 
 
162 
 
 SLUBBING AND ROVING MACHINES. 
 
 from its centre, and have perfect freedom of revolution. They also engage with the bevel wheel D, cast in 
 one piece with the spur wheel N, which is known as the "bobbin wheel." The latter gears with a spur 
 pinion carried in a double swing frame O O 1 (Fig. 134), centred on the jack shaft and attached at its 
 other end to the bobbin rail. In this way, as the latter rises and falls, the swing frame or "swing" — as it 
 is shortly called — oscillates on its centre,- and the spur pinion rolls round the bobbin wheel N, being always 
 in full gear. By means of a carrier wheel — also borne by the swing — the motion of the bobbin wheel is 
 communicated to a spur wheel on one of the bobbin shafts, and by equal sized pinions on each shaft to the 
 other. Thus, the bobbins are driven by a train of wheels, which are always in gear, no matter what the 
 vertical position of the bobbin may be. The bobbin wheel and its compound bevel run loose upon the 
 cast-iron tube, as previously stated. 
 
 (244) The foregoing description of the winding motion will serve to show the principle of its construction, and 
 its mode of action can now be explained. Suppose first, that the bearings of the pinions C and E are 
 fixed instead of revolving with the wheel L, and that the shaft A is revolved, it is obvious that the 
 revolution of the wheel B would be communicated to C and E. These would rotate on their axes, and 
 would consequently drive the wheel D N at the same speed as B, but in the opposite direction. This may 
 be called one pole of the operation of this motion. The other is reached when the plate wheel L is rotated 
 in the same direction as B at an equal velocity, the wheel D N being then carried round in the same 
 direction, and at the same speed as B. But if the relative velocity of L is reduced, there will be a lessened 
 speed communicated to the wheel D N in the proportion of two revolutions less than that of B for every 
 revolution of |_. That is to say, if B was running at 20 revolutions per minute and L in the same time 
 made one revolution, D N would make 18 revolutions. This gives rise to a curious result in working. 
 When the number of revolutions made by L is half of those made by B, the motion of D N entirely ceases, 
 but as the proportion is varied so as to be slower than B, the velocity of D N is reduced as described, but 
 its direction of rotation will be different. That is, if L makes more than half as many revolutions as B, the 
 wheel D N will move in the same direction as B ; but if it makes less than half, D N will rotate in the 
 opposite direction to B. This motion is admirably treated in Professor Goodeve's "Elements of Mechanism," 
 where its rationale is fully described, and where the student will find ample explanations of the operation of 
 this class of mechanism. It is sufficient for the present purpose, however, to reiterate that the loss of motion 
 in the bobbin wheel D N, is equal to two revolutions of B for each one of L ; and that the direction of 
 motion of D N depends on the speed of |_. It may be said, in amplification, that when |_ revolves at less than half 
 the speed of B, the velocity of D N increases as that of L decreases ; while if the plate wheel L makes more than 
 one-half the number of turns of B the speed of D N increases with that of |_. The middle point thus becomes a 
 sort of zero, a fact which it is desirable to remember. Treated algebraically, the formula may be stated as 
 follows, where b= the velocity of the driving pinion B, 1= that of the plate wheel L, and n that of the bobbin 
 D N, if L revolves in the same direction as the shaft, n = b - 21 ; but if in the contrary direction, then n = ~b-2l. 
 
 (245) The effect of the application of this formula in the latter case is different entirely to the results 
 already described. If the wheel L revolves at the same speed as B, but in the contrary direction, then 
 
SLUBBING AND ROVING MACHINES. 
 
 163 
 
 n = - 3 b, if the value of b be substituted for that of If |_ makos half the number of revolutions 
 that B does, then n = -2 b. The relations of B and D N can thus be accurately ascertained, and by 
 the aid of this formula the speed of the bobbin wheel can be easily calculated. It is only necessary to know 
 the value of the entire train of gearing from the fixed wheel B to the plate wheel N to be able to apply 
 the formula given above. Thus, if it is found that the ratio of the velocity of L and the fixed wheel B be, say, 
 as 1 : 40, and that B makes 250 revolutions per minute, the speed of D N could be arrived at easily. 
 
 Fig. 137. 
 
 Substituting the arithmetical value of I and b for those signs, the result would be »= 250 - 2(-^°) = -262-5. 
 As the changing position of the cone strap is the only variable factor in the problem, it is only necessary to know 
 the diameters at various points to ascertain accurately the reduction or acceleration of speed which will occur 
 during the time it is making the necessary traverse. It should be explained, before passing on to deal at greater 
 length with the practice of the subject, that the minus sign merely indicates that the bobbin wheel revolves in 
 a contrary direction to the wheel B and the shaft A. 
 
 (246) The application of this mechanism to the purposes of winding depends, therefore, upon the regulation 
 of the speed of L. It has been seen that the motion of the latter is derived from the bottom cone E 1 . Assuming 
 the plate wheel to run in the same direction as the wheel B, it follows that when the bobbin leads, the 
 
164 
 
 SLUBBING AND ROVING MACHINES. 
 
 wheel L must start at its slowest relative speed, and increase as the bobbin fills. It is for many reasons 
 desirable that the speed of the plate wheel should be as low as possible, which is the course generally 
 adopted. If the flyer leads, the opposite plan is pursued. When, as is the case in the machine made by Mr. 
 John Mason, the plate wheel revolves in the reverse direction to that of the wheel B, it commences at its 
 quickest and finishes at its lowest relative speed, with a bobbin lead. Under these circumstances the full 
 value of the special arrangement, illustrated in Fig. 137, is seen. The highest velocity of the cone is obtained 
 when the bobbins are empty and have in consequence the lightest weight. Where spindles are revolving at 
 800 to 1,000 revolutions per minute, this is undoubtedly a great consideration, because the strain upon the 
 strap is lessened by reason of the decreased velocity at a time when the strap is on the smallest diameter 
 of the driving cone. It is sometimes the practice to run L and D on the bare jack shaft in the contrary 
 direction, this creating a good deal of friction and necessitating extra driving power. For this reason the 
 introduction of a tubular bush, such as is shown in Fig. 137, is attended with considerable advantage. The 
 friction existing when the wheels run upon the bare shaft, but in the contrary direction, is very great, as 
 will be understood when the speed of the wheels — about 400 revolutions per minute— is remembered. Any 
 rotation of one or more of the wheels in the opposite direction to the shaft is therefore equal to an increase 
 of the friction on the latter by the rate of the movement of the former. 
 
 (247) To overcome this defect, therefore, the motion has been re-arranged in one or two cases, so that 
 all the parts revolve in the same direction. Messrs. Curtis, Sons, and Co. employ Curtis and Khodes' motion, 
 which is illustrated in section in Fig. 138. The bobbin wheel A is cast in one piece with, or fixed to, an 
 
 3 J#N ' 
 
 Fig. 138. 
 
 internal wheel C, which is loose upon the shaft B. The disc D is fastened on the shaft, revolving with it, 
 and carrying a pin or spindle, on each end of which are fastened the pinions E and F. E gears with the 
 internal wheel, and F with a compound pinion G> which in turn engages with the pinion H. The latter is 
 
SLUBBING AND KOVING MACHINES. 
 
 165 
 
 cast on the collar L, which is driven from the lower cone and is loose upon the shaft B, revolving in the 
 same direction. If the collar L is fastened to the shaft, the whole of the wheels become locked together, 
 and the bobbin wheel A and the driving pinion H will revolve together at the same speed and in the same 
 way. This arises from the fact that the disc D is fixed on the shaft, and as it carries the train of wheels 
 the fastening of L keeps the teeth of E and F locked, so causing the rotation of the latter and its attached 
 wheel A. The carrier wheels would be standing under these conditions, while the Holdsworth motion in the 
 same circumstances would have the whole of the wheels in rapid motion. Thus, if in actual work, when the 
 collar L is loose, it is revolved at the same speed as the disc D or at one nearly approaching it, there would be 
 no motion in the carrier wheels, or very little, and the speed of A would equal that of H. As the velocity 
 of the latter is reducing, more motion is given to the wheels, which thus retard the wheel A while allowing 
 it to rotate in the same direction as the shaft. In this way the wear and tear of the parts, and the power 
 required to drive them, are alike materially reduced. 
 
 (248) Messrs. Howard and Bullough use Tweedale's motion, which is illustrated in Fig. 139. The shaft A 
 has a boss fastened on it, which is constructed with a second boss G at right angles to, but on one side of it. 
 The latter is bored to receive a short shaft, on each end of which the two wheels F H are fixed. The wheel B 
 is driven from the lower cone, and is compounded with the bevel wheel E, both being free to revolve on the shaft. 
 The bobbin wheel C is cast in one piece with the wheel D, and also runs loosely upon the shaft. It will be 
 noticed that only the wheels F and H are positively rotated on the shaft A, being carried round with the boss. The 
 
 Fig. 139. 
 
 motion is communicated from E to D as follows : E drives the wheel F, thus rotating the short cross shaft and 
 the pinion H. The latter gears with and drives the wheel D, the pinion F acting merely as a carrier. The 
 action of this mechanism can be readily understood from the preceding explanation, and it need only be pointed 
 out that the regulation comes from the wheel B. There is introduced into this mechanism the element of a 
 double set of driving and driven wheels. Thus G drives the wheel F, and H D, so that there is a difference 
 between this and the Holdsworth motion, in which the intermediate pinions act as carriers only. In order, 
 
 M 
 
166 
 
 SLUB13ING AND KOVING MACHINES. 
 
 therefore, to get the speed communicated to the wheel D, it is necessary to multiply the number of teeth in the 
 driving wheels and divide by those of the driven, by which means the proportions of the two are arrived at. By 
 the use of the following formula the speed of D can easily be arrived at. Let m = revolutions of the shaft, 
 fi — revolutions of the pinion B, which is variable, a = the constant arrived at as above, and v = the speed of 
 bobbin wheel D, then v = m-a(m + n). Having obtained the speed v it is of course easy to calculate the 
 necessary wheels to give the speed of the bobbins. 
 
 (249) The operation of the differential motion is controlled, as has been seen, by the lower cone, the speed 
 of which is carefully regulated by altering the position of the driving strap laterally. It has been pointed out 
 that the cones are correspondingly but conversely curved, the reason for this being that the actual increase which 
 takes place in the diameter of the bobbin is not in the same proportion to the actual diameter at the end as at 
 the beginning of winding. There is a slight decrease occurring as the bobbin fills, and in the early stages of 
 spinning it was the practice to use a rack with uneven teeth cut to a parabola, which was a costly process, and 
 is entirely avoided by the use of cones of that shape. Further, it is found that the bite of the strap is better 
 during a change of position. It will be readily understood that the position of the strap on the two cones 
 determines the speed of the plate wheel L. It is therefore essential to provide means by which the traverse of 
 the strap can be effected, and, as the addition of one layer of roving implies the necessity for a change in the 
 bobbin speed, the movement of the strap is given at the termination of each lift, at the moment of the change 
 of traverse. It follows, therefore, that the mechanism by which the strap is moved, and that by which the 
 reversal of the lift is effected, must be connected. Before proceeding to describe how this is done it may be 
 stated that the strap passes between two guides fastened to the toothed rack or slide P (Fig. 134), sustained by 
 bearings fixed to the frame of the machine. The operation of traversing the rack is performed by an interesting 
 piece of mechanism which has several functions. 
 
 (250) The "building motion," or "box of tricks" as it is sometimes called, is placed in the position 
 shown in Fig. 133 by the letter Q. In order that its details may be better understood, a front and 
 back elevation and plan of it is given in Figs. 140, 141, and 142, to which special reference will be made. 
 The objects of the building motion are three-fold: 1st, to give the requisite traverse to the cone strap; 
 2nd, to give the reciprocal traverse to the bobbin ; and 3rd, to shorten that traverse or lift at the 
 termination of the winding of each layer. It has been already explained why the two first objects 
 have to be attained, and it will be profitable to explain the reason for the third. Suppose that in 
 commencing winding the tube is 1^ inches diameter, the lift say 10 inches, and the diameter of the 
 roving i inch, there would be wrapped upon that surface during one lift 80 coils or 314 inches of roving. Now, 
 assuming that four kyers have been wound, the diameter of the bobbin would be 2\ inches, which, if 
 the lift remained constant, would cause 563 inches to be wound on the surface. But as the rate of 
 delivery by the rollers is definite during the time occupied by the lift, it follows that such a length 
 of roving could not be wound. It, therefore, becomes necessary to reduce the lift after each layer of 
 yarn is wound, so as to compensate for the increased area of the cylindrical surface, and provide that 
 the whole of the length delivered by the rollers is taken up, but no more. 
 
SLUBBING AND ROVING MACHINES. 
 
 167 
 
 (251) Referring now to Figs. 140 and 141 it will be noticed that there are two cradles A and B, 
 centred respectively on the pins A 1 and B 1 . Fixed in the upper cradle A are hooks, one at each 
 side, which are connected, as shown, with double hooks C D, passing through ears on the lower 
 cradle B, having weights attached to their lower ends. The lower cradle B has fixed in it a pin E 1 , 
 engaging with a slot in the lever E. E is centred on the pin^F, and is | coupled at its lower end to 
 the rod R, which is connected with the double bevel wheel T T, this connection being shown in Fig. 
 134. Two catches G G 1 , centred at their lower ends to the frame carrying the cradles, are coupled by 
 
 ^ -J 
 
 — « 
 K 
 
 
 111 
 
 lllllilllll 
 
 11! 
 
 E 
 
 
 
 
 Fig. 140. 
 
 the helical spring H. It will be noticed tbat the pawls of the catch levers are differently shaped, so as 
 to engage with the teeth of the rack or ratchet wheel I on the upper and lower side of the centre respectively. 
 The rack wheel is fixed on the same centre as the cradle A, as is also a bevel pinion J, gearing with a 
 similar one J 1 fixed on the upright shaft K, Fig. 141. At a higher point on K a spur pinion P 1 is fastened, 
 which gears with the teeth on the rack P, controlling the strap guides. Two levers |_ L 1 are pivoted 
 to the frame as shown, and are coupled at their inner ends by a helical spring M, which is carried 
 round the centre B 1 . The inner ends of L L 1 engage with shoulders or corners N IN 1 , formed in the 
 
168 
 
 SLUBBING AND ROVING MACHINES. 
 
 lower cradle B. Fixed to the bobbin rail is the double slide Q, which has a pin O sliding in it, on 
 which the end of the connecting rod S is centred. This rod passes through bearings placed in the cradle 
 A (see Fig. 140), and is formed with a toothed rack at its lower side with which a wheel T fixed on the 
 pin A 1 gears. These are the whole of the parts of this particular mechanism, but a reference to Fig. 134 
 will show that the rack P has a weight attached to it by a chain, which is always tending to draw it 
 inwards, and move the strap. In addition to this it causes a torsional strain to bo exercised on the shaft 
 K, aud consequently on the rack wheel, which causes the latter, when released by the catches, to rotate. 
 
 (252) The action of this mechanism is as follows : The slide Q in its reciprocal vertical movement causes by 
 means of tbe "diminishing rod" or "hanger bar" S, the upper cradle A to oscillate in its centre. When the 
 bobbins are midway in their lift, the centre of the slide Q should be in a line drawn horizontally through the 
 centre of the pin A 1 , and the rod S should be capable of being moved horizontally without producing any 
 oscillating movement in the cradle A. When this is the case, the two levers L L 1 engage respectively with the 
 shoulders N N 1 . Assuming that the bobbins are descending, the cradle A is turned from left to right when 
 looked at from the back of the frame as in Fig. 141. In this way the hook D is raised with its pendant weight, 
 while C is simultaneously lowered. As the shoulder on the upper part of the hook C prevents it passing through 
 the hole in the ear on the cradle B, it follows that a pressure is exercised on the latter, which causes it to turn in 
 the same direction as A. The weight attached to D is finally completely taken off the cradle B, and the 
 continuance of the movement causes the point of contact of L and N to become the fulcrum by which the rotary 
 movement of A is arrested for the time. This movement closely resembles the action of an anchor, the cradle B 
 being practically fixed as a ship is by its anchor. In some modifications of the mechanism this resemblance is 
 more pronounced than in the one immediately under notice. Thus the point through which D passes continues 
 to be free, while the whole weight is thrown upon the hook C, which thus exercises a proportionate strain on B. 
 The continued oscillation of A in the direction indicated causes the screw X, fixed in the left hand arm of A, 
 as shown in Fig. 140, to come into contact with the outer end of the lever |_. The increasing pressure so applied 
 causes L to turn upon its centre, destroying the contact of its inner end with the shoulder N, and 
 allowing the cradle B to make a sudden movement, which is partially rotary, but is also vertical in character. 
 The movement being reversed, the parts assume the position shown in Fig. 140, shortly after the reversal. The 
 screws fixed in the arms of the cradle A can be readily adjusted and locked so as to make the release of the lower 
 cradle B simultaneous with the termination of the bobbin traverse. 
 
 (253) In consequence of the sudden release so effected, the lever L 1 assumes the position shown in Fig. 140, 
 and at the same time the pin E 1 strikes one side of the hole in the lever E (see Fig. 141), and causes the latter to 
 turn rapidly on the pin F. This is followed by three things. The head of the lever E strikes the catch G 1 and 
 throws it out of gear with the ratchet wheel. The latter at once makes a rotary movement to the extent of half 
 a tooth, but is then arrested and retained by the catch G. As the catch levers G G 1 are coupled by the spring 
 H it will be easily understood how the movement of one of them to the right or left is accompanied by a 
 corresponding movement of the other. By this release of the ratchet wheel and its partial revolution, the upright 
 
SLUBBING AND ROVING MACHINE?. 
 
 171 
 
 shaft K also moves and causes the rack P to travel inwards and so move the strap on the cones. This is the 
 first effect of the movement of the lever E. 
 
 (254) As shown in Fig. 134, and also in Fig. 141, the lower end of the lever E is attached to the rod R, which 
 is connected at its other extremity by a forked lever to the double bevel or " striking" wheel T T 1 . The latter 
 engage alternately with the small bevel pinion fixed on the lower end of the upright or " change " shaft M and 
 slide upon a short shaft U, which they drive by means of a feather key. On U is also fixed a spur pinion V 
 which drives, by the intervention of suitable gearing, a shaft running longitudinally and placed just behind the 
 spindles. This shaft has a number of spur pinions fixed on it, which engage with vertical racks or " pokers " 
 fastened to the bobbin frame. In this way the rotation of the pinion V in either direction is followed by the 
 traverse of the bobbins either upwards or downwards. When, therefore, the rod R is traversed by the oscillation 
 of the lever E and the bevel wheels T T 1 are respectively thrown into gear with the pinion on M, the bobbin 
 traverse in a corresponding direction is obtained. 
 
 (255) A further effect which arises from the rotation of the ratchet wheel is found in the fact that the wheel 
 T (Fig. 140) also moves, and as it engages with the rack on the underside of the rod S draws the latter inward 
 As will be readily understood, the position of the pin O plays an important part in the oscillation of the cradle A. 
 If, for instance, the pin were at the extreme point of Q furthest from A, the motion of the latter would be made 
 much more slowly than if O were at the other end of the slide, when, owing to the shorter radius, A would make 
 its oscillatory movement more quickly, and, if Q made the same vertical traverse, A would move through a greater 
 arc. Thus, if O is drawn inwards, it is followed by a more rapid movement of the cradle A, and, as a consequence, 
 the change of the position of the lever E occurs at an earlier moment. This causes the reversal of the traverse of 
 the bobbin rail to take place sooner, and, in this way, each succeeding layer of roving occupies a shorter portion of 
 the bobbin surface longitudinally than its predecessor. Thus the bobbin is built accurately in the double conical 
 shape required, and the shortening of the lift, the necessity for which has been previously demonstrated, is properly 
 effected. 
 
 (256) A reference to Fig. 134 will show that the weight attached to the rack P is fastened to the latter by a 
 chain, which passes over a pulley at the lower end of the lever W, which is sustained in position by a catch placed 
 at X. When the rack P has made its extreme inward traverse the catch is released, and the lever W is caused to 
 strike the collar on the rod Y, so as to cause the latter to move longitudinally. As the rod is connected with the 
 driving strap fork, the strap is thrown over on to the loose pulley, and the frame is stopped. Attached to the 
 bobbin frame are chains, to the other end of which balance weights are fastened so as to relieve the work of the 
 lifting pinions. These chains are passed over pulleys fixed to the framing as shown in Fig. 134. 
 
 (257) Recurring now to the action of the building and winding motions, it is necessary to note that 
 the number of the releases of the ratchet wheel I correspond to those of the reversals of the bobbin rail, 
 and consequently to the number of the layers of roving. It therefore becomes necessary to alter the wheel I 
 whenever a change in the roving which is being produced is made. As the ratchet wheel is the governing 
 factor in the regulation alike of the speed of the strap traverse and of that of the inward movement of the 
 
172 
 
 SLUBBTNG AND ROVING MACHINES. 
 
 rod S, the reason for changing it is easily seen. Thus the increase in the diameter of a bobbin on which 
 a roving J^th inch diameter is being spun would be less than that which occurs when a roving ^\nd inch 
 diameter is made. It follows, therefore, that the rate at which the strap is moved along the cones would 
 in the first case be only two-thirds of that at which it moves in the last case. Again, the lessened increase 
 in diameter involves, as was shown, the winding on of a shorter length of roving during the "lift" of the 
 bobbin, and consequently the latter does not require to be diminished in the same ratio. Therefore, it is 
 desirable to substitute for the ratchet wheel one with more teeth, the number of which must be in direct 
 ratio to the number of coils it is intended to wind on the full bobbin. 
 
 (258) Let it be assumed that the pitch of the teeth of the rack P and of that in S is one-quarter inch ; 
 that the ratchet wheel I has 30 teeth, the pinion engaging with P 31 teeth, and the pinion T 19 teeth. 
 As was shown, the wheel I moves to the extent of half the pitch of the tooth every time the traverse of 
 the bobbin rail takes place. In this case 60 such reversions would take place during the time that the 
 ratchet wheel made a complete revolution. During that time the wheel engaging with P would also have 
 made a complete revolution, and P would have moved in 7f inches, giving a corresponding traverse to the 
 strap. In the same time the pinion T would have made a revolution, and the "diminishing rod" S would 
 move in 4§ inches. Assuming — a purely hypothetical assumption — that the distance from the centre A 1 of 
 the cradle A to the outermost point of the slide Q to which the pin O can be pushed is 15 inches, and that 
 the lift of the bobbin be 7 inches, it will follow that the above reduction of the distance of O from A 1 will cause 
 a more rapid oscillation of the cradle A. A simple calculation will show that this would cause the change 
 of the direction of the lift to take place when 4f inches was covered. This example will serve to illustrate 
 the principle involved, but does not necessarily represent any actually existing case. It is only intended to 
 show that the reduction of the lift takes place in exact accordance with the period occupied by the ratchet 
 wheel I in its rotation. During the time the traverse has been shortened the speed of the bobbin, owing to 
 the traverse of the strap along the cones, has also been diminished in the exact proportion required to 
 compensate for the increased diameter. 
 
 (259) Now, if it be assumed that a coarser roving requires producing, and that the ratchet wheel | 
 is changed for one containing only 20 teeth, it will be seen that while the same necessity exists for the full 
 traverse of the strap guide and diminishing rod, a smaller number of layers of roving will be wound in 
 the same time. In this case 40 layers only will be laid, although the strap makes the same movement. 
 That is, the same reduction of the speed of the bobbin is made while 40 layers are wound that was 
 previously made while 60 were wound. Now, as the diminution of the speed of the bobbin must be 
 exactly proportionate to the increase of its diameter, it follows that the roving in the former case must 
 be correspondingly thicker. It should also be observed that the inward traverse of the diminishing rod 
 S is quickened as well as that of the racks P, because the time occupied by the ratchet wheel in 
 making a complete revolution is, of course, less than when one with 30 teeth is employed. Thus the 
 speed of the bobbin and the length of its traverse are both decreased at a more rapid rate when a 
 ratchet wheel is employed, which is exactly what is wanted when coarser roving is being produced. 
 
SLUBBING AND BOVING MACHINES. 
 
 173 
 
 (260) A locking motion is fitted to the machine by which, when the rack P is released in the manner 
 described, the stop rod is locked in such a way that until the rack has been wound back by hand into 
 proper position the frame cannot be started. There are two advantages in this motion, viz., that the size 
 of the bobbins is accurately regulated, and damage to the frame is prevented. 
 
 (261) In order to avoid the uneven wear of the top rollers, caused by the slubbing or roving passing 
 through them at one point constantly, it has become the practice to give a slight lateral traverse to 
 the guide bar. One of the latest developments of this special treatment is illustrated in Figs. 143 to 
 147, this being the invention" of Mr. George Paley, a spinner, of Preston. It consists of a worm I fixed 
 
 Section i hrouch The 
 Eccentrics. 
 
 Figs. 143, 144, 145, and 146. 
 
 upon the end of the roller spindle, which gears into two wheels G H, carried on a pin fixed in a 
 bracket. The number of teeth in the wheels are different, H having one more tooth than G. In this 
 way G is revolved once for every 24 revolutions of the worm, while H requires 25 revolutions of the 
 latter before making a complete rotation. The wheel H has a boss J, the upper part of which K is 
 formed eccentrically, and on this portion the eccentric L is placed. To the clip of L the traverse rod P 
 is coupled. L is driven from the wheel G by means of a pin fastened in |_, and engaging with a 
 slot in G. Thus the rotation of the eccentric L is followed by the traverse of the guide bar. 
 
174 
 
 SLUBBING AND ROVING MACHINES. 
 
 (262) It will be noticed that the outer eccentric L is not only out of centre with the pin S, but 
 also with the inner eccentric K. Thus the rotation of the latter perpetually establishes a new condition of 
 eccentricity. At one point the throw of the combined eccentrics is smaller than at another, and there 
 are fixed limits within which many positions are assumed. If the throw of K is § inch, and of L f inch, 
 it is obvious that if they are both at the front centre their combined throw will be 1 inch. But if K is 
 at its back centre and L at its front one the combined throw is only £ inch. Now owing to the fact that 
 the wheels G and H are made with one tooth more or less, it happens that 25 complete revolutions of the 
 eccentrics are needed before they are brought with their centres coinciding after that position had been 
 abandoned. The result is, that during every one of the 25 traverses a different throw occurs, and the 
 length of the traverse is varied, as shown diagramatically in Fig. 147. By altering the size of the wheels 
 G H any number of variations desired can be obtained. 
 
 Fig. 147. 
 
 (263) Messrs. Howard and Bullough fit to their intermediate frame an electric stop motion. It should be 
 explained that it is customary to pass two slubbings through the rollers at once, twisting them together to form 
 one thread. If from any cause one of these ends breaks, the other may go on twisting, and a thin defective 
 place would result. To obviate this, the arrangement named is applied. The slubbing bobbins are placed 
 in a creel, and are passed between the surface of a metallic spring, and a roller placed at the back part of 
 the machine. The drawing rollers are fixed in their usual position, and the spring is held by a bracket 
 attached to one pole of an electro magnet and battery, the back roller being connected to the other pole. 
 When the thread of slubbing breaks, contact between the spring and the roller occurs, and the circuit is 
 closed. Thereupon a current is passed through the magnet, and one end of a lever is attracted so as to 
 bring its other end in the path of a constantly rotating ratchet wheel. This arrests the motion of the 
 latter, and so releases a catch on the stop rod, allowing it to be drawn along by the action of a helical 
 spring. In this way the machine is rapidly stopped. 
 
SLUBBING AND ROVING MACHINES. 
 
 PRODUCTION OF SLUBBING AND ROVING FRAMES IN LBS. PER WORKING 
 
 WEEK OF 56 HOURS. 
 
 Hank Roving. 
 
 Speed of Spindles. 
 Revolutions 
 Per Minute. 
 
 Twist per Inch. 
 
 Production. 
 
 Maker's Name. 
 
 •50 
 
 600 
 
 •85 
 
 114 
 
 John Mason. 
 
 •50 
 
 600 
 
 •85 
 
 116 
 
 Crighton and Sons. 
 
 •50 
 
 700 
 
 •84 
 
 115 
 
 Howard and Bullough. 
 
 100 
 
 700 
 
 120 
 
 56 
 
 Join Mason. 
 
 1-00 
 
 700 
 
 1-20 
 
 56 
 
 Crighton and Sons. 
 
 100 
 
 700 
 
 1-20 
 
 59 
 
 Howard and Bullough. 
 
 3-00 
 
 1000 
 
 2-08 
 
 17 
 
 John Mason. 
 
 3-00 
 
 1000 
 
 2-08 
 
 16 
 
 Crighton and Sons. 
 
 3-00 
 
 1100 
 
 2-07 
 
 16-53 
 
 Howard and Bullough. 
 
 6-00 
 
 1400 
 
 294 
 
 7-25 
 
 John Mason. 
 
 6-00 
 
 1300 
 
 2-94 
 
 7-20 
 
 Crighton and Sons. 
 
 600 
 
 1100 
 
 2-92 
 
 6 25 
 
 Howard and Bullough. 
 
 Note. — The velocity of the spindles and amount of twist introduced will largely influence the productions 
 as given above, which are only illustrative of the capacity of these machines. 
 
CHAPTER XI. 
 
 THE MULE. 
 
 (264) The last process in the production of yarn is that in which the rovings, obtained in the manner 
 described, are elongated and twisted into a thread. To many persons this is known as " spinning," although 
 strictly speaking, that phrase is applicable to the whole range of treatment by which cotton is converted into yarn. 
 Using the term, however, in its narrower sense, spinning may be either an intermittent or continuous operation, 
 that is, the rovings can be twisted for a portion of the time only during which the machine is working, or for the 
 
 — whole of that period. Although the latter system is the most ancient, for the last century the former has been 
 more generally pursued. It is, therefore, advisable to describe first the machine by which it is carried out. 
 
 (265) This is known as the "mule," and owing to the practical automaticity of its mechanism, as the "self- 
 acting " mule or " self actor." It is without exception the most interesting of the whole series of machines used 
 in cotton manufacture, combining an intricate sequence of mechanical movements with great ingenuity. As a 
 further consideration will show, one piece or part of the mechanism used performs work widely diverse in its 
 character at different periods, and it is this fact which renders the mule so difficult a machine to understand. The 
 time occupied in completing the cycle of operations which constitute mule spinning is so small that the action of 
 the various parts must be very rapid and certain. In order to understand the description which follows, it will be 
 advisable to define the stages or periods which succeed each other and form the entire process. 
 
 (266) In order to facilitate the grasp of the subject by the reader, it will be better to describe first and briefly 
 the essential or primary parts of the machine. These are shown in Fig. 148, which is a purely diagrammatic 
 representation. The roving bobbins A are fitted on a skewer and placed in the frame or creel 
 arranged at the back of the machine, being held in an almost vertical position. The roving R is 
 guided as shown to the nip of triple lines of drawing rollers B B B. From the rollers the roving 
 passes to the tip or point of a steel spindle H, sustained by an upper bearing or bolster O, and a foot- 
 step N. These are fixed in wooden rails which form part of a box or frame I, known as the "carriage." The 
 carriage is fitted at convenient distances along its length, with cross brackets, in each end of which bearings are 
 formed for the axes of the pulleys or runners P. These rest upon the edges of oblong iron bars or "slips" Q, 
 which are securely fastened to the floor of the room. The spindle receives a rapid rotary motion, being driven by 
 a band M, carried tightly round a small V grooved pulley or " warve" fixed on the spindle, and a light roller K 
 extending longitudinally of the carriage, and fastened on a shaft T. The roller — or more correctly the " tin 
 roller" — K is suitably driven, and, it will be easily understood that the direction and velocity of H will depend 
 upon those of K. In its passage to the spindle the roving is taken under a small guide wire D- -known as the 
 
THE MULE. 
 
 177 
 
 " faller wire " or shortly the winding " failer " — fastened on the outer end of a curved arm or " sickle " secured on 
 the shaft F— known as the " faller shaft." The roving also passes over a second wire C— called the " counter 
 foUer " — which is fixed in a similarly shaped arm fastened on the " counter faller shaft " E. By the oscillation of 
 the shafts E F, the winding faller and counter faller are elevated or depressed, thus enabling the finished yarn to 
 be wound into the spool or "cop " G, which is made of the shape shown. The above form the essential portions 
 of a mule and their respective functions can now be explained. 
 
 (267) The rollers B perform the same office as those used in the drawing and roving machines, namely, 
 the attenuation and delivery of the roving. Each of the three lines revolve at different velocities, that of the 
 front line being the superior one, with the result that roving which, as was shown, has been already considerably 
 reduced in diameter is still further attenuated prior to being twisted. 
 
 (268) The roving is wrapped round the spindle two or three times in commencing operations, being 
 sometimes rendered adhesive by paste, and sometimes wrapped on a paper tube placed on the spindle. Being 
 thus held at one end by the spindle, and at the other by the nip of the front rollers, the rotation of the former 
 will necessarily further twist the partially twisted roving. On the degree of twist— that is the number of turns 
 per inch— depends the amount of roving delivered by the rollers in a given time, as explained in paragraph 234. 
 
 (269) In the roving machines the relative positions of the spindle and front rollers are fixed, but in the 
 mule an important variation in this practice occurs. The carriage I receives by suitably arranged mechanism 
 an alternate movement from and towards the roller B. During the period they are delivering roving it 
 is drawn away from them until it has travelled about 63 inches, when its motion ceases. While this traverse 
 is taking place the spindles are revolving, and twist is therefore being introduced into the roving. The cessation 
 of the motion of the carriage is accompanied by a similar stoppage of the rollers and spindles, and there 
 is then a number of lengths of yarn— each 63 inches— held in tension by them. This traverse of the carriage is 
 called its "stretch" or "draw." 
 
 (270) The yarn, as thus spun, requires winding upon the spindle, so as to form the cop, but before doing 
 this it is necessary to free two or three turns which are wrapped on the spindle between its point and 
 the point or " nose " of the cop. This operation is called " backing off." In order to effect it the roller K 
 has its motion reversed for a short time, so as to give the necessary backward rotation to the spindles. The 
 slack yarn thus produced is taken up, first, by the ascent of the counter faller, and, second, by the descent 
 of the winding faller. The former rises sufficiently to preserve the tension of the yarn as it is freed, and 
 the latter is drawn down so as to assume a proper position to commence winding when the operation of 
 backing off is completed. 
 
 (271) As soon as this stage is finished the inward traverse of the carriage I commences, an operation 
 which is accompanied by the forward revolution of the spindles, which thus wrap or " wind " on to the 
 cop the 63 inches of twisted yarn. The rollers during winding are, of course, stationary. By the time 
 the carriage has again reached its innermost point the full length of yarn is wound, and during that period 
 the faller has risen from the base of the upper cone of the cop to its nose. This ascent is a gradual one, and 
 
178 
 
 THE MULE. 
 
 causes the yarn to bo wound in finely pitched spiral coils upon the cop. With the termination of the inward 
 traverse or " run " of the carriage winding ceases, the winding faller and counter faller wires are released, 
 and the whole of the operations begin anew. 
 
 (272) It is now possible to define the various stages in the whole process of mule spinning. These 
 are as follows : — 
 
 First. The period during which roving is being delivered and twisted. During it, the rollers 
 are revolving at a defiued speed ; the carriage is being drawn outwards at a constant rate ; the spindles 
 are revolving rapidly at a velocity definitely relative to that of the front roller. During this period the 
 faller and counter faller are held in the position shown in Fig. 148, being quite clear of the yarn. 
 
 Fig. 148. 
 
 Second. The period during which the movements just named are stopped. The roller driving gear is 
 detached ; the mechanism by which the carriage is drawn out is stopped ; the spindles are stopped because of the 
 transfer of the driving strap to the loose pulley and the consequent cessation of the motion of the driving band ; 
 and preparation for the engagement of the faller and counter-faller with the yarn takes place. 
 
 Third. This is the period of " backing-off." During it the driving band is driven in the contrary 
 direction to its normal one, and the spindles are reversed. The faller wire is drawn down, depressing the yarn ; 
 the yarn between the nose of the cop and spindle point is uncoiled ; the counter faller rises and takes up the 
 lack yarn ; and the faller is "locked." 
 
THE MULE. 
 
 179 
 
 Fourth. Daring this period " winding" takes place. The rollers are stationary; the carriage is " running 
 in " at a variable speed ; the spindles are revolving in the same direction as when twisting ; and the winding 
 faller is operated so as to guide the yarn on the cop. 
 
 Fifth. The carriage comes to rest j the faller and counter faller are released ; the roller driving gear 
 is re-engaged ; the strap is moved on to the fast pulley and the driving band put in motion ; and the drawing out 
 gear is again engaged. 
 
 With this the cycle of movements is completed, and the whole of the operations begin anew. 
 
 (273) There are thus five periods, viz., 1st, twisting j 2nd, arrestation ; 3rd, backing-off ; 4th, winding; and 
 5th, re-engagement. In addition to these, wheu fine yarns are spun, there is sometimes a sixth period, which 
 takes place immediately after the termination of the first as at present defined. This is a period of supplementary 
 twisting after the rollers have stopped. This operation is sometimes known as " twisting at the head," and will 
 be dealt with at a later stage. 
 
 (274) It is thus indicated that at various times one part of the mechanism performs different functions. 
 The rollers revolve for the whole or part of the first period and remain stationary afterwards. The spindles 
 revolve at a constant and maximum velocity in their normal direction during the first period, at a slower 
 but constant velocity in the reverse direction during the third period, and at a variable speed in their 
 normal direction during the fourth stage. The carriage makes its outward run at a regular speed during the 
 first period, is at rest during the second and third, and makes its inward traverse at a variable speed 
 during the fourth. The winding faller remains stationary and free from contact with the yarn until the 
 third period, when it makes a rapid descent to the winding point, after which it first descends quickly to 
 its lowest point, and then ascends slowly to the nose of the cop during the fourth. The counter faller 
 remains below and out of contact with the thread during the first and second periods, and ascends during 
 the third, remaining in contact with and sustaining the yarn until the termination of the fourth. 
 
 (275) This preliminary explanation will enable the detailed description following to be more easily 
 understood and appreciated. As there are many variations in the construction of the mule it is desirable 
 to select one of the most widely used, and for this reason the machine constructed by Messrs. Piatt 
 Brothers and Co. has been chosen for description. Front and back perspective views of the machine 
 are given in Figs. 149 and 150. The Parr-Curtis mule is also largely employed, and many modifications 
 of it exist. All the root principles which are contained in the machine are, however, found 
 in the Piatt machine. That is to say, it contains mechanism founded upon certain rules which 
 are essential to all mules, so that, although the details may be, and are, varied, the main features are 
 identical. A detailed description of its mechanism, therefore, will enable the subject to be fully understood, 
 but, at the close of the chapter, particulars will be given of special features in other makers' machines. 
 To enable the construction of the machine to be more fully grasped, a series of diagrammatic views 
 are given of each motion separately, and the reference letters are arranged so that each part is marked 
 with the same letter in all the views in which it occurs, although the same letter, in some cases, refers 
 to various parts in different diagrams. 
 
180 
 
 THE MULE. 
 
 (276) It may be first explained that the greater number of the parts by means of which the required 
 motion is given to the various portions of the mechanism are contained in a longitudinal framing placed in 
 the centre of the machine, this part of the mule being called the "headstock." At right angles to the 
 headstock, and at each side of it, the rollers and carriages extend for the entire length of the machine. 
 The arrangement of a "pair" of mules is clearly shown in Fig. 151, the machines being usually 
 placed with their headstocks zig-zag to one another. The carriage of one mule is coming out while that 
 of the one opposite to it is at the roller beam, tlrs arraugement permitting the free movement of the 
 workman attending to the machines, and preventing the broken threads in each machine requiring 
 piecing at the same time. It might, perhaps, be explained that " piecing " is always effected when the carriage 
 is making the first part of the outward run, so that some inconvenience would arise if both carriages 
 were in that position at the same time. A special motion is sometimes fitted by which each carriage is released 
 alternately by the movement of the carriage opposite to it. Referring now to Fig. 151, H represents the 
 
 1 
 
 
 
 
 
 T 
 
 
 
 
 6 
 
 
 H 
 
 
 H 
 
 I 
 
 
 
 
 
 in L 
 231 
 
 
 r- , 
 
 
 
 Fig. 151. 
 
 headstocks of the two mules, E the lines of rollers, F the end frames, and O the carriages. It will be noticed 
 that the headstock divides the machine into two portions of unequal length, each of which contains its own 
 rollers and spindles. The special object of this is to enable the mules to be placed in closer proximity 
 than could be done if both sides were of the same length, and the headstocks were placed quite 
 opposite to each other. 
 
 (277) The rollers are in three lines, and are borne in brackets or stands fastened to longitudinal iron 
 " roller beams," sustained at intervals by light frames or " spring pieces." The lower lines of rollers are 
 finely fluted, and are made of the same superior quality of iron as those used in the roving frames. Their 
 diameter is usually an inch, but this varies with the staple to be spun. The front line of top rollers are 
 generally of Leigh's loose boss type, cloth and leather covered, and are weighted by a saddle, stirrup, and lever 
 weight. The middle and back lines are "common rollers," also covered in the same manner. The front 
 lines of the right and left-hand set in each mule are coupled by a short shaft, and the second and third 
 are driven from the first. 
 
THE MULE. 
 
 181 
 
 Fxo. 149. 
 
 Fio. 150. 
 
 N 
 
THE MULE. 
 
 183 
 
 (278) The carriage has a rectangular frame, being built with strong longitudinal timbers, securely tied 
 together by cros3 pieces. These carry, as was shown, the bolster and footstep rails. On the cross cast-iron 
 "rauntins" the bearings for the tinroller shafts are fastened. The carriages at each side of the headstock 
 are coupled by a strong iron frame, to which they are securely fastened. This is known as the "square," 
 and carries some of the mechanism for giving motion to the spindles and building the cop. 
 
 (279) The tin roller is generally six inches in diameter, and consists of a series of cylinders made from 
 sheets of tinned iron, securely soldered together. In each end of the rollers so formed an iron disc is fastened, 
 and the lengths are coupled by means of short shafts. The whole of the lengths are thus connected, and 
 a bearing is placed at each junction, so that the tin roller is well sustained throughout. The rollers in 
 each of the two carriages are coupled by a short shaft, extending across the square, and carried by means 
 of pedestals, fixed to the latter. On this short length of shaft the driven tin roller pulley is secured, as 
 will be hereafter fully described. 
 
 (280) The spindle is made of steel, and is from 13| to 18 inches long, according to the class of material 
 being dealt with. For coarse counts and for " twist" yarn a larger cop is made, and the spindle is of 
 necessity loDger. For 32's twist yarn a spindle about 17 inches long is used, and its diameter varies from 
 fths inch to less than |th inch. The part between the two bearings is called the "haft," and that above 
 the bolster— on which the cop is wound— the "blade." The spindle is thickest in the haft, terminating in 
 a small foot, but the blade is tapered throughout. Great care is taken with the spindles to ensure their 
 accuracy, and they can, therefore, be run at velocities as high as 11,000 revolutions per minute without 
 vibration. The extra diameter of the haft ensures the necessary resistance to flexure caused by the pull of 
 the driving band. The latter is a thin cotton cord— made of the best grades of cotton— passed tightly over 
 the spindle warve and the tin roller. It is highly important that the bands should not be either too tight 
 or too slack. In the one case the friction generated would be excessive and detrimental, and in the other 
 the twist would not be fully put into the roving, which would be said to be "slack twisted." Varying 
 atmospheric conditions materially alter the tension of the bands, and their proper piecing is only to be 
 mastered after long practice. The spindle is disposed in the carriage at a varying angle, to suit the material 
 being spun. 
 
 (281) The description of the general construction of the machine thus given clears the ground for the 
 detailed explanation which follows. For convenience it will be as well to begin by describing the mode of 
 obtaining the motion of the spindles. This is illustrated in Fig. 152, which is a diagrammatic representation 
 of the course of the bands and driving pulleys. The mule is driven from the line shaft, or a counter shaft 
 by means of a strap passing over the pulley A fastened upon the shaft C. The latter is termed the "rim 
 shaft," and upon it the loose pulley B is also placed. Free to revolve and slide upon the same shaft is the 
 spur wheel A 1 , formed with a large internal cone, the exact object of which will be hereafter described. The 
 fast pulley is about 5 inches wide, and the loose pulley 5| inches, the diameter being about 15 inches. Thus, 
 when the strap is on the fast pulley it is also partially on the loose pulley, which is always revolving. At 
 
184 
 
 THE MULE. 
 
 the other extremity of the rim shaft a double, treble, or quadruple grooved pulley C 1 is fixed, which is called 
 the " rim." Over this the endless cord or baud driving the spindles is passed— being known as the " rim 
 band"— its course being clearly shown by means of the arrows. It will be noticed that it is first passed 
 round a carrier pulley on the carriage square, and then round the tin roller pulley on the tin roller shaft 
 T, being then taken round the carrier pulley Y fixed at the end of the headstock frame, afterwards returning 
 to the rim pulley. It will, of course, be understood that the explanation just given relates to the course 
 of the rim band, considered as a single rope. When the rim is double or treble grooved, corresponding 
 arrangements must necessarily be made in the rim band course. The rollers E are driven from the rim shaft 
 by the train of wheels and the side shaft G shown, and the drawing out of the carriage is effected by the 
 band passing round the scrolls at H and round the pulley Z. This will be more particularly described 
 presently. 
 
 (282) Particular reference will now be made to Figs. 153 and 154, which are respectively longitudinal 
 sections of the driving gear and back view of the same. The loose pulley B has formed upon its boss a 
 spur pinion B 1 , from which, by means of a carrier wheel, the side shaft D is driven. On the other end of 
 this shaft a pinion D 1 is fixed, which gears with and constantly drives the spur wheel A 1 , this being the 
 object of the overlapping of the driving strap previously referred to. The wheel A 1 is formed, as shown, on 
 its inner side with a large internal conical surface, which, at the proper moment, engages with a corresponding 
 leather-covered surface formed on the pulley A. This engagement takes place for the purpose of backing-ofi, 
 and the cone A 1 is therefore known as the "backing-off cone" or "friction." The engagement of the friction 
 cone with the fast pulley causes it first to act as a brake, and the strap having been moved upon the loose 
 pulley it then exerts sufficient force to revolve the backing-off cone in the contrary direction. To enable this 
 contact to take place a ring groove is formed in the boss of the backing-off wheel, in which a claw engages, 
 which is oscillated as afterwards described. The effect of this arrangement is that the rotation from the loose 
 pulley B of the friction wheel A 1 , whilst it is engaged with the fast pulley A, causes the rim shaft to be 
 rotated in the opposite direction to that normal to it. The direction in which the various parts revolve 
 normally is clearly shown by the arrows. The extent of the backward movement of the rim shaft depends, 
 of course, entirely upDn the length of time during which the friction cone A 1 is allowed to engage with 
 that on the pulley A, this being regulated by the amount of yarn to be unwound. 
 
 (283) The rollers E are driven from a pinion G 1 fastened on the rim shaft, by means of which the 
 shaft G is revolved, and motion is thus given to a bevel wheel loose upon the short shaft coupling the two 
 front lines of rollers. One half of a toothed or claw clutch is formed on the boss of the wheel, the other 
 half of which is secured to but slides upon the coupling shaft, being formed with a ring groove on its boss 
 into which the two arms of a claw are fitted so as to engage and disengage the clutch. 
 
 (284) On the boss of the bevel wheel is a spur wheel which, by means of the train of wheels shown, 
 communicates the forward movement to the " back " shaft H on which are fixed the scrolls H *. On these 
 the ropes or bands shown are wound, being attached to the carriage as shown in Fig. 152. As 
 
THE MULE. 
 
 185 
 
 Fig. 153. 
 
 Fig. 154. 
 
THE MULE. 
 
 187 
 
 the carriage extends to the right and left of the headstock, as explained, the back shaft H is similarly- 
 extended, and has placed upon it a number of scrolls at suitable distances apart, on which other bands are 
 wound. This enables the carriage to be evenly drawn out throughout its entire length. The method of 
 attaching the bands to the end frames of the carriage is shown in Fig. 155, and it will be seen that there 
 is power of adjustment given, which enables the carriage to be "squared" or kept parallel with the roller 
 beam. The last of the train of wheels P 1 , by which the back shaft is driven, is loose upon it, and forms 
 one half of a clutch, the teeth of which are peculiarly shaped. The other half P slides upon the boss of a 
 disc which is keyed upon the shaft, and has a ring groove in its boss, being ordinarily pushed up to its 
 position by a spiral spring surrounding the back shaft and kept in compression by a stop hoop or collar 
 which can be set up as desired. This, combined with the peculiar construction of the teeth, enables the 
 clutch to open and its teeth to glide over one another in the event of any obstruction being offered to the 
 free outward run of the carriage. The forked end of an L lever fits in the groove in the clutch, being 
 oscillated as afterwards described. 
 
 Fig. 155. 
 
 (285) The bevel wheel on the outer end of the taking-in side shaft D gears with a similar one 
 fixed on the upper end of the vertical shaft I, on the lower end of which is loosely placed the friction cone 
 K. With the latter the hollow cone I 1 engages, this being able to slide in a vertical direction on a disc 
 keyed to the shaft. It is usually kept out of gear by means of a hinged forked lever, the fork of which 
 fits in the groove shown in I 1 , and which is sustained at its free end so that it can be readily 
 released to allow the sudden engagement of the friction cone. On the half cone K, at its underside, 
 is cast a small bevel pinion, which engages with a bevel wheel K 1 fixed on the shaft L, extending 
 transversely of the headstock at the back. Spirally grooved or "scroll" pulleys L 1 are fixed on the shaft 
 L, on which ropes are wound, these being attached to the carriage square as shown in Fig. 168, page 212. An 
 additional scroll is fitted on the shaft L, and is set at such an angle that when the rope is fully 
 drawn off the other scrolls it is wound on the additional one. When the friction cone is in gear the 
 ropes are wound on to the scrolls, and the carriage is drawn in. From the fact that these scrolls are 
 employed, and that their object is to draw in the carriage, the shaft L is called the "scroll" or 
 
188 
 
 THE MULE. 
 
 " taking-in " shaft, and the friction cone is commonly styled the " taking-in friction," or, more shortly, the 
 " friction." 
 
 (286) The means just described are those which are in use on a large number of mules constructed by 
 Messrs. Piatt, and worked satisfactorily until the speed of the rim shaft was largely increased. Up to about 
 750 revolutions the train of gearing driving the taking-in side shaft could be used, but as the rim is now 
 run at speeds as high as 900 revolutions it is the practice to drive the taking-in side shaft by means of a 
 grooved pulley fastened upon it, and driven by a separate band from the counter shaft. In this way much 
 of the strain is taken from the rim shaft, and the use of gearing obviated for the taking-in and backing-off. 
 When this method is adopted— as is now almost generally done — there are many advantages gained, and it 
 is the most modern practice. 
 
 (287) Another method of driving, also largely employed by Messrs. Piatt, is a patented system of duplex 
 driving. This is shown in plan in Fig. 157. Instead of using one belt only, by means of which the power 
 is transmitted, two narrower ones are employed, each of which is 2f inches wide. The fast pulleys A are also 
 2| inches on their face, while the loose pulleys B are 3 inches wide. The strap guide is made, as shown, 
 double, and the distance which it has to traverse is only half that which is usual. The advantages of this 
 arrangement are derived both from the smaller width of the belts, and the shorter distance they need moving. 
 The diminished width causes the belt to be more pliable and less rigid, and in consequence the pressure 
 applied is more readily responded to. The shortened traverse enables the change of the belts to be 
 made more easily and in less time, and, in consequence of the latter fact, the time the edges of the belts 
 are pressed upon by the guider is reduced. This reduction involves considerably less wear of the strap edges, 
 which, alike on this account and because of their easier and less strained motion, are found to have a much 
 longer life. The smooth action of the belts produces another effect. It enables the full speed of the rim 
 shaft to be more readily reached, and so tends to increase the production of the machine. The makers have 
 now constructed a large number of mules with this arrangement, and its use is steadily extending. 
 
 (288) The mechanism just described is that on which depends the driving of the whole of the parts, 
 and its mode of action can now be easily explained. Beginning with the commencement of the outward 
 run, when the rim band is traversing in its normal direction, the rollers commencing to deliver yam, 
 and the spindles revolving, the position of the parts is as follows. The strap is on the fast pulley, 
 and the rim shaft is revolving. The backing-off friction is out of gear, the necessary motion is given 
 to the roller shaft, and as the claw clutch is engaged the front line of rollers is revolved, roving being 
 delivered. At the same time the back shaft is driven, the clutch on it being in gear, and the carriage 
 is drawn out. The scrolls on the back shaft are shaped so as to allow the carriage to move at a 
 constant velocity. While the carriage is running out the rim band is giving the required revolution to 
 the tin roller shaft, and the spindles rotate in consequence at their normal velocity. The carrier pulley 
 on the square shown in Fig. 152 is arranged at such an angle that the rim band passes freely on to 
 and from the pulley on the tin roller shaft. A similarly accurate setting is given to the guide pulleys 
 
THE MULE. 
 
 189 
 
 at the back of the headstock, the wear of the bands being much reduced in consequence. The velocity 
 given to the carriage is slightly in excess of that of the surface speed of the rollers, so that the roving is a 
 little stretched. The excess of the carriage traverse is from 1 to 3 inches, and is known as its "gain." 
 
 (289) When the carriage reaches the termination of its outward run, or, as is commonly said, the end of its 
 stretch, it becomes necessary, first to arrest and then to reverse its movement, these operations necessitating a 
 complete change in the positions of the various parts. The chief agent in making these changes is the shaft M, 
 placed parallel to but a little higher than the rim shaft. It is known as the "cam shaft,'' and plays an important 
 part in the operation of the machine. It is entirely distinct both by position and function from the rest of the 
 mechanism, and a separate view of it and its connections is given in Fig. 156, which is a detached sectional 
 elevation. 
 
 (290) Hinged to one side of the headstock framing is the lever T — known as the " long lever " — at each end 
 of which pins are fastened, which carry the bowls RR 1 . Fastened to the carriage by bolts are two horn brackets 
 S S 1 , to which power of adjustment is given. The underside of the brackets is curved, and they are fixed at 
 such a height, that, as the carriage approaches either end of its run, one of them will engage with the bowl or 
 runner carried on a stud fixed in the end of the long lever, as shown very clearly by the dotted lines. At the outer 
 end of the long lever, the bell crank lever Q is pivoted, and is ordinarily drawn towards the end of the long lever 
 by a spiral spring O. In this way, when the latter has assumed a position in consequence of the pressure of the 
 horn brackets S S\ the pressure of Q upon it prevents it from moving until a similar force is again applied. In 
 short, the long lever is locked. 
 
 (291) On the cam shaft three cam or eccentric surfaces are placed, marked respectively W Y and Z. 
 These are shown with their connections in detached views. The cam W is compounded with the male half 
 of the friction clutch X, and can slide along with the half clutch upon a feather key fixed in the shaft. 
 The other half of the clutch is loose upon the shaft, and has formed upon its boss a spur pinion which, as 
 shown in Fig. 153, engages with the teeth of the backing-off wheel A 1 . Thus the continuous rotation of 
 the latter leads to a similar movement of X, and, as a consequence, the latter is always in a state of 
 readiness to rotate the cam shaft. A spiral spring surrounds the cam shaft, being sunk into a recess in the 
 bearing and continually pressing upon a flange formed on the sliding half of the friction clutch, thus 
 tending to force the latter into gear. On the inner side of the flange two cam surfaces are formed, as 
 shown at V, with which the nose of the rocking or escape lever engages. The latter is connected by a short 
 rod to the end of the long lever, the whole attachment being very clearly indicated in the illustration. 
 Suppose the end of the lever to be in the position shown in the left hand view of V, the friction clutch 
 would then be engaged, and the cam shaft would revolve until the outer cam surface on V came into 
 contact with the end of the lever, when the sliding half clutch would be disengaged and arrested, and the 
 motion of the cam shaft would cease. In this position the parts remain until the long lever is again moved, 
 this time having its inner end depressed by reason of the contact of the bracket S 1 , and bowl R 1 . The 
 nose of the escape lever is then moved oflf the outer cam surface into the flat or level portion of the inner 
 
190 
 
 THE MULE. 
 
 cam course. This permits the re-engagement of the friction clutch, and the cam shaft makes the second 
 half turn, causing the inner cam course to engage with the nose of the lever and again disengaging the 
 friction clutch. The raised cam surfaces on V are directly opposite one another, so that the cam shaft can 
 only make a half turn bufore it is disengaged. The next movement of the long lever, which takes place at 
 the end of the next outward run, is caused by the engagement of S and R, and the escape lever nose is 
 then moved on to the level surface of the outer cam course. This alternate movement of the long lever 
 takes place, as will be readily understood, when the carriage reaches the termination of its inward and outward 
 runs. 
 
 (292) If it be assumed that the carriage has reached the end of its outward run, and the cam shaft 
 has made a half revolution, three things take place. The back shaft clutch is disengaged, and the shaft 
 ceases to revolve; the roller clutch is detached, stopping the delivery of roving; and the cam Y is moved 
 into such a position that the strap lever can traverse so as to allow the strap to pass on to the loose 
 pulley. 
 
 (293) The back shaft clutch is controlled by the internal cam Z, in which a bowl on a pin fixed in 
 the bell crank lever Z\ Fig. 162, page 201, to which reference will be made for this part of the subject, works. In 
 the groove of the sliding half P of the clutch, the forked end of the lever T fits, this lever being- 
 hinged at its lower end and having a horizontal arm, the end or nose of which rests upon the horizontal 
 limb of the rocking lever Z 1 . Thus, when the latter is rocked so as to make an upward movement, the 
 lever T is raised, and causes a disengagement of the clutch PR 1 . The back shaft is thus freed, and all 
 motion of the carriage ceases. 
 
 (294) The rollers are disengaged by the cam W, which acts upon the cranked lever shown, the 
 vertical arm of which is forked and fits in the groove in the loose half of the roller clutch |. When the 
 cam is in the position shown in Fig. 156, the rollers are engaged, but when the cam shaft makes its half 
 revolution the lever is oscillated and the clutch is detached. As previously noted, the cam course is 
 formed in the loose half of the friction clutch X, which thus serves a double purpose. 
 
 (295) The compound strap guide lever is placed almost vertically, as shown in Fig. 158, being hinged 
 upon a pin in the headstock frame. The part G carries a short pin on which a small runner or bowl can 
 freely revolve. While the carriage is running out, the bowl is at the point of the cam Y, but when the 
 half revolution of the cam shaft is made it assumes a position at the base of the cam. These two positions 
 are very clearly shown in the right hand bottom corner of Fig. 156. This allows the strap to move, in 
 a manner mare particularly described afterwards, on to the loose pulley, so that the backing off friction 
 can be engaged. 
 
 (296) It has thus been shown that the half revolution of the cam shaft causes the stoppage of the 
 motion of the carriage, rollers, and spindles. This is the second stage or period, and it is at once followed 
 by tha third. Before passing on it is worth while reiterating that there is a decided advantage in the constant 
 rotation of the loose half of the clutches X aud A\ their engagement being made more rapidly and with less 
 
THE MULE. 
 
 191 
 
THE MULE. 
 
 193 
 
 strain. The power derived from the portion of the strap upon the loose pulley is sufficient to rotate the 
 cam shaft, and cause it to make the changes. It is also capable of maintaining the steady rotation of the 
 backing-off and taking-in friction clutches, so long as these are not in gear, or communicating motion to 
 the spindles or carriages. 
 
 (297) The strap guide arrangement is shown in detail in Fig. 158. The guider is fixed at the upper 
 end of a lever F, which is hinged, as shown, at its lower end to the heel of the lever G. F has also an 
 arm F\ which is coupled to a horizontal limb of the lever G by the spriug & The two or compound 
 levers are therefore constantly drawn towards each other. The lever G is secured on a short shaft, and has 
 a second spring Q attached, which pulls it in the direction of the arrow, when it is freed by the rotation of the 
 cam Y. A short stud bowl is fixed in G, and the pull of the spring presses it constantly against the cam. 
 Coupled to a short arm, fixed on the shaft to which G is secured, but at the other side of the headstock, is the 
 horizontal lever H, the outer end of which is drawn upwards by the spring P, fastened to the framing. A 
 shoulder or recess is formed in H, which ordinarily engages with the fixed catch L, by which the strap guide 
 lever is locked in position when the strap is on the fast pulley. On the inner end of the rim shaft a worm 
 K is formed, which gears with a worm wheel compounded with a spur pinion, which, in turn, gears with 
 the spur wheel shown. On the spindle of the last-named wheel a small crank O is keyed, the outer end 
 of which has a pin, carrying a bowl, fixed in it. 
 
 (298) The action of this mechanism is as follows : The revolution of the rim shaft causes the crank O, which 
 is, at the commencement of the outward run, just clear of the nose of the lever H, to revolve. By the time 
 the outward run is completed, the crank will have made almost a complete revolution. When the necessary 
 twist has been put in the yarn, the crank O comes in contact with the front end of the lever H and releases 
 the catch L. Immediately this happens the spring Q acts, and the strap guide lever oscillates, causing the 
 strap to glide upon the loose pulley. 
 
 (299) This step having been accomplished, the next operation is to engage the backing-off friction. As 
 shown -in Fig. 158, the boss of the wheel A 1 is formed with a ring groove, into which a claw fastened on a 
 short stud fits. The lever D is also fixed on the same stud, so that any movement given to it is communicated 
 to the claw and backing-off friction. The lower end of the lever is forked and passes over a rod X extending 
 along the side of the headstock. This rod is guided by a bracket fixed to the side of the frame, and has 
 the two stop hoops X 1 X 2 fastened on it. Between the stop hoops a spiral spring, always in compression, is 
 threaded upon the shaft, one end pressing against the lever D, and the other against the hoop X 2 . It will 
 be readily understood that the compression of the spring will tend to push the lever D in the direction of 
 the arrow, until its motion is stopped by a link connected with the slide in the arm, to which is fastened 
 the lever H. It is essential that the engagement of the backing-off clutch should be practically simultaneous 
 with the transferring of the strap from the fast to the loose pulley, and it is therefore desirable that the 
 spring on X should be put in compression a little before the actual traverse of the strap. 
 
 (300) This is accomplished by means of the swinging lever V shown in Fig. 162. This is hinged upon 
 the square, and is formed, as shown, with an open mouth, at the upper part of which is an angular projection 
 
194 
 
 THE MULE. 
 
 or lip. Pivoted on the framing is the lever L, the horizontal arm of which carries a small runner, which 
 engages with the incline of V as the carriage runs out. The lever V cannot, until the termination of the 
 stretch, be swung upon its pivot by reason of its connection with the faller locking lever A. When, therefore, 
 the bowl in the lever L engages with the incline of V, the lever L is oscillated, so that the spring on X is 
 further compressed. The spring is, therefore, in a position to push the backing-ofF lever forward, as soon as 
 the latter is freed. The engagement of the lever L with the lever V takes place a few inches before the 
 carriage arrives at the end of its outward run. 
 
 (301) When the outward run is completed, and the cam shaft begins to revolve, the lever D has sufficient 
 pressnre on it to push it over if it were free to move. Reverting again to Fig. 158, the horizontal lever H 
 and the arm previously referred to are coupled by a small pin in the latter, which takes into a slot in the 
 former. When, therefore, the lever H is locked, the vertical lever D cannot move, but when the unlocking 
 of the lever H by the crank O occurs, the oscillation of the strap lever draws, by means of the arm, the 
 lever H in the direction of the arrow. This permits the spring X to extend and push the lever D forward 
 and so engage the backing-ofF friction. This movement is rapid and nearly simultaneous with the transferal 
 of the driving strap. The mechanism is set to permit the backing-ofF friction to come gradually into gear 
 for the purpose of acting as a brake, as was explained in paragraph 282. 
 
 (302) The friction cones being engaged and the strap placed on the loose pulley, the rim shaft is 
 driven in the contrary direction, thus reversing the spindles. It therefore becomes necessary to take up the yarn 
 as it is delivered from the spindles. This is effected by means of the faller and counter faller, as indicated 
 in paragraph 270, and the precise mode of action of these can now be described. 
 
 (303) The faller arms M and U, as shown in Fig. 161 (page 205), are sickle or crescent shaped, so that they 
 can readily pass down between the cops without touching them. The arms are keyed on the winding faller and 
 counter faller rods B B 1 at convenient intervals, and the wires are threaded through them. The latter are 
 thus well sustained, and do not deflect to any appreciable extent, this being fatal to the effective building of 
 the complete set of cops. The rods or shafts B B 1 are borne by brackets fastened to the carriage, so that 
 their axes are quite parallel to the centre line of the carriage. The winding faller shaft is oscillated by 
 suitable mechanism, by which at the proper moment it is drawn downwards, while the upward movement of the 
 counter faller is regulated from the winding faller. There is an important difference in the action of these parts. 
 As the winding faller is to act as a guide to the yarn during winding, it is essential that it is, at the beginning 
 of each inward run, in the correct initial position for that purpose, and that, when it has reached that position, 
 it shall be locked. On the other hand, the function of the counter faller being merely to maintain the 
 tension of the yarn during winding and backing-off, it is necessary that it should be free, so as to bear constantly 
 against the underside of the threads without exercising an undue strain. The pressure thus exerted should be a 
 little in excess of the downward pull of the whole of the threads which are being spun in the machine, but 
 not so much in excess as to prevent the counter faller yielding a little if from any cause an extra pull is put upon 
 the threads. In other words, the action of the winding faller is positive, while the counter faller acts as a 
 
THE MULE. 
 
 195 
 
 regulator of the yarn tension. In order to maintain this relation t is desirable to establish a connection 
 between the descent of the faller and the ascent of the counter faller. This is done by making the latter dependent 
 on the former, and by leaving it free after it has been released. 
 
 (304) The controlling mechanism is shown in Fig. 159, which is a representation of the parts affecting 
 the counter faller. Hinged, as shown, to a bracket on the underside of the carriage is a lever J, to which 
 are attached two chains E 1 I. The former is coupled to a sector E, which is secured on the counter faller 
 
 Fig. 158. 
 
 shaft or rod B 1 . If it is assumed that the latter is free to rotate, as it is, the pull exercised by the lever J 
 would be sufficient to cause it to do so. But until the winding faller makes its descent so as to assume 
 the winding position, as afterwards described, the weight of the lever J is taken by the chain I, which at 
 its upper end is fixed to the hook shown. The latter is hinged to the bracket or lever S, the other arm. 
 of which rests upon the counter faller rod B 1 , and thus limits the upward movement of the winding faller. 
 
196 
 
 THE MULE. 
 
 A steady torsional pull is exercised upon the bracket S, so as to draw the chain I upwards, by the spring V, 
 attached as shown. The unwinding of the two or three coils of yarn during backing-off takes place during 
 the time the winding faller is descending. Immediately backing-off is completed, the carriage begins to run 
 in, and the yarn is wound. It is therefore necessary for the counter faller to rise, so as to take up 
 any slack yarn. Unless this is done, the yarn — owing to its tightly twisted condition — runs into small loops or kinks, 
 technically known as "snarls." The oscillation of the winding faller rod B has caused a similar movement 
 in S, and, as a result, the chain I becomes slackened and ceases to sustain the lever J. As, therefore, the 
 carriage O begins to run in the lever J descends, and the whole of its weight is borne by the chain E 1 , which 
 is caused to pull upon the sector E. In this way the counter faller rod B 1 is oscillated, and the counter 
 faller wire M is raised. The extent of its upward movement is regulated solely by the tension of the threads, 
 which is sufficient to act as a counterbalance to the lever J. In order that this equilibrium shall be sufficient 
 to preserve the necessary tightness of the threads, without any danger existing of either slack threads or of 
 the counter faller being unyielding when an extra strain is put upon the yarn, balance weights can be added 
 at the end of the lever J, as shown. In this way the necessary sustainment of the yarn threads is obtained 
 without any likelihood of straining or breakage. When the carriage has completed its inward run the 
 weight of the lever J is relieved by the roller W, so that the faller, when released, as afterwards described, 
 can easily assume its proper position during spinning or twisting. 
 
 (305) While the counter faller is being freed in the manner described the downward movement of the 
 faller is also proceeding. Eeferring now to Fig. 160, which is a detailed view of the faller arrangement, the 
 faller shaft has fixed on it an arm or backing-off finger D, to which is fastened one end of a chain E. One 
 end of E passes round the small bowl F, and its other end is fastened to a snail or scroll G mounted on 
 the tin roller shaft. The snail is geared by a ratchet clutch which engages only when the tin roller is 
 revolving during backing-off. being disengaged during the whole period of spinning. The size of the snail is 
 arranged so as to draw down the faller finger D during the period of backing off to such an extent that the 
 faller is brought into the proper position for the commencement of winding. In dealing with the latter 
 operation it will be shown that the faller is a little below the cop nose when winding begins, and then rapidly 
 descends until the base of the upper cone is reached. At present it ia only necessary to note this fact, as 
 it has a somewhat important bearing on the mechanism being described. During the period of the faller 
 descent a pull is exercised on the rod F 1 , by which the bowl or runner F is carried. The other end of F 
 is hinged to the "locking" lever A, to which the curved arm or sector C is hinged at its upper end. This 
 arm is fixed on the faller shaft, so that the oscillation of the latter, which is caused by the pull of the chain E, 
 gradually raises the "locking" lever A. This elevation goes on until the shoulder or bracket K is high 
 enough for its under side to slip over the small bowl fixed in the lever or slide L. The latter is at the end 
 of a lever hinged at one end to the carriage and carrying the runner or bowl L 1 . This is drawn along with 
 the carriage, and the lever is consequently called the " trail " lever. As soon as K slips on to the bowl in 
 L the " locking " lever and faller are said to be " locked," and are then in a position to begin winding. 
 
THE MULE. 
 
 197 
 
 This action is practically simultaneous with the termination of backing-off. This method of locking the 
 faller is now general, having quite superseded the older method of locking at the top. 
 
 (306) In order to render the action of backing-ofF more perfect, and to ensure that the slack of the 
 yarn, as it is unwound, shall be taken up by the faller, Messrs. Piatt Brothers and Company have adopted 
 the mechanism also shown in Fig. 160. The reversal of the direction of rotation of the spindles takes place 
 a little in advance of the downward movement of the faller, and it is therefore found that a short length 
 of yarn is unwound before the faller presses upon it. The actual extent of the unwinding is relatively greatest 
 when the cop is almost built. It therefore becomes necessary to expedite the action of the backing-off chain 
 
 Fig. 160. 
 
 as the cops are built, so that the faller is drawn into contact with the yarn at the earliest moment. A little 
 reflection will show that at the period when the cops are beginning to be built the faller wire has a much longer 
 distance to travel than when they are almost finished. As will be afterwards shown, the period at which the 
 faller is locked is gradually made earlier as building proceeds, so that a much shorter traverse of the faller prior 
 to locking takes place correspondingly. Thus, for instance, if it has to be depressed one inch before it touches 
 the yarn at the commencement of a set of cops, the relative proportion of that distance to the whole traverse 
 prior to locking is less than when the traverse is so much diminished at the end of a set. Thus it follows that 
 a degree of lagging permissible at one stage is absolutely detrimental at the other. From this it may be 
 
198 THE MULE. 
 
 deduced that an earlier and accelerated motion of the faller is necessary in order to take up the slack yarn 
 during backing off. 
 
 ■ 1 (307) It is' hardly practicable to fit a motion of absolute accuracy to effect this purpose, but an approximation 
 to it can be obtained. It is, therefore, arranged that at the beginning of a set the backing-off chain shall be 
 slack, and during building shall be gradually tightened until at the end of it is nearly in a state of tension. 
 The snail is proportioned so as to give a quick downward movement to the faller, and in combination with the 
 
 Fig. 159. 
 
 arrangement about to be described gives very good results. Referring again to Fig. 160, attached to the snail G is 
 a second chain, the other end of which is fastened to a lever H, hinged on the bracket shown. The other end of 
 H rests on an inclined plate N, which slides on a bedplate fastened to the floor. The plate N is fastened to 
 the copping plate connecting rod— afterwards referred to — which passes through a horn fastened on N. As the 
 copping plate is moved in, H is also caused to assume the position indicated by the dotted lines, N having also 
 moved in. The effect is that a pull is put upon the snail which gradually rotates it, and causes it to wind on 
 
THE MULE. 
 
 199 
 
 the slack of the chain E, so that, when backing-off occurs, the faller is drawn downwards at an earlier 
 moment. The restoration of N to its original position accompanies that of the copping plate, and is made at 
 the beginning of a new set of cops. 
 
 (308) The various movements in connection with backing-off having tbus been described, it is necessary to 
 show how the traverse of the faller is obtained during the inward traverse of the carriage. This is shown 
 in Fig. 161, page 205, which is a separate view of the copping or building mechanism. The faller "locking " lever 
 A is, as has been described, raised until the shoulder R slips on to the slide L, in which position it remains 
 until it is released at the termination of the inward run. On the underside of L a small bowi or runner 
 L 1 is carried, which rests upon the upper surface of a longitudinal, or "copping" rail P, made of a strong 
 section. If the latter was placed in such a position that its upper surface was horizontal, it is plain that the 
 slide L would receive no vertical motion during the period that the runner L 1 was traversing it. In consequence 
 the sickle U would remain in one position during the same time. But if the rail P is raised at one end so that 
 its upper edge is inclined, the slide |_ will, during the run in of the carriage, receive a vertical traverse' 
 corresponding to the difference in the altitude of the two ends of the copping rail. That is to say, if one end of 
 the rail was six inches from the floor line, while the other end was seven, |_ would ascend or descend to the extent 
 of one inch while it was travelling from one end to the other of the rail P. The question as to whether it would 
 ascend or descend depends entirely upon wdiich end of the rail was highest. From this it may be inferred that by 
 varying the angularity or profile of the copping rail any desired traverse, either regular or intermittent, could be 
 given to the slide L. Now it was shown that the winding faller sickles are keyed on the shaft B, which is 
 oscillated by the backing-off finger D fastened upon it. The latter being jointed to the " locking " lever A, it 
 follows, that, as the latter is raised, the winding faller moves in an arc, which corresponds in length and direction 
 to the length and inclination of the copping rail. 
 
 (309) It is necessary when the carriage arrives at the end of its stretch to lock it in that position 
 during the time that backing-off is taking place, and the motions of releasing the counter faller and locking the 
 winding faller are in operation. A reference to Fig. 162 is necessary to understand this part of the mechanism. 
 That illustration is a diagrammatic representation of the mechanism relating to locking the carriage, and the 
 engagement and disengagement of the taking-iu gear. The parts are not in their working position, but are projected 
 so that their operation may be better understood. The actual relative position of the various motions is 
 shown by the diagrammatic sketch in the right hand top corner of Fig. 162. Upon the carriage O a bracket 
 O 1 is fixed, which carries at its outer end a pin or catch, with which the hook at the end of the horizontal 
 arm of the L lever S can engage. The hook readily falls over the pin in O 1 , as the carriage is pushed up to 
 it near the end of its traverse. The lever S is coupled in the manner shown to the horizontal rod R, 
 which, at its other end, is jointed to a bell crank lever U 1 . The rod R, on account of its function, is termed the 
 "holding-out catch rod." The lever U 1 is in turn connected with the rod U, jointed at its upper end to the lever 
 W, which is coupled to the horizontal arm of the lever Z 1 by the connecting rod M. A connection is thus 
 established between the cam Z on the cam shaft and the " holding-out" catch lever During the run out- of 
 
200 
 
 THE MULE. 
 
 the carriage the friction clutch | 1 K is disengaged by means of the lever W- The rod R is also locked by 
 the small vertical slide S 1 , which engages with the catch notch formed in it. The movement of the 
 backing-off rod X, which is hinged to the lever L, causes the projecting arm in the lever Y to be pushed 
 under the end of the lever W, thus sustaining the latter and preventing the engagement of the upper half 1 1 of 
 the taking-in friction with the lower half K. This action occurs just before the termination of the outward run, 
 being a little in advance of backing-off, but simultaneous with the compression of the backing-off spring on 
 X. Whatever movement of W may take place after the arm on Y is thus projected into the path of the end of 
 the lever W, the friction cannot fall into gear until the support of the arm is withdrawn. The whole of 
 these parts are thus locked together, and fall into gear simultaneously. It will be noticed that the connection 
 between the lever S and the rod R is such that the latter can make a certain movement forward before the lever 
 falls. Further, the carriage can be arrested during its outward run by the pedal lever fixed to the floor. 
 
 (310) The action of the mechanism is as follows : When the carriage arrives at its outermost point the 
 connecting rod R is unlocked, and is free to move. In this way the catch lever S can be easily raised by 
 the bracket on the carriage O, over which it falls, and securely holds it, the slot in the rod R permitting 
 this movement. In this position it remains during the whole period of backing-off, when in a way which 
 is afterwai'ds described, it is released simultaneously with the taking-in friction with which, as shown, it is 
 oonnected. The locking of the carriage is the last operation requiring explanation before proceeding to deal with 
 the movements, which, together, make up the fourth stage or period. This is the one in which the nicest problems 
 require solution, and in which the mechanism used is the most ingenious. 
 
 (311) The first step in commencing to wind is, of course, to release the carriage and draw it in. Before 
 proceeding to show how this is effected, it will be as well to recapitulate and describe the position of the various 
 parts. The strap is entirely upon the loose pulley ; the backing-off friction clutch is in gear ; the spindles 
 are revolving in the opposite direction to that normal to them ; the winding faller is drawn down and locked 
 in a position a little below the nose of the cop; the counter faller is held just out of contact with the 
 threads, but free to rise as soon as an inward movement of the carriage occurs ; the roller and back shaft 
 clutches are disengaged ; and the upper half of the taking-in friction is out of gear with the lower, but 
 revolving with the vertical shaft on which it slides. 
 
 (312) When the chain E (Fig. 160) has sufficiently raised the faller locking lever A to permit it to lock, 
 the swinging lever V is suddenly drawn back. An examination of the drawings, either Fig. 160 or Fig. 161, 
 will show that so long as the face of the locking lever presses against the face of the slide no lateral movement 
 of the former is possible. Further, the connection established between the locking lever A and the lever V, by 
 means of the lever F 1 , ensures that as soon as the inward movement of the lever takes place when locking 
 occurs, the lever V must necessarily oscillate on its pivot. This movement of the lever V causes its lower jaw 
 to exercise a pressure upon the lever L in the contrary direction to that previously noted, and so draws the stop 
 X 1 in contact with the bottom of the backing-off lever D. This action is aided by the spring on the backing-off 
 rod, which is free to extend, and its whole force can be exerted on the lever D. In this way D is drawn 
 back, and the backing-off clutch is disengaged. 
 
THE MULE. 
 
 201 
 
 (313) The same movement draws -away the supporting piece on the vertical lever Y, and allows the 
 upper half of the taking-in friction to fall into gear with the lower half, this action being aided by the 
 spring Q. The slot in the end of the connecting rod M permits the upward movement of the left hand end 
 of the lever W to be made rapidly and freely. In this way the engagement of the friction clutch is a 
 very quick one. This upward movement of the lever W is communicated, in a manner described, to the 
 holding out catch, which is also raised nearly simultaneously, and the carriage released. 
 
 (314) It is, of course, highly essential that all the three releasing motions shall be accurately 
 " timed," so as not to take place either before or after the proper moment. Accordingly, ample means of 
 
 
 S L 
 
 
 o 
 
 R X 
 
 O 
 
 u' 
 
 W 
 
 Y 
 
 „ .'..^ W f.-'Y.V"' 
 
 :> H • ■y.'.'y.'v.v.;:-.-:;. 
 
 Fig. 162. 
 
 adjustment are provided, both on the rod X by the regulation of the stops X 1 and X 2 ; on the connecting 
 rod M coupling the levers Z and T ; and also on the holding-out rod. In this way it is possible to secure that 
 simultaneous movement of the three parts, which is so essential for effective working. It is obvious that 
 the backing-off friction and holding-out catch must be released before the taking-in friction gears, but 
 the interval between these is so slight that they occur practically simultaneously. 
 
 (315) The taking-in friction being in gear, the rotation of the loose pulley is, by the train of wheels 
 shown, communicated to the "scroll" shaft, on which the taking-in scrolls are fixed. These have bands 
 
202 
 
 THE MULE. 
 
 attached to and wrapped round them when the carriage is at the roller beam. As the carriage runs out, the 
 bands, which are fastened to it, are drawn off the scrolls, the scroll shaft being then free to revolve. The 
 engagement of the taking-in friction reverses this process and winds on the bands, thus drawing up the carriage. 
 It will be observed that the scrolls vary in diameter, being about 9 inches in the largest part, and about 3 
 inches in the smallest. The reason of this construction is to give a varying traverse to the carriage, so as 
 to start it easily, and bring it up to the back stops gently. The scrolls are designed so that, so long as 
 they are revolving, they exercise a pull upon the carriage which is steady and constant. In this way, over- 
 running is avoided, but to prevent any possibility of it a scroll L 1 , shown in a detached position in Fig. 153, is 
 fixed on |_ at an angle of 180 degrees to the others, the point of attachment of its rope being diametrically 
 opposite that on the other scrolls. Thus when the bands on the drawing out scrolls are unwound, that on 
 the " check scroll " is wound and vice versa. The purpose of this scroll is, as its name indicates, to check 
 any tendency to over-running, which it effectually does. In all mules above a certain length, it is desirable 
 to provide some means whereby the carriage shall be drawn in evenly throughout its length, and shall not 
 be in danger of twisting or warping. The scroll shaft, it will be noticed, only extends across the headstock, 
 so that the bands can only exercise any pull on the square, and if no other points of attachment were made, 
 the carriage would at its extremities lag behind the centre. A considerable amount of friction would be thus 
 caused, and the spindles at the end of the carriage would not take up the full length of yarn. It was shown 
 that the back shaft is, during winding, disengaged, so that it is only necessary to establish a connection 
 between it and the scroll shaft, to enable the carriage to be drawn in at several points throughout its length, 
 instead of at one only. Accordingly, the scroll shaft is extended, and an extra scroll shown in Fig. 154 at the right 
 hand side is fitted, from which a band is taken to a drum upon the back shaft. Thus the back shaft is 
 converted into a taking-in shaft, and during that operation revolves of necessity at a variable speed given to 
 it by the scrolls. In this way the carriage is kept parallel to the roller beam throughout its course, and 
 comes up to the back stops along its entire length at one time. 
 
 (316) The arrangements for taking-in having thus been described, it now becomes necessary to describe 
 the operation of winding. Before doing so, it will be better to deal with the problem to be solved, and it 
 will aid in understanding it if the construction and method of building the cop be described. For this 
 purpose a reference to the diagrams given in Figs. 163 and 164, page 207, is necessary. The cop is built, as before 
 explained, upon the blade or taper part of the spindle, and, when finished, is of the shape shown in Fig. 163, 
 viz., a cylinder with conical ends. The central part of the cop, EG K F, is cylindrical, and at the top and 
 bottom of this part are two cones. The lower coue, A E B C F D, forms what is known as the " cop 
 bottom," and the upper one, G H I K, the "nose," although the latter term is more often and strictly 
 applied to the extreme apex at the points H I. As previously stated, the yarn may be wound either upon 
 the bare spindle, upon a short paper tube, as indicated by the thick line inside the cop bottom, or upon a 
 similar tube the whole length of the cop. The use of paper tubes of this character is preferable, especially 
 in cases where the cop is likely to be much handled, as it prevents it from being crushed in, and enables 
 
THE MULE. 
 
 203 
 
 the introduction of a skewer for subsequent winding without there being any danger of the cop being pierced 
 or "stabbed," this being a fruitful source of waste. 
 
 (317) In commencing to wind, the yarn is wrapped on the lower part of the spindle in close coils or 
 spirals for a length of a little more than an inch. The whole of one stretch is wrapped upon this space, and 
 when the next stretch requires winding, it is laid upon the previous layer, and so on until the double cone 
 A E B C F D is produced. The length of the traverse of the winding faller wire, or the length of each layer verti- 
 cally, is called the " chase " of the cop or faller. From this point the yarn is wound in successive layers, beginning 
 always at a higher point, until the final traverse is obtained by which the winding is conducted upon the surface 
 or nose represented by the letters G H I K. It was stated in paragraph 311 that the winding faller wire, when 
 the winding faller is locked, is in a position a little below the point HI. As soon as the carriage begins 
 to run in, the vertical movement of the winding faller locking lever begins, and is so arranged that the first 
 movement of the wire is a rapid downward one. The effect is that the yarn is laid on the no3e of the cop 
 in coarsely-pitched descending spirals, as shown in Fig. 164, these extending downwards until the winding 
 faller wire reaches a point opposite the base of the upper cone, in this case shown in Fig. 163 at K. From 
 this point a slower ascent of the winding faller wire is made, so that the yarn is laid in the more finely 
 pitched spirals shown, until the nose of the cop is reached. By this time the carriage has arrived at the 
 roller beam, and the whole of the 63 inches of yarn has been wound. 
 
 (318) When the first layer of yarn is wound, and the winding faller is assuming its position to wrap 
 on the second, the initial point of its traverse is a little raised. In this way the yarn is gradually wound in layers, 
 which are represented by the angular lines springing from the lines A E and D F towards the spindles 
 During this period the enlargement of the diameter of the cop bottom is proceeding until at the points E F the 
 full diameter of the cop is reached. As soon as this occurs the initial point of each layer is gradually raised, and 
 the length of the traverse is slowly diminished as the completion of building is approached, until at the 
 termination of a cop the angle of the layers is shown by the lines G H and I K. There are thus two adjustments 
 shown to be necessary — First, the starting point of each traverse of the winding faller requires altering ; and 
 second, its extent also needs regulation. 
 
 (319) These two objects are attained by the regulation of the copping rail P, as shown in Fig. 161 
 The ends of this rail rest upon inclined " copping " plates Y X, which are fastened together by the rod W, and 
 which receive, as will afterwards be described, an inward movement during the building of the cop. It was shown 
 that the locking of the faller lever and its vertical movement leads to a corresponding movement of the faller. If, 
 for instance, the faller locking lever fell an inch, the winding faller sector would be oscillated and the faller 
 wire drawn upwards. The rate of the ascent of the latter is absolutely relative to the period of the descent of the 
 locking lever. Referring now to Fig. 165, which is a small diagrammatic sketch of the copping rail and its 
 supports, suppose the line G H to represent the top of former, O P the latter, and L the bowl at the foot of the 
 locking lever, if L, starting from the left hand position, be supposed to travel in the direction of the arrow 
 V, it will be seen that it will fall to the extent indicated by the space Y Z. If, on the other hand, the slides 0 P 
 
204 
 
 THE MULE. 
 
 are moved into the position shown by the dotted lines, the rail G H will also fall into that indicated in a 
 similar maimer. The result is that if L now makes the same traverse as before it will rise a little as indicated by 
 the space W X. The effect on the winding faller would be that in the first case it would be raised, and in the 
 second it would be depressed to an extent corresponding to the depression of the locking lever. The extent to 
 which this elevation or depression is made depends upon the vertical traverse of the locking lever, and the ratio of 
 the distance of the point of junction of the sector C with the faller shaft and that of the faller wire from the 
 
 v 
 
 . 165. 
 
 same rod. If, for instance, this proportion was 1 : 2, an elevation of the locking lever half an inch would result 
 in a depression of the faller an inch. It is therefore necessary, during the inward run of the carriage, to 
 provide for the inclination of the carriage to such an extent as to secure the requisite traverse of the faller 
 wire. As the amount of such traverse varies during the building of the cop, it follows that the inclination 
 of the copping rail must be varied correspondingly. 
 
 (320) Referring again to Fig. 161, the ends of the copping rails have pins fixed in them, on which are anti- 
 friction bowls, which run upon the edges of the copping plates. The latter are duplicated, so as to sustain the rail 
 at each side, and thus maintain its vertical position. At one side of one of the plates Y is an ear S 1 , which is 
 threaded to correspond with a square threaded screw S passing through a fixed bracket fastened to the floor. In 
 this way the screw S is free to revolve, but cannot make any longitudinal movement. On the end of the screw S 
 a ratchet wheel is fixed with which a pawl S 2 engages, which is oscillated so as to move the wheel one tooth at 
 convenient times. The speed of the revolution of the screw varies according to the counts being spun, the elevation 
 of the point of locking being more quickly effected when coarse yarns are being made than when the finer varieties 
 are produced. Whatever may be the velocity at which this elevation is accelerated, the profile of the copping 
 plates is such that the inner end of the copping rail P is lowered at a more rapid rate during the formation of the 
 cop bottom than at a subsequent stage. The reason of this will be easily comprehended, if the description of the 
 mode of building the latter be borne in mind. It was then shown that the traverse of the winding faller rapidly 
 increased in extent until the full length of the cop bottom was built. It, therefore, follows that the descent of the 
 locking lever must be largely increased at this period at a quick rate, in order to produce the result indicated. 
 When the outer end of the copping rail begins to descend at a rate which more nearly corresponds to that of the 
 inner end, it gradually approaches to the horizontal, and the vertical motion of the slide, locking lever, and faller 
 is proportionately limited. 
 
THE MULE. 
 
 205 
 
 (321) The regulation of the winding faller as just described was the one which was usual uutil recent years. 
 It has been found necessary, however, to obtain a more accurate regulation, so as to ensure that the faller wire 
 shall be in its correct position when locking occurs, especially during the period between the beginning of a cop 
 and the attainment of its full diameter. It is now customary to attach to the front end of the copping rail a loose 
 plate Q, which is hinged at one end to the rail, and which carries at its outer extremity a pin and bowl resting 
 upon a third inclined plate Z. By varying the profile of the plate Z, the regulation of the faller during the early 
 part of its traverse can be accurately made and the proper position of the wire ensured. As a glance at the 
 illustration will show, the upper edge of the copping rail is not straight, but is shaped so as to give a variable 
 speed to the slide L in its vertical movement. The proper shaping of the copping rail gave rise to some difficulty, 
 and it will be seen that the loose copping rail Q is shaped so as to produce the proper effect, while being much 
 more easily adjusted. 
 
 Fig. 161. 
 
 (322) The actual operation of this mechanism is as follows : When the carriage is at its outermost point, 
 and the winding faller is locked, the wire is, as previously mentioned, a little below the nose of the cop. As 
 the inward run proceeds, the bowl first runs up the loose incline, thus raising the locking lever and depressing 
 the winding faller wire. The distance, from the extreme outward point reached by the bowl L 1 and that where 
 the loose rail Q is hinged and the downward inclination of the copping rail begins, is so short that the initial 
 depression of the winding faller is very rapid. This produces the coarsely pitched coils referred to in paragraph 
 317, and illustrated in Fig. 164. By the time the bowl L 1 is at its highest point the winding faller wire is 
 opposite the base of the upper cone. The subsequent downward inclination of the copping rail is much less 
 acute, and the consequent descent of the faller locking lever less rapid. As a result the upward traverse of 
 
206 
 
 THE MULE. 
 
 the winding faller wire is made more slowly, and the yarn is wound in more finely pitched spirals. It only 
 remains to be said, in connection with this part of the subject, that owing to the shape of the copping plates 
 their inward movement is accompanied by a gradual fall of the copping rail, and, consequently, the locking point 
 of the faller lever is relatively elevated. In other words, the traverse of the locking lever prior to locking is 
 gradually lessened as the trail lever slide L is lowered, and this is equivalent to an elevation of the winding faller 
 lever and its locking point or shoulder K. This causes the depression of the winding faller wire prior to locking 
 to be gradually diminished, so that there is an elevation of its initial point. 
 
 (323) The method of obtaining the traverse of the winding faller having been described, the equally 
 important points relating to the mode of rotating the spindle during winding require to be dealt with. A little 
 thought will show that so long as the surface upon which the yarn is wound remains small the spindles must 
 revolve at a more rapid rate than when the surface is enlarged. As the extreme diameter of the cop bottom is 
 enlarged the conditions of successful winding are continually changing. At the commencement of the cop the 
 yarn is wound upon what is practically a parallel surface with a diameter of y T inch and a circumference 
 of -9S inch. This implies that to wind the 63 inches of yarn 64*3 revolutions are required, these being made 
 during the run up of the carriage. But as the diameter of the cop is enlarged the circumference of the conical 
 surface becomes a variable one, and owing to its enlargement the number of revolutions required to wind the 
 same length of yarn is fewer. This is quite clear and needs no demonstration. Thus when the cop bottom is 
 formed the extreme range of variation is reached, and it follows that in the interval between the commencement 
 of winding and the formation of the cop bottom each stretch must be accompanied by a diminution of the 
 velocity of the spindle proportionate to the increase of diameter. In addition to this it is necessary to take 
 into consideration the varying diameter of the conical surface on which winding takes place, which necessitates 
 a greater terminal than initial velocity of the spindle. 
 
 (324) A further point requires elucidation. If the spindle blade were parallel, the number of revolutions 
 necessary to wind the 63 inches of yarn properly, when the cop bottom is formed, being fixed, no further 
 alteration would be necessary. But these conditions do not exist, and the nose of the cop is wound upon a 
 continually diminishing diameter. It is of the utmost importance that the yarn is wound tightly at the nose 
 during the whole of the building of the cop. The rate of the vertical traverse being practically 
 uniform, unless an acceleration of the spindle velocity occurred, there would be slack winding during the 
 latter part of the building of the cop. This would produce a sponginess of the nose, which, when the yarn 
 was drawn off in the subsequent process of winding, as shown by the arrow in Fig. 164, would result in 
 several rings or coils being pulled out in an entangled condition, thus producing waste. Technically the 
 cop would be said to be "halched." Illustrating this part of the subject by figures, if the diameter of the 
 spindle at the point B, Fig. 163, be assumed to be ^ inch, its circumference would be '7854 inch ; while 
 if the diameter at H be assumed to be £ inch, the circumference would be only *3927 inch. To wind, say, 
 10 inches of yarn in each case, would require about 12 and 25 revolutions of the spindle respectively. It 
 is therefore clear that, if the same length is to be wound with equal tension upon the nose of the cop 
 
208 
 
 THE MULE. 
 
 throughout the whole process of building, there must be a gradual acceleration of the terminal velocity of 
 the spindle. Although this is only slight at first it is required at an earlier point as the cop is formed, 
 and becomes of increasing importance. 
 
 (325) It will be shown, a little later, that the rotation of the spindles during winding is obtained by 
 the pull of the carriage on a chain, which has its other end attached to an oscillating arm, being fastened 
 to a drum on the carriage. To get a clear idea of the action of this part of the mechanism the two 
 diagrams shown in Figs. 166 and 167 are given, a study of which will be profitable. In Fig. 166 the 
 circles BCD represent three positions of the barrel or drum after it has moved in a horizontal plane in 
 the direction of the arrow. To the drum a chain is supposed to be attached, which is held at the point A. 
 It is, of course, understood that the barrel is mounted upon a shaft or axis so that it can freely revolve. 
 If it be now assumed that the barrel is in the left hand of the three positions B, the chain will be wrapped 
 completely round it. As it is moved horizontally in the direction of the arrow it is revolved, as indicated 
 
 A 
 
 Fig. 166. 
 
 by the curved arrows, and, by the time it has reached its middle position C, has been rotated sufficiently 
 to unwind about half a turn of the chain. A further horizontal motion to the right hand position D will 
 complete the unwinding, and, by this time, the drum will have made one complete revolution. It will be 
 at once seen that the rate at which the drum will be revolved will depend upon two factors — its diameter, 
 and the speed of its horizontal traverse. If the point A at which the chain is held is stationary, and the 
 horizontal movement uniform, then the rotation of the barrel will be constant. But if the barrel be traversed 
 at a variable rate then its rotation will also be variable. In actual practice this uniformity does not exist, 
 for, as was shown in paragraph 315, the taking-in scrolls vary considerably in diameter. Assuming this 
 variation to be 1:3: 1, it would follow that the rotation of the barrel would increase and diminish in the 
 
THE MULE. 
 
 209 
 
 same ratio. In practice this is what happens, and the speed of the revolution of the barrel is quicker about 
 the middle of the takiug-in than at any other time. 
 
 (326) The assumption that the point A is stationary was only made to illustrate the point at 
 issue, and is not founded upon the actual facts of the case. If now it be assumed that not only the 
 barrel but the point at which the chain is held makes a forward movement, a new set of conditions arises. In 
 this case the unwinding of the chain during a given time will be diminished by the amount of the advance 
 of the point A in the same period. Assuming the latter to be made at a regular rate it would be easy 
 to calculate the extent of the unwinding. If the effect of the horizontal movement of the barrel from 
 B to C be to unwind half of one coil of chain — say a length of 7 inches — and that in the same space 
 of time the point A moved 3 inches, the amount unwound would be reduced to 4 inches. But this is 
 not the actual condition of things in practice. The point moves at a variable velocity, its forward motion 
 gradually diminishing, so that the acceleration of the rotary velocity of the barrel is greater at the end of 
 its horizontal traverse than at the beginning. In other words, its terminal velocity is highest. 
 
 (327) The point of the attachment of the chain at A is made in an oscillating arm which, during 
 the inward run of the carriage, receives a forward movement at a speed which is controlled by 
 the velocity of the back shaft. As the latter is, in turn, commanded by the scroll shaft during this 
 period — see paragraph 315 — it follows that the variation in the forward movement of the arm is 
 coincident with that of the carriage. Thus the advance of the point A will always be in strict 
 correspondence with the velocity of the carriage traverse. 
 
 (328) Referring now to Fig. 167, and, assuming A B to be the arm to which the chain is fastened, and O J 
 and H C to represent the arcs through which the point of attachment of the chain travels at different times, it will 
 be seen that the periods of movement are well marked. In each case the arcs are of the same number of degrees, 
 although the chord of one is shorter than that of the other. Dealing first with the inner arc, which represents 
 the position of the point of attachment when nearer the centre, the whole period of movement is divided into equal 
 parts. These are represented by the letters J K L M N O. Now, if vertical lines are drawn from these, until 
 they terminate in a straight line drawn parallel to a horizontal line through the point B, a clear idea can be 
 formed of the effect of the oscillation of the vertical arm A B. The lines terminate at J 1 K 1 L 1 M 1 N 1 O 1 . 
 It can ba easily seen that the horizontal movement of the point of attachment of the chain gradually becomes less 
 as the arm is oscillated from its mo3t backward position B C to its most forward one B H, this diminution 
 occurring most after the point L is reached. In the movement from J to K and K to L the horizontal traverse 
 is about equal. It shows a decrease from L to M, a greater one from M to N, and a still greater one from N to 
 O. The same thing happens if the chain be supposed to be attached at the point D. In this case also the 
 decrease in the horizontal forward traverse is variable, but occurs in the same Avay. The periods here are marked 
 by the letters C to H, and the extent of the forward motion by those C 1 to H 1 . It will be noticed that the 
 amount of the traverse is greater than that previously noted, the total space covered being respectively J 1 to O 1 
 and C 1 to H 1 . That is to say, the point at which the chain is fastened moves forward in the same direction as 
 
210 
 
 THE MULE. 
 
 the barrel, but at a different speed. In other words, when the chain is held at K, the total forward movement is 
 comparatively small, and if it were held at a point shown by the small inner circle, it would be still less. On the 
 other hand, its attachment at B implies a greater total forward movement. It therefore happens that the 
 retardation of the chain by the arm is less in the early part of the oscillation of A B— or, to put it differently, the 
 delivery of the winding chain by the arm is greater when it is fixed at D than when it is fixed at K. Therefore 
 the barrel is more slowly rotated during the same period in the former than in the latter case, but as it completes 
 its lateral movement it is rapidly and considerably accelerated. 
 
 (329) The application of this principle is as follows, and it can now be stated that the end of the chain 
 is attached to a nut which slides along the arm, being actuated by the rotation of a screw upon which it 
 fits. Remembering that an acceleration of the terminal velocity and a regulation of the revolution of the 
 spindle is required, the demonstration just given shows that these are obtained by the removal of the nut 
 further from the centre of oscillation. The influence of the pull of the chain upon the barrel when the nut 
 is in the position K is much slighter, and shows less variation than when it is at D. Every inch which the 
 nut travels outwards has an influence upon this factor, an! the conditions of winding are thus accurately 
 regulated. When the winding of the cop begins, the nut is in its lowest position, and the rotation of the 
 barrel is then practically equal. As the nut moves away from the centre the barrel gradually rotates more 
 slowly at the beginning of its inward movement. By the time the most outward position is reached — which, 
 in practice, coincides with the formation of the cop bottom — the variation in the velocity has reached its 
 greatest amount. This, it can be easily seen, is what is wanted. Referring again to Fig. 163, one revolution 
 of the spindle when the yarn is being wound on A D would practically take up the same length as would 
 be taken up at the top of the paper tube. But when the faller is guiding the yarn on the conical surface 
 from E to B, one revolution of the spindle would wind on a greater length at E than it would at B. 
 Therefore, the initial velocity requires to be less than the terminal. But when the point E has become the 
 initial position, the conditions of winding remain thereafter constant, except in so far as is affected by the 
 taper of the blade, and there is no further need for an outward movement of the nut. 
 
 (330) The theory underlying the method of winding having thus been dealt with, the mechanism 
 employed can be described. This is shown in Fig. 168, which is a diagram of the whole of the apparatus, and in 
 Fig. 169, which is an enlarged view of a portion of it. The winding arm M is centered at its lower end, 
 and has formed on it a toothed quadrant M 1 . The "quadrant" M oscillates on a short shaft, securely 
 carried by the headstock framing, and receives its forward movement by means of a pinion Z, which engages 
 with its teeth. The extent of the quadrant movement is about a quarter circle. The pinion Z is mounted 
 on the same centre as a grooved pulley, over which a cord from the back shaft H is passed. Thus the 
 rotation of H in either direction produces a similar movement in the pinion Z ; and the effect is, that, while 
 the back shaft is drawing the carriage out, the pinion is revolving so as to raise the arm M or cause it to 
 make a backward oscillation. When the back shaft acts as a taking-in shaft, as described in paragraph 315, 
 the pinion Z is revolved so as to move the arm M forward. The velocity at which the forward stroke is 
 
THE MULE. 
 
 211 
 
 made is by this arrangement a variable one, and completely corresponds to that of the carriage traverse. 
 Inside the winding arm a long slot is formed in which a screw P is placed, this being free to revolve. It 
 may be made with a thread of equal pitch throughout, but, as shown, is provided with a thread of varying 
 pitch, which gradually becomes finer towards the outward end of the arm. The reason of this is obvious. 
 The effect of each layer of yarn upon the problem of winding is greater at the beginning of the formation 
 of the cop bottom than when it is more nearly finished. That is, the enlargement of its diameter is relatively 
 
 A 
 
 Fig. 167. 
 
 greater at the first stage than at any other. For instance, if the diameter is f inch and it be increased 
 T \ inch, the ratio is |-th ; while if the diameter is £ inch, and the same increase takes place, the ratio 
 is T Vth only. The variation required in the speed of winding as each layer is wrapped is therefore less in 
 the latter than in the former case. This is the purpose of the helical screw, which gives a quicker advance 
 to the nut in the earlier stages of winding than when the cop bottom is nearly formed. 
 
212 
 
 THE MULE. 
 
 (331) The screw has fixed upon it, at its lower extremity, a small bevel pinion, gearing with a similar 
 one placed loosely on the short shaft forming the centre for the arm. During the oscillation of the arm 
 the pinion moves with it, and it is clear that if both remained in this position only this alternate action 
 would occur, and no rotation of the screw would be made. If, however, the pinion on the short shaft be 
 rotated it communicates its motion to the screw P, and thus traverses the nut. This is what takes place, 
 and the precise method of effecting it will be described in detail at a little later period. The nut engages 
 with the screw and originally had an eye or hook formed in it, to which the end of the winding chain or 
 
 band C was fastened. The attachment is now made in a different manner, a frame A being fixed to the 
 nut along with which it can slide. At the upper end of the frame a small drum is carried, round which 
 the winding chain is wrapped, passing over a small bowl D at the lower end of the frame. The other end 
 of the chain or band C is fastened to the drum or scroll X 1 which is mounted on a shaft X carried in 
 suitable bearings in the square. On the same shaft a spur wheel is geared which engages with a pinion 
 loose upon the tin roller shaft, which it revolves by special mechanism afterwards described in detail. The 
 use of a scroll is intended to accelerate the revolutions of the spindles during the latter part of the fallen 
 
THE MULE. 
 
 213 
 
 traverse. This, like the winding arm, is a modified application of the fusee, and it will be easily understood 
 that when the chain is being unwouud from the larger diameter of the scroll, the number of revolutions 
 given to the scroll will be less than when it is being taken off the smaller diameter. 
 
 (332) It has been previously shown that the diminishing diameter of the spindle causes it to be 
 necessary that, as the cop is built higher upon it, a correspondingly higher rotary velocity shall be given 
 to it, in addition to the increased terminal velocity produced in the manner described. The most usual 
 method of doing this has been to provide at the end of the quadrant arm a bracket carrying a pin known 
 as the "nosing peg.'' The object of this device is to shorten the chain by deflecting it from a straight line 
 about the time when the carriage nears the end of its inward run. This is equivalent to a sudden 
 shortening of the chain, and gives a sudden acceleration to the winding drum. In some cases an automatic 
 arrangement is fitted by which the peg is brought into contact with the chain at an earlier point every 
 stretch, so that the acceleration of the spindle takes place sooner, as the nose of the cop is formed higher 
 up the spindle. It is not difficult to obtain a clear notion of the action of the nose peg if a short length 
 of string be held at one end and attached to a sliding piece at the other. If then the string be pressed 
 down by a rod at the same point, but a little further every time, it will be seen that the sliding piece is moved 
 to a greater extent with each depression. 
 
 (333) The arrangement used in the Piatt mule is shown in detail in Fig. 169. It consists of the sliding 
 bracket A, carrying, as described, at its upper part, a small drum on which the winding chain C is fastened. 
 On the spindle of the winding drum a ratchet wheel E is fixed, with which the detent pawls E 1 engage, 
 thus ensuring that E is held in any position assumed by it. Also fastened on the spindle of the drum is 
 the curved sector arm F, to which a chain G is secured. By means of the guide pulleys shown the chain 
 G is conducted over the arm or lever K, and is attached to the bracket I. The lever K is hung from its 
 upper end, and has a projecting short arm K 1 attached to it, which can move upwards in the direction of the 
 arrow. The outer end of K 1 presses against a bracket K 2 attached to the quadrant, so shaped that the 
 backward movement of the quadrant pushes the lever K back at its lower end. In the bracket I a finger 
 I 1 engaging with the copping nut is fixed. The parts having been adjusted to their proper position the slide 
 A is at the bottom end of the quadrant M, as shown, and the curved arm F is in such a position that it 
 has wound upon it a certain length of the chain G. The latter is a little slack at first, but as the nut 
 moves out this is rapidly taken up until the chain G is in tension. As soon as this happens, each of the forward 
 oscillations of the arm M leads to the chain being drawn, and causes the lower end of the lever K to be 
 swung forward. The l'eturn movement of the quadrant leads to the bracket K a pressing upon the arm K 1 , 
 so as to push back the end of the arm or lever K. In this way the chain G is pulled and the curved arm 
 F is drawn a little forward, thus causing the drum and ratchet wheel E to revolve. As the winding chain 
 is wound on the barrel, every rotary movement of the latter in a forward direction takes up a little more 
 chain and shortens its length. The amount of this shortening is not great up to the time of the completion 
 of the cop bottom and the arrival of the slide A at the end of its traverse along the arm. The position of 
 
 p 
 
214 
 
 THE MULE. 
 
 the parts at this period is shown in the detached view at the right hand top corner of Fig. 169. Up to this 
 time only about the same length of chain is taken up which is needed by the increased distance of the slide 
 A from the centre, and the greater forward traverse of the quadrant arm, which, in a sense, releases a certain 
 length of winding chain. When this point is reached the finger I 1 begins to be pressed against by the nut 
 S 1 of the shaper screw, and the bracket I commences to be drawn inward. To facilitate the correct action 
 of this mechanism the finger I 1 is adjustable, and the exact moment of its contact with the nut S 1 is thus 
 regulated. The forward movement of the shaper nut which follows gives a similar motion to the bracket I, 
 and the chain G is thus drawn forward. In this way the drum and ratchet wheel E are rotated, and the 
 winding chain gradually shortened. Thus more of it is unwound from the scrolls at each traverse of the 
 carriage, and as it is drawn from the smaller diameter of the scroll towards the end of the run in, the velocity 
 of the spindles is considerably accelerated. The position of the various parts when the carriage is at the back 
 stops is shown in Figs. 170 and 171. 
 
 (334) These represent respectively the places occupied by the different portions of the mechanism 
 immediately at the completion of the cop bottom, and at the finish of building a set of cops. The positions 
 of the various parts connected with the slide A when winding is complete are shown also in Fig. 169, at the 
 top end of the quadrant arm. Referring to Fig. 170, it will be noticed that the winding chain C is unwound 
 from the large part of the scroll only, while Fig. 171 shows it almost entirely unwound from the smaller 
 portion. As was show r n, this implies a high terminal velocity of the winding scroll and spindles. 
 
 (335) It has been previously mentioned that the rotation of the quadrant screw is obtained by means 
 of the engagement of two bevel wheels, one on the foot of the screw and the other upon the spindle, forming 
 the centre of the quadrant. It was also stated that the last-named wheel was held so as to move round 
 the centre with the quadrant. This is effected by means of a brake spring P 2 which clips the boss of the 
 wheel and holds it. The resistance thus created causes the bevel wheel to move with the quadrant, and 
 prevents it from rotating on its axis. The wheel is compounded with a grooved cord pulley P 1 , over which 
 an endless band Q passes. The band Q fits the groove in the pulley, and is afterwards guided by the 
 various carrier pulleys shown. Two of these, S S 1 , are borne by brackets fixed to the carriage, and S is 
 formed with teeth so as to allow of the engagement of the vertical detent catch on the lever Y. If the 
 whole of the pulleys over which the band Q passes are free to revolve, except that on the quadrant centre, 
 the inward run of the carriage gives no motion to the cord or band. No effect is produced beyond the 
 rotation of the carrier pulleys, and the forward stroke of the quadrant is made without any effect being 
 produced upon the position of the nut. 
 
 (336) It was shown that the gradual accretion of yarn by the cop results in the necessity for a graduation 
 of the velocity of the spindle in winding. This takes place during the whole period of building, and it follows 
 that the traverse of the nut must be governed during the whole period. After a layer of yarn has been 
 wound the nut remains in the position occupied by it during the preceding inward run, until the carriage 
 has made another outward run, and is again commencing to run in. At the commencement of the run in 
 
THE MULE. 
 
 '215 
 
 of the carriage the spindles revolve at the same speed as that at which they rotated in the preceding period 
 of winding. If the yarn is a coarse one this is sure to be too fast, because of the increase in the diameter 
 of the cop, owing to the yarn wound during the last inward run. The initial velocity of the spindles is, 
 therefore, such that they take up the yarn too rapidly, and put an extra amount of tension upon it. 
 
 J -N 
 
 As was shown in paragraph 303, this causes a depression of the counter faller wire. This is utilised to revolve 
 the quadrant screw and traverse the nut and slide. In other words, the winding is said to be "governed," 
 and the motion is known as the " governing " or " strapping " motion. 
 
 (337) Fixed on the winding faller and counter faller shafts B B 1 (Fig. 168) are two arms U U 1 , to which the 
 ends of a light chain Y 1 are attached. The chain passes round a runner, or pulley, placed in the outer 
 
216 
 
 THE MULE. 
 
 end of the hinged lever Y, which is in this way sustained. It is obvious that the vertical position of the 
 lever will be strictly regulated by the position of the two arms U U 1 . As they follow the oscillations of 
 the winding and counter faller shafts, the elevated position of these during spinning ensures the lever Y being 
 , raised at its free end. This results in the tooth, or detent, being taken out of contact with the teeth on the 
 pulley S- When the. counter faller is depressed by reason of the tension of the yarn upon it a similar movement 
 occurs in the lever Y. 
 
 (338) In the early stages of winding, when the winding faller is depressed to a comparatively large extent 
 prior to being locked, the vertical position of the lever Y is naturally lower than when the winding faller 
 is not pushed down so far. It thus occurs that, when the cop bottom is being formed, which is the stage 
 during which the traverse of the nut is required, and the winding faller is locked at its lowest point, the 
 clearance of the detent catch on Y and the teeth on the pulley S is least. At this period, therefore, they 
 are most easily engaged by any depression of the counter faller. When the higher initial velocity of the spindle, 
 produced as described in paragraph 336, causes the yarn to be put into tension and the counter faller wire 
 depressed, an engagement of the catch and pulley teeth occurs. 
 
 J.N, J N 
 
 Figs. 170 and 171. 
 
 (339) The effect is that the rotation of the toothed pulley is stopped, and the band Q is practically 
 gripped by S and its fellow pulley S 1 , which are borne by the carriage. Instead, therefore, of slipping over 
 the pulleys as before, the band is drawn along with the carriage and j the remaining pulleys are caused to 
 revolve. The force so applied is sufficient to rotate the grooved pulley P 1 by overcoming the resistance of 
 the spring clip, and the bevel wheels and quadrant screw are rotated. The nut is thus moved outwards, 
 and the winding chain relieved as previously described. This causes a slight diminution in the speed of 
 winding, sufficient to relieve the pressure of the threads on the counter faller wire, which rises and breaks the 
 contact of the detent and the toothed pulley. The further movement of the nut is thus arrested. 
 
 (340) The necessity for a diminution of the initial velocity of the spindle is strictly relative to 
 the counts of yarn being spun. Some of the finer counts require a very slow traverse of the nut, and there 
 may be practically none during several draws of the carriage. As the nut slowly rises and the locking point 
 of the winding faller is elevated, the period of the engagement of the detent catch and the wheel S becomes 
 
THE MULE. 
 
 217 
 
 shorter, and the rotation of the screw is not so prolonged. When the cop bottom is fully formed, the nut 
 is at its most outward point, and the "governing" motion is not therefore required. At this point, the 
 relative positions of the arms U U 1 are such, that the chain Y 1 will not permit the lever Y to fall 
 sufficiently to allow its tooth to engage with the wheel. The motion, therefore, falls out of use until the 
 commencement of another set of cops. 
 
 (341) The motion of the winding scroll is communicated to the tin roller by means of a catch or 
 "click" plate shown in detail in Fig. 168. On the spindle of the winding scroll X 1 is a spur wheel — 
 indicated by dotted lines — which engages with a small pinion on the tin roller shaft T. The whole of this 
 special mechanism is shown in longitudinal section in the right hand top corner of Fig. 168. The pinion is 
 cast in one piece with the disc V which is loose upon the shaft T. The latter has a pin fixed in it, on 
 which the small catch or "click" V 1 is hinged. The click catch is ordinarily held out of position by the 
 bent spring W\ which surrounds the boss of a ratchet wheel T 1 — to which the name of the " click wheel " 
 is given. When the " click spring " W 1 is slightly oscillated in the same direction as the rotation of the 
 ratchet wheel, it allows the click catch to fall into gear with the click wheel. As the latter is keyed 
 Tipon the tin roller shaft T, the engagement with it of the catch causes the tin roller to be revolved, and 
 thus rotates the spindles. 
 
 (342) It was formerly the practice to allow the click catch to fall into gear when the disc V began to 
 rotate upon the commencement of the inward run of the carriage. It was, however, found that the click 
 catch engaged with the wheel earlier at one stretch than at another, and that, consequently, winding began 
 a little more slowly than it should. The effect of such an occurrence is that a little slack yarn was produced 
 as the carriage was running in, although winding was not taking place. Under these conditions tight winding 
 at the nose throughout ' was practically impossible. It will be easily understood that, when the click catch is 
 released, it may very readily be left either close to the tooth with which it has to engage or only just over 
 the point of the preceding tooth. In the first case the engagement would take place at once, while in the 
 second instance almost the distance of a tooth would have to be travelled by the click catch before engagement 
 occurred. In hard twisted yarns this is especially objectionable, and its prevention is of importance. 
 
 (343) To overcome the defect thus explained a hanging lever W is fitted on the tin roller shaft, and 
 the click spring W 1 , instead of fitting on the boss of the disc V, fits on the inner boss of the lever W, which 
 it clips. A slight oscillation of the lever is, therefore, at once followed by the movement of the spring, and 
 the click catch is engaged. The tail end of the lever W comes in contact with a stop R 1 on the holding-out 
 catch rod R. When R is moved in order to release the catch it causes the lever W to move into the 
 position shown by the dotted lines, and so oscillate the spring W 1 . The tail of the click spring passes 
 between a fork formed in the click catch, and thus presses the catch in either direction, according to which 
 side of the fork it gears with. When, therefore, the click spring is oscillated by the releasing movement of 
 the holding-out rod acting upon the lever W, the click catch is forced hard up to the tooth with which it is 
 engaging. The continued movement of the rod, if made, has, of course, no further effect upon the click catch, 
 
218 
 
 THE MULE. 
 
 but the parts are quite ready for winding with the click in gear. Immediately the carriage begins its inward 
 run winding commences. Thus, whatever may be the position of the click catch at the end of an outward 
 run, it is always ready for its work before the inward run commences. The weight of the rod W is 
 sufficient to keep the click catch disengaged during the whole period of spinning and backing-off. 
 
 (344) The whole of the points relating to winding having been considered, the motions used in the 
 fifth and last period require describing. When the carriage is near the completion of its inward run, the various 
 parts are in the following position : The strap is on the loose pulley and the backing-off side shaft is 
 being revolved either by the gearing named, or by its independent band; the back shaft clutch is disengaged 
 and the back shaft is revolving so as to aid in drawing up the carriage; the rollers are disengaged and are 
 not delivering roving ; the taking-in friction is engaged, and the scroll bands are drawing in the carriage ; 
 the quadrant arm is completing its forward movement, and the spindles are revolving in their normal 
 direction ; the winding faller is locked and the wire is approaching the nose of the cop ; and the counter 
 faller is in contact with and sustaining the threads. As soon as the carriage arrives at the roller beam, the 
 whole of these motions require changing, so that the different parts shall occupy the positions indicated in 
 paragraph 286. 
 
 (345) This operation is mainly the work of the cam shaft, but in part is performed by other mechanism. 
 As soon as the carriage arrives at, or near, the end of its outward run, the horn S 1 on the carriage comes 
 in contact with the anti-friction bowl R 1 in the long lever T and depresses it (see Fig. 156). This removes 
 the nose of the releasing lever from the raised surface on V and allows the friction clutch W X to come 
 into gear. The cam shaft immediately begins to rotate, and the three cams to act upon the various parts 
 in the reverse w r ay to that previously described. The rotation of the cam Z (Fig. 156) performs the two 
 functions of disengaging the taking-in friction clutch and engaging the back shaft clutch, the motions of 
 these always being closely related. The cam W during the same period allows the roller clutch to go 
 into gear, and the delivery of roving again begins. The rotation of the cam Y causes it to exercise a 
 thrust on the pin fixed in G (Fig. 158), so forcing the driving strap over on to the fast pulley, this giving 
 renewed motion to the spindles. The same movement causes the lever H to be pushed forward until 
 the shoulder formed in it can again engage with the fixed catch L, the spring P pulling the end of H 
 upwards as soon as it is sufficiently far forward. The strap guider is thus again locked when the strap is on 
 the fast pulley. By the time these engagements and disengagements have been made, the cam shaft M has 
 made its second half revolution, and the end of the release lever again presses upon the raised surface on 
 the cam V and detaches the friction cone W from X. The cam shaft is thus stopped and remains 
 stationary until the end of the outward run as described in paragraph 29 1. 
 
 (346) The whole of the parts governed by the cam shaft having thus resumed their original position, it 
 remains to be shown how the winding and counter fallers are released, so as to be able to assume their 
 relative positions out of contact with the yarn. The unlocking of the winding faller must be made as late 
 as possible in the inward run, but the exact period at which it is made is affected by the height of the cop nose 
 
THE MULE. 
 
 219 
 
 on the spindle. The termination of winding requires to be made throughout the whole period of building 
 a set of cops, at such a point as to leave sufficient yarn to coil on the spindles between their points and the 
 cop nose. It will be easily seen that this quantity is varying throughout the whole of the formation of the 
 cop, and that the length to be wound on is greatest at the commencement of the cop. This implies the 
 unlocking of the winding faller at a point which is made gradually later, and this is well carried out in the 
 Piatt mule. At the lower end of the locking lever is a curved arm or " boot leg," which, at the termination of the 
 inward run, comes in contact with the fixed stop bracket G (Fig. 161). The face of this is so shaped that 
 the moment of unlocking is regulated in accordance with the requirements of the case throughout the whole 
 of the formation of the cop. This is an important point, and requires careful attention. In a special form 
 of mule, made by Messrs. Piatt Brothers and Co., for finer counts, the stop bracket is a movable one, and is 
 released by the run of the carriage, so as to slide forward and unlock at the exact moment required. The 
 finer the yarns the more care is required in this respect, owing to their greater liability to breakage. 
 
 (347) Referring now to the release of the winding and counter fallers, it is essential that they should 
 leave the yarn free as soon as spinning begins. For this purpose the lever J is raised by contact with the 
 small roller W (Fig. 159), and its weight is removed from the counter faller shaft, and also from the winding 
 faller. Still further to facilitate the descent of the counter faller, which is sometimes a little sluggish, a 
 stop is placed in the headstock, which engages with a tail piece on the counter faller shaft when the carriage 
 has run in. This arrangement is shown in the dotted lines at the right hand top corner of Fig. 161. The 
 weight of the winding faller connections is, of course, sufficient to lift it quickly out of contact with 
 the yarn. 
 
 (348) The operations thus described constitute the fifth period, and at its termination the mechanism is 
 again engaged in the work of spinning or twisting, being at the commencement of another cycle of movements. 
 There is, however, one more piece of mechanism to refer to before the description of this machine can be brought 
 to a close. It was seen that during the period of winding the chain was drawn off the winding scroll during the 
 forward stroke of the quadrant arm. Referring to Fig. 172, which represents a portion of the mechanism 
 relating to the quadrant, it will be seen by the arrows that during the outward run of the carriage, the quadrant 
 M also makes its backward stroke. During the same period it is necessary to rewind on the winding scroll 
 the chain C which was previously unwound, and this is effected by the cord S. S is attached at one end 
 to a hook or staple T, fixed to the framing, and at its other end to a weighted lever U, pivoted on a bracket 
 fixed to the floor. The cord S, in its course, passes over the two pulleys shown fixed to the carriage, and 
 its tension is sufficient to cause the pulley on the shaft X to be rotated by the inward run of the carriage, 
 thus winding the chain C on to the scroll. By the termination of the outward run this operation is 
 concluded, and the chain is ready to act again efficiently as soon as winding recommences. When a " set " of 
 cops— that is, the whole number spun on a mule— is finished, it is "doffed" or stripped from the spindles. 
 As soon as this is completed the winding nut is wound back by hand to the bottom of the quadrant, and 
 the copping plates are also restored manually to their original position. 
 
220 
 
 THE MULE. 
 
 (349) The description thus given of the machine as made by Messrs. Piatt will enable an accurate idea to be 
 obtained of the mechanical movements which are found in the work of a mule. It is true that this special machine 
 differs iu some of its details from many of other makers, and that there are motions fitted to it which are not 
 found in other machines. When the latter are used, however, they tend to increase the automaticity of the 
 machine. The winding chain shortening, or, as it is more correctly called, the nosing motion, and the backing-off 
 chain tightening motion, are of this class, both tending to an increased efficiency. The main principles in a 
 machine of this class are embodied in the mule described, and the general explanations given will prove serviceable, 
 whatever may be the make of mule studied. 
 
 (350) One of the important points of difference between this and mules of other makes is found in the position 
 of the cam shaft. This, it was seen, is in the Piatt machine placed above the axis of the rim shaft. In other cases 
 it is placed, as shown diagramatically in Fig. 173, along the headstock of the mule, and below the centre of the long 
 or " balanced" lever T. In this case the cam shaft K is a tubular one, and has passed through its centre the shaft 
 M, which is suitably driven from one end. The cam shaft is fitted with a friction clutch at P, the fixed half being 
 on the tubular shaft. The other half slides on the shaft M, being pressed up to the fixed half by the spiral spring 
 
 Fig. 173. 
 
 shown. On the long lever T at the point L a pendant cam plate is hung, which surrounds the cam shaft as 
 shown in a detached front view and section in Figs. 174 and 175, and is formed with a slot so as to permit it to 
 rise and fall freely. The cam plate has two raised cam surfaces or courses, against which the end 
 of a pin is pressed by the action of the spiral spring. The pin passes through the half clutch 
 fixed on the cam shaft, and presses against the sliding half on the shaft M. Thus when the 
 pin is on the raised part of the cam plate the clutch is detached, while if it is on the lower 
 part the clutch is in gear. When, therefore, the inner end of the balanced lever T is depressed, the fall 
 of the pendant plate causes the pin to come upon the lower part of the cam course, and permits the engagement of 
 the clutch. The cam shaft thus makes a half circle turn, and effects the necessary changes for beginning spinning. 
 This causes the end of the pin to run on to the second cam course, and by the time the half revolution is made, 
 
THE MULE. 
 
 221 
 
 it comes on the raised surface and disengages the cam. In this position it rests until the outer end of the long 
 lever is depressed, when a similar action occurs, terminating in a similar way. 
 
 (351) The back shaft is also engaged and detached in a different manner. It is driven from the roller shaft 
 by a train of wheels, but the last of the train is a compound one, consisting of a large wheel with a smaller pinion. 
 The latter gears with the back shaft wheel, and is put into or out of gear accordingly, as it is desired to revolve or 
 
 Fig. 172. 
 
 stop the rotation of the back shaft. For this purpose the compound wheel is borne on a hinged lever, called 
 commonly the Mendoza lever, which is weighted in a suitable maimer. The exact origin of the word Mendoza, as 
 applied to this lever, is difficult to define, but it probably arises from the French phrase, main douce — Anglice, the 
 soft hand. However this may be, the function of the lever is to put the pinion into and out of gear with the 
 backing-off wheel, and to effect this, its motion is controlled by a cam or eccentric on the cam shaft. This cam 
 
 Fig. 174. Fig. 175. 
 
 works in a fork in a lever, and the rotation of the cam shaft raises or lowers the Mendoza. The object of the 
 weight is to ensure the full engagement of the pinion and back shaft wheel, so as to obviate any jumping out of 
 gear at the commencement of winding. There is some tendency towards this unsteadiness of driving in the early 
 part of the outward run, and it is desirable to lock the Mendoza lever in position. . 
 
222 
 
 THE MULE. 
 
 (352) Messrs. John Hetherington and Sons employ a special device by which this difficulty is overcome. 
 The mule, as made by them — arranged to be driven with the rim shaft transversely, instead of longitudinally, 
 placed in the headstock — is illustrated in Fig. 176 in longitudinal elevation, and in Fig. 177 in back view. 
 Both views show the method of driving quite clearly. On the outward end of the Mendoza weight a pin is 
 fixed which takes into a fork formed at the upper end of a vertical lever. The fork is shaped with a shoulder 
 or recess, below which the pin referred to can slip when desired to lock the Mendoza in position. A small ear is 
 formed on the vertical lever, through which a set screw is passed, the point of which comes in contact with 
 
 Fig. 176. 
 
 the end of a horizontal lever centred on a pin fixed in the headstock. The last named lever has a long 
 tail extending outwards toward the carriage. When the carriage comes up to the back stops and the Mendoza 
 lever falls, putting the driving pinion into gear with the back shaft wheel, the long tail of the horizontal 
 lever is raised, and the effect is that the pin in the Mendoza weight passes under the shoulder of the fork 
 in the vertical catch lever, and so firmly holds the Mendoza lever down. As the latter carries the driving 
 wheel, the pinion is kept firmly in gear, and the effective driving of the carriage is obtained. As soon as the 
 carriage has run out a little — by which time it has gained momentum — the horizontal lever is released, and 
 
THE MULE. 
 
 223 
 
 its long end falls, thus freeing the catch or pin in the Mendoza. Sometimes the minder, in cleaning, runs 
 out the carriage a little and then changes the cam, without freeing the horizontal or locking lever. If 
 afterwards the mule is started the carriage endeavours to run in, although the back shaft wheel aud its 
 driving pinion are in gear. This leads to breakages, and in order to avoid these, Messrs. Hetherington have 
 arranged a small relieving lever, coupled to the long lever, so that any motion of the latter causes the 
 
 Fig. 177. 
 
 relieving lever to act and free the Mendoza catch pin, without reference to the position of the horizontal 
 locking lever. This mule is arranged with the extra band for driving the taking-in side shaft D referred to 
 in paragraph 286. The band E is driven from the counter shaft R, and passes round a double grooved 
 pulley on D. It is kept in tension by the pulley F, carried by a frame which can be moved inwards by 
 the quadrant rack G with which a worm gears. The remaining reference letters indicate the same parts as 
 in the other illustrations. 
 
 (353) It was shown that to perfect the action of winding at the nose of the cop it is customary to deflect 
 the chain by means of a nose peg. A motion based upon the principle of the deflection of the chain, but 
 in which that object is attained in a different fashion, is shown in Fig. 178 in side elevation, and in Fig. 
 
224 
 
 THE MULE. 
 
 179 in enlarged detail. This is Dobson and Hardman's patent, and is made by Messrs. Dobson and Barlow. 
 Two main objects have been aimed at. These are the control of the winding from the faller — so that the 
 relation of the two will be strictly maintained — and the deflection of the chain by a pull from below instead 
 of a push from above. On the faller shaft a tappet is fixed,' to which is jointed a lever J with an arm or 
 finger K secured to it. A bracket H is attached to the quadrant arm a few inches from its centre, and its 
 outer edge H 1 is formed into a rack with which two catches engage. These are carried by a lever G, 
 which is hung on a pin in the upper part of the bracket H. G has a projecting shoulder at its outer end, 
 to which is fastened one end of the chain E passing over the pulley F, and having its other end attached to 
 the lower end of the link C- The winding chain B is also attached to the link C. The lever G is formed 
 with an arm G 1 , to which is jointed a double tumbler |, each part of which is free to move as required. 
 A projection is cast on |, which causes it to rest on G when in its normal position. This mechanism acts 
 
 J.N. 
 
 Fig. 178. 
 
 in the following manner : When a set of cops is begun the lever G is at its lowest position relatively to the 
 quadrant rack H l , and the winding chain B and link C are then almost straight. At the end of each stretch 
 the finger K comes into contact with the lower part of I, which is raised to allow K to pass. When the 
 inward run begins K causes the projection on I to press upon the lever G and raise it if the pressure is 
 maintained a sufficient time. Whether this is so or not is determined solely by the vertical position of J, 
 which, in turn, is regulated from the winding faller. If the latter is not substantially raised from stretch 
 to stretch the position of G in like manner remains unaltered. If this is not the case G is a little lifted, 
 and the chain E is thus drawn forward a little over the pulley F. The result is that a pull is exercised 
 on -the link C, which is drawn down so that it and the chain B no longer represent a straight line. This 
 is equivalent to shortening the chain B, and the result is that the necessary acceleration of the winding 
 
THE MULE. 
 
 225 
 
 drum is effected. The chief feature of this motion is the regulation which is obtained from the faller, the 
 position of which fixes the amount of extra pull put on the drum. However slowly the building proceeds the 
 necessary acceleration is made in exact proportion. 
 
 (354) In the description of the governing motion, given in paragraph 339, it was shown that the rotation 
 of the screw in the quadrant arm is made during the inward run of the carriage. There are some objections 
 made to this procedure on the ground of the extra tension put on the yarn in the early part of winding, 
 which is of some moment when fine or tender yarns are being spun. In Fig. 180 a side view is given of a 
 motion made by Messrs. Dobson and Barlow, which is designed to obviate the necessity for altering the 
 • screw during the inward run, and provide means by which it can be made during the outward run. In 
 
 Fig. 179. 
 
 lieu of the ordinary grooved pulley on the quadrant axis, a toothed wheel U is used, with which a toothed 
 rack R can engage under circumstances presently to be described. The rack R is carried by a sliding frame S, 
 which is fixed upon a longitudinal rod T, extending backwards in the headstock, and carried by brackets 
 fastened to the floor. The rack is fitted at one end with an inclined foot, and at the other with a spring, 
 which prevents too deep an engagement of the rack and wheel. The rack passes — during its outward stroke — 
 over a frame fastened to the headstock, in which is a screw X on which is threaded the sliding stop W. 
 The pitch of the screw thread is varied to correspond with the thread in the quadrant arm Q, and the screw 
 is rotated by a ratchet wheel, with which a pawl, oscillated by a finger, engages. At the point I a loose 
 tongue is hinged, which at the end of the stroke of the frame engages with the nut W- On the. winding faller 
 
226 
 
 THE MULE. 
 
 a sector Y is fixed, in which a stud, formed with two portions of different diameters, is bolted On the counter 
 faller a sector Z is fastened, carrying a screwed staple, to which is secured one end of a chain, indicated by dotted 
 lines. The chain passes round the bowl R at the upper end of the pendant lever O, guided in brackets at 
 the front of the carriage. The loose end of the chain is formed into a loop, which can be slipped on to either 
 of the surfaces of the bowl in the sector Y. A hinged finger L is carried by a bracket on the rod T, and 
 has a little range of movement in a circular direction. 
 
 (355) In beginning a set of cops the stop W is turned back to its proper position, which is determined 
 by the size of the cop about to be spun. The frame S is then pushed forward as much as possible, and 
 the chain is slipped on to the smaller portion of the bowl in Y. This allows the pendant O to fall a little, 
 and its height subsequently is regulated strictly by the position of the fallers. During the outward run the 
 horizontal arm P, which forms part of the pendant O, engages with the vertical projection on the frame S 
 and causes it to move forward. The rack R being raised engages with the wheel U and rotates it, this 
 movement being consequently communicated to the quadrant nut. Thus the latter is put into position for action 
 during the next period of winding and any straining of the yarn is avoided. As the stroke of the rack is 
 continued, the tongue I engages with the nut and causes the rack to drop out of gear with the pinion, and 
 any further movement of the quadrant nut is avoided. It has been shown that the traverse of the latter 
 is gradually diminished as the cop is built, and, in like manner, the inward motion of the stop W causes 
 the engagement of the rack and pinion to be limited. This is a sort of "trip" motion very familiar to 
 students of steam engine practice, and is well applied in this case. The slide S is drawn back into position 
 by the engagement of the lower end of the pendant O with the finger L. A slight contact at first between 
 these becomes a firm one by the backward movement of the finger when pressed upon by the pendant O, but 
 it will be obvious that, if the latter is too high to move the finger |_, the rack will remain untraversed 
 until a sufficient depression of O takes place. It only remains to be said that once the nut W has been 
 set at the beginning of winding, all that is required is for the minder to slip the loop of the chain on the 
 right portion of the bowl in Y, and the motion acts automatically until winding is finished. 
 
 (356) A somewhat similar attachment has been recently introduced in France, and is the invention of 
 Mons. Dubs. The author is informed by a trustworthy mechanician that the motion acts perfectly throughout 
 winding, and it may, therefore, be well to give a brief description of it. As in the motion of Messrs. Dobson 
 and Barlow, the regulation of the nut takes place during the outward run, and it is unnecessary to again 
 detail the reasons for this course. The chief operating part of the mechanism is the rack finger A— shown 
 in its position when in gear— which is hinged on a vertical rod or plunger K, sustained in a frame or bearing 
 S fastened to the carriage. Referring to Fig. 181, the whole of the apparatus moves with the carriage 
 and is self-contained. Attached to the faller is a connecting rod or link B, which is coupled to a hinged 
 lever O formed at its outer end with a toothed rack or quadrant finely pitched. With this rack, which 
 has two sets of stepped teeth, two detent catches H engage. The lever O is hinged to a plunger |_, 
 which has at its lower end a screwed shank fixed to a plate F also secured in the same manner to the 
 
THE MULE. 
 
 227 
 
 plunger K. The inner end of the rack lever A has a hanging piece D which can engage with a catch E 
 on the plate F, but which in the view is shown out of gear. The downward motion of the inner end of 
 A is regulated by the stop screw R, and it is coupled by the chain C to the counter faller. The spring M 
 constantly presses the inner end of A down, tending to raise the rack. When the various parts are adjusted 
 the parts F K and L move together and simultaneously with the lever O. 
 
 (357) The action of this mechanism is as follows : Assuming that the inward run of the carriage is nearing 
 completion, the lever G engages with a stop or bracket fixed to the floor, which causes D to fall out of gear 
 with the catch E. This leaves the plate F and all its connections to the control of the chain C and the 
 
 J.N 
 
 Fig. 180. 
 
 counter faller. When the faller locks it raises the rod B and the lever O, which is then held in position by the 
 detent catches H. During the first inward run O is lifted to its highest point, which, of course, affects all 
 the parts attached to it. Just before the end of each stretch the catches H are released, so that the whole 
 of the subsequent regulation depends on the counter faller. As the . locking point of the winding faller wire 
 is gradually raised the elevation of the fork at the upper end of K — which by reason of the connection of 
 the plate F with the lever O always takes place— occurs at a gradually lower point throughout building. 
 The effect is that when D is released, as described, an elevation of the rack A takes place if needed. If not, 
 D falls over the catch E as the carriage begins to run out and thus locks it, preventing the rack A from 
 
228 
 
 THE MULE. 
 
 rising. If, however, the tension on the yarn at the end of winding is such that the counter faller is depressed, 
 the catch D cannot recover its position. The end of the rack lever consequently falls on to the stop screw R, 
 and the rack is raised into contact with a wheel on the quadrant axis formed with teeth of a similar shape. 
 Thus the screw is given a turn while the carriage is running out, and the nut is in the correct position for 
 winding the next length. 
 
 (358) Quite recently Messrs. Curtis, Sons and Co. have constructed a mule in which the cam shaft, as 
 an instrument for making the " changes," is entirely done away with. A side elevation of the mechanism for 
 effecting this is shown in Fig. 182, and a plan of the same in Fig. 183. The back shaft clutch F is formed 
 so that its driving half slides, this being controlled by the action of a lever |_, connected, as shown, at two 
 points to the rods R M. The taking-in friction is placed horizontally, and is controlled by the vertical lever 
 H connected with the sliding rod R. The lever F\ by which the back shaft clutch is disengaged, is coupled 
 by the link going across the carriage— shown in Fig. 183 — to the roller clutch box, so that the engagement or 
 disengagement of the roller clutch box is simultaneous with the attachment or detachment of the roller gear. 
 The mechanism for actuating these parts is based upon the principle of the push and pull of spiral springs, 
 a partial application of which was shown in the case of the backing-off rod. On the axle of the quadrant a 
 short arm S is fixed, which is coupled with the rocking lever T, connected to the sliding boss on the rod M. 
 Two springs M 1 M 2 are threaded on the shaft, and are placed respectively between the sliding boss and 
 stop hoops fixed on the shaft. The rod M is coupled at the back to the lever L, the function of which is, 
 as indicated, to actuate the back shaft clutch. At the front end of the rod M a catch lever Q is fixed, 
 which detains it as the carriage is running out. When this happens, the spring M 1 is compressed 
 by the oscillation of the quadrant axle acting through the crank S and its connections, the other spring M 2 
 being then out of compression. As soon as the end of the outward run is reached a boss on the counter 
 faller shaft B 1 comes in contact with the underside of the catch lever Q and raises it, thus freeing the rod M. 
 The spring M 1 is thus free to extend, and, acting upon the lever |_, disengages the back shaft and roller 
 clutches. This accounts for one part of the changes ; and while it is taking place a catch lever O, which had 
 previously been raised, is lowered. When the inward run of the carriage is made by the operation of the 
 same parts the spring M 2 is compressed. On the arrival of the carriage at the roller beam the lever O is 
 tripped by a boss on the faller shaft B, allowing the spring M 2 to extend and re-engage the two clutches 
 named. 
 
 (359) The taking-in or scroll shaft is operated from the rod R, which is fitted with one spring only 
 at its back end. This is compressed by the intervention of a second lever, fastened on the same shaft on 
 which the rocking lever T oscillates, the compression taking place during the outward run of the carriage. 
 The spring is held in compression by a latch P, which engages with a lug on the rod R. When the carriage 
 runs in, a boss on the faller shaft releases the latch, and the extension of the spring disengages the taking-in 
 friction clutch. The latter is put into gear by the locking of the faller in the ordinary manner, and is 
 held in gear until the latches O and P are tripped in the manner described. The spring R presses on 
 
THE MULE. 229 
 
 a collar carried by the lever H, and the releasing of the friction is aided by the lever L, which 
 comes against the head of H when the spring M 2 is extended. The levers H and L are so arranged that 
 thty cannot both act together, so that the two motions of taking-in and drawing-out cannot be in action 
 at the same time. 
 
 (360) The angle of the spindle relatively to the vertical line is such as is necessary to suit the material 
 being spun, but there is another feature which it is necessary to mention. As the point of the spindle moves 
 
 i-qo. 181. 
 
 in a horizontal plane, it is obvious that the yarn will pass on to it from the rollers at an angle varying with 
 its distance from them. That is to say, the angle formed by the yarn, in passing on to the spindle, will 
 be more acute when the carriage is near to the rollers than it will be when it is further away. This has a little 
 influence upon the problem of spinning, and an arrangement exhibited at the Manchester Jubilee Exhibition, 
 applied to Messrs. Asa Lees and Co.'s mule, is shown in Fig. 184. In this case there are two carriage slips 
 instead of only one, and these are inclined so as to compensate for the difference in angle. On one of the 
 
 Q 
 
230 
 
 THE MULE. 
 
 slips A the front carriage runuer D travels, and on the other the back one C. The result is that the 
 inclination of the spindles is slowly altered, with the result that the angle formed by the yarn and the 
 spindle in each case, is nearly the same in all positions. This device worked well, but the difficulty existing 
 does not appear to be great enough to lead to any wide adoption of it. 
 
 (361) Having thus described in detail the construction and principles of the mule, it is only necessary 
 to say a few words on the subject of its application to the spinning of the finer counts, which require specially 
 
 r i 
 
 Figs. 182 and 183. 
 
 delicate treatment. It is found necessary to fit a few special attachments which are supplementary to the 
 ordinary mechanism employed. In dealing with fine yarns the rollers are stopped a little before the carriage 
 has completed its outward run, and this results in the yarn being a little stretched. A more important 
 result, however, is that if there be any unevenness in the diameter of the yarn, the twist speedily runs into 
 the thin places, which become hardened, and do not easily elongate or draw. The thicker places remaining 
 untwisted are, therefore, drawn down until the full twist runs into them also. This supplementary twisting 
 
THE MULE. 
 
 231 
 
 and drawing is called "jacking," and its amount varies, of course, with the staple of the cotton being spun, 
 the further movement of the carriage being sometimes as much as five inches. In order to permit the jacking to be 
 effective, it is the custom to put into the yarn very little twist before the roller delivery ceases, after which it is 
 rapidly introduced. This tends to shorten the yarn and puts it in such a state of tension, that unless relieved, it 
 would break. There are two methods of obviating this difficulty. The first is to move the carriage in a little 
 during the period of twisting, and the other to cause the rollers to deliver a short length of yarn. The latter is 
 now the most usual method, and by the adoption of a special engaging motion, the amount delivered can be 
 regulated at will. When long stapled cotton is being spun, it is the practice to cause the rollers to deliver a little 
 yarn during the inward run, while winding is going on. The amount varies, but is about three inches, 
 so that only 60 inches is wound on the spindle during each inward run. Messrs. Piatt Brothers and Co. 
 make a very good fine spinning mule with a number of well thought out motions of great ingenuity, a full 
 description of which will be found in the Proceedings of the Institution of Mechanical Engineers, 1880, pages 
 516 to 527. 
 
 (362) Mr. Richard Threlfall of Bolton has devoted himself to the construction of fine spinning mules, 
 and has produced a self-acting machine, which is capable of spinning the highest counts. With a brief 
 description of it as made by him, the present treatment of this machine must be closed. In the 
 Threlfall mule the roller delivery after jacking is effected by a short shaft on which is a catch box, the 
 outer surface of which constitutes a cam course, which is revolved from the twist shaft. On this cam shaft 
 is the first of a train of wheels, which gear up to the roller, and the first wheel has motion given to it by 
 a ratchet and pawl, the movement of the latter being controlled by the throw of the cam. The cam can be 
 set so as to give a whole turn to the rollers, or only one flute, and by means of changes in the train of 
 wheels further regulation can be made. The copping rail is specially constructed, so as to enable short cops 
 of any shape to be easily built. The fallers are arranged so as to be very sensitive in action. The action 
 of the quadrant is aided by a special contrivance consisting of a narrow pulley placed alongside the loose 
 
232 
 
 THE MULE. 
 
 backing-off pulley, but fast on the shaft. Connected to the strap guide is a lever which is coupled to a rod 
 suitably carried in brackets, and on which is a regulating screw and nut. This regulation is provided so that 
 the passage of the strap on to the narrow pulley is effected as desired. The strap is prevented from traversing 
 from the loose pulley by a catch, and the release of the latter is effected by a finger on a bracket fastened 
 to the carriage square. When the latter runs in the finger pushes over a tumbler holding the catch in position 
 and releases the latter. The weight of the parts then throws the strap over on to the fast narrow pulley, and 
 the winding is thus accelerated. By fixing the finger and setting the adjusting screw, this motion may be 
 brought into play at any desired moment. On the faller shaft is a bracket, to the outer edge of which is 
 attached by a bolt or screw a grooved cam surface. To this is attached a cord actuated by the governor 
 motion. By suitably setting the cam, winding is effected during each inward run with equal tension. A 
 brake is applied to the faller shaft, consisting of a lever fastened to the carriage, one end of which engages 
 with an inclined plane, and the other end has a cord attached passing over a pulley on the faller shaft. By 
 tightening the band the faller is held perfectly steady. The combination of the last three motions effectually 
 prevents snarls. A roller delivery motion is added, and the most perfect adjustment of the whole of the 
 movements is provided. The spindles revolve at two speeds, the final or twisting velocity being about 8,000 
 revolutions per minute. 
 
 (363) Such is a description of the most intricate machine in the whole range of textile mechanics, which, 
 although threatened more than once with extinction, is yet more largely used to-day than at any previous 
 time. On it yarn of varying qualities can be spun, either soft or hard twisted. The yarn which is used for 
 warp purposes is more commonly known as twist, and that employed for weft is known by that name. Weft 
 yarn, as will be shown at the end of the next chapter, is always more softly twisted than warp 
 yarn, and the mule spindles revolve in the opposite direction to that employed when the latter is spun. 
 About the question of twists and the system of the arrangement of draughts throughout the whole process of 
 spinning, a few words will be said in concluding the next chapter. 
 
 (364) The mule is used in a modified form to produce " doubled" warps— that is, two strands of yarn 
 twisted together. When so employed, the machine is known as a "twiner," and is constructed with a low 
 creel. With the necessary alterations to suit the circumstances peculiar to the case, the machine is largely 
 employed in certain districts. In its main features, however, it resembles the mule, and does not require a 
 detailed description. Another modified form is used for spinning yarns made from waste, being nearly identical 
 with the machine as employed in spinning fine worsted yarns. The student who is interested in this subject 
 will find a description of the woollen mule in "Spinning Woollen and Worsted," by Mr. W. S. Bright 
 M'Laren, M.A 
 
 (365) A table is appended of actual productions from Messrs. John Hetherington and Sons' mule. These 
 are given from 74 machines for the ordinary working week of 56| hours. A great variety of counts are 
 iucluded, all of which were being spuu at the same time. An additional table is given of productions from Messrs. 
 Piatt Brothers and Co.'s mule. An explanation of the value of the hank is appended to the next chapter. 
 
THE MULE. 
 
 233 
 
 Table 2. 
 
 ACTUAL PRODUCTIONS IN A WORKING WEEK OF 56£ HOURS, FROM 
 MESSRS. JOHN HETHERINGTON AND SON'S MULES. 
 
 No. of 
 Mule. 
 
 Hanks. 
 
 Counts. 
 
 Hanks per 
 Spindle. 
 
 No. of 
 Mule. 
 
 ET;ui1ck. 
 
 Counts. 
 
 Hanks per 
 Spindle. 
 
 2 
 
 77,250 
 
 39 
 
 3114 
 
 40 
 
 62,000 
 
 38 
 
 30 21 
 
 4 
 
 70,750 
 
 43 
 
 28:52 
 
 42 
 
 58,500 
 
 38 
 
 28-50 
 
 6 
 
 71,000 
 
 43 
 
 28'62 
 
 44 
 
 62,750 
 
 36 
 
 30-57 
 
 8 
 
 75,500 
 
 41 
 
 30-44 
 
 46 
 
 62,250 
 
 38 
 
 30-33 
 
 10 
 
 65,750 
 
 32 
 
 32-42 
 
 48 
 
 63,250 
 
 36 
 
 30-82 
 
 12 
 
 68,750 
 
 28 
 
 33-90 
 
 50 
 
 60,250 
 
 00 CO 
 CO CO 
 
 29-35 
 
 14 
 
 61,750 
 
 36 
 
 3044 
 
 
 16 
 
 71,750 
 
 45 
 
 28-73 
 
 52 
 
 64,750 
 
 34 
 
 31-55 
 
 18 
 
 69,750 
 
 45 
 
 27-94 
 
 54 
 
 65,750 
 
 36 
 
 32 03 
 
 20 
 
 72,250 
 
 45 
 
 28-94 
 
 56 
 
 65,000 
 
 40 
 
 30-52 
 
 22 
 
 71,750 
 
 45 
 
 28-73 
 
 58 
 
 61,750 
 
 40 
 
 29-91 
 
 24 
 
 71,000 
 
 45 
 
 28-43 
 
 60 
 
 61,000 
 
 42 
 
 29-55 
 
 26 
 
 71,250 
 
 45 
 
 28-53 
 
 62 
 
 60,000 
 
 42 
 
 29 06 
 
 28 
 
 71,250 
 
 45 
 
 28-53 
 
 64 
 
 63,000 
 
 40 
 
 30-52 
 
 30 
 
 72,250 
 
 45 
 
 28 93 
 
 66 
 
 61,500 
 
 40 
 
 29-79 
 
 32 
 
 73,000 
 
 42 
 
 29-23 
 
 68 
 
 61,500 
 
 42 
 
 29-79 
 
 34 
 
 72,500 
 
 42 
 
 29-03 
 
 70 
 
 61,250 
 
 42 
 
 29-67 
 
 36 
 
 61,500 
 
 36 
 
 29-97 
 
 72 
 
 59,750 
 
 42 
 
 ; ' 28-94 
 
 38 
 
 66,750 
 
 32 
 
 3252 
 
 74 
 
 65,750 
 
 40 
 
 31-85 
 
 1 
 
 Total Weight, 59,9204 lbs. Average Counts, 39 53. Average Hanks per Spindle, 
 
 Table 3. 
 
 ACTUAL PRODUCTIONS IN A WEEK OF 56* HOURS OF TWIST AND WEFT YARNS FROM 
 
 MESSRS. PLATT BROTHERS AND CO'S. MULES. 
 
 TWIST. 
 
 No. of Spindles in each 
 Mule. 
 
 Counts spun. 
 
 Hanks per 
 Spindle. 
 
 1044 
 
 30's 
 
 32 
 
 » 
 
 32's 
 
 31-5 
 
 » 
 
 33's 
 
 30-65 
 
 j> 
 
 34's 
 
 30 
 
 V 
 
 50's 
 
 28 
 
 >! 
 
 54's 
 
 27 
 
 WEFT. 
 
 No. of Spindles in each 
 Mule. 
 
 1280 
 
 Counts spun. 
 
 Hanks per 
 Spindle. 
 
 28's 
 
 33-81 
 
 29's 
 
 34 
 
 34's 
 
 3185 
 
 36's 
 
 31 
 
 38's 
 
 30-46 
 
 40's 
 
 30 
 
 46's 
 
 29 
 
 Note.— The production of any mule varies of course with the class of cotton used, the 
 amount of twist required, and the length of mules ; but the figures given in the tables are, in 
 each case, figures of actual productions. 
 
CHAPTER XII. 
 
 THE RING SPINNING MACHINE. 
 
 (366) The term Ring Spinning is applied to that process by which yarn is spun by means of a machine 
 in which a spindle, revolving in the centre of an annular ring, is used. The ring is formed with a flange 
 or bead over which a C shaped clip or " traveller " is sprung, being drawn round the ring by the yarn during 
 the revolution of the spindle. It is from the use of such a "ring" that the system has been named. The 
 difference between mule and ring spinning is mainly that between continuous and intermittent work. The 
 ring frame is the successor of the throstle, as it was called, in which the twisting was conducted by the aid 
 of a two-armed flyer, formed with a curl at the end of each arm, through one of which the yarn passed on 
 its way to the bobbin. The flyer was fixed on the end of a vertical spindle, and the bobbin was super- 
 imposed on it, resting on a rail having a reciprocal traverse, flannel washers being placed between the flange 
 of the bobbin and the rail to give the necessary drag to the bobbin. Generally, the principle of the throstle 
 is similar to that of the roving frame, when allowance is made for the fact that the bobbin is not positively 
 driven. As it is not now in extensive use it is unnecessary to describe it in further detail, but its general 
 construction can be easily understood if a spindle and flyer be substituted for the spindle and ring in the 
 succeeding description. 
 
 (367) Referring now to Figs. 185, 186, and 187, the mechanism will be easily understood, and, as described, 
 is common to most machines made at present, the illustrations being those of the machine as made by Mr. 
 Samuel Brooks. Fig. 185 is a front, Fig. 186 an end view, and Fig. 187 a transverse section of the machine. 
 A detached and enlarged view of one spindle and its necessary roller stand and lifting mechanism is given 
 in Fig. 188. The roving bobbins B are placed in a two-height creel, and are conducted to the three 
 lines of rollers carried by the stand A. From the front roller the roving passes through the wire eye E, 
 fixed in a wooden board known as the " thread board," to the ring F, which is held by a suitable clip on 
 a rail extending the length of the frame, and known as the " ring rail." The thread boards are hinged, and 
 can be simultaneously thrown up by the levers I and their connecting rods, which are worked from the end 
 of the frame. The spindle C is, as shown, self-contained, and is fastened into the " spindle rail " G by a nut. 
 The top rollers are weighted by a stirrup, lever H, and weight M, ordinarily but not invariably. The spindles 
 are driven by bands from the tin rollers in the centre of the machine, and the cop or spool is built by the 
 reciprocal traverse vertically of the ring rail. The ring is approximately of the section shown in Fig. 188, 
 and has slipped on to it the traveller. Without stopping to inquire at present the precise action of the 
 latter, it is sufficient to say that the yam is passed through the traveller on its way to the bobbin, and it is 
 
THE EING SPINNING MACHINE. 
 
 235 
 
 evident that as the ring is raised or lowered the yarn will be wound on the corresponding portion of the spindle. 
 Specially referring now to Fig. 186, the vertical reciprocal motion of the rail G is obtained from the cam E, which 
 is keyed on the same shaft as the wheel D, driven by the worm A, which derives its motion from the main shaft. 
 Each revolution of E depresses the lever in contact with it, the weight of the ring rails and their attachments 
 
 J.N. 
 
 Fig. 180. 
 
 keeping the cam and lever in contact. The chain attached to the axis of the wheel D is thus unwound from 
 a pulley, which being fixed on a longitudinal shaft causes the latter to rotate. On the shaft small pulleys 
 H are keyed, to which the ends of chains, the other ends of which are attached to the lower ends of 
 vertical rods or "pokers" sustaining the ring rail, are fastened. It is a common practice, instead of using 
 
236 
 
 THE RING SPINNING MACHINE. 
 
 this chain arrangement, to key levers on the shaft, the free ends of which come linger the feet of the pokers. 
 An arrangement of this character is shown in Fig. 202. The rotation of the shaft obtained in the manner 
 described raises the ring rail, the descent beiug obtained by gravity, but is regulated as to speed by the 
 shape of the cam E. As this reciprocal movement is only about If to 2 inches, while the length of the cop 
 
 Si 
 
 J.N. 
 
 Fig. 187. 
 
 or spool spun is five or six inches, it will be seen that the ring rail must be slowly raised and a fresh starting 
 point at each lift of the rail be obtained. This is effected by means of a ratchet motion automatically operated 
 by the rise and fall of the lever. The rotation of the ratchet wheel is communicated through a train of 
 gearing' to the wheel |, and the chain connecting | and H is thus wound on to the former and from the 
 latter. In this way a limited rotation of the shaft to which H is attached is effected, and the lift of the 
 
THE RING SPINNING MACHINE. 
 
 237 
 
THE RING SPINNING MACHINE. 
 
 239 
 
 pokers commences gradually at a higher point. This elevation of the ring rail is of course a very slow one, 
 but it is always taking place, and the result is that a thoroughly well built cop is obtained. 
 
 (368) The history of the ring frame is interesting, and keeping in mind the fact that a stationary 
 annular ring is an essential feature of a machine of this description, no earlier date than 1828 can be 
 assigned to it. In that year a patent was granted in the United States to one J. Thorp, who invented a 
 ring somewhat resembling that in Fig. 201. The ring was in two pieces, and a groove was thus formed in 
 which a solid hoop was placed. The yarn was conducted between the two rings, and was drawn round the 
 periphery of the hoop by the pull of the spindle. In the next year a patent was taken out in the United 
 States by Messrs. Addison and Stevens, in which the first mention is made of a traveller. The first patent 
 taken out in this country was by Messrs. Sharp and Roberts in 1834, the next by C. de Bergue in 1836, 
 and after that by J. G. Bodmer in 1837. In 1847 Messrs. John Piatt and Thomas Palmer took out letters 
 patent for spinning cops on a spindle similar to a mule spindle by the aid of a ring and traveller, 
 a task which is not even yet accomplished. After this date nothing was done in this direction for some 
 time, and inventors in this country appear to have dropped the subject, while in America it received much 
 greater attention, and was finally brought to a successful conclusion there. 
 
 (369) In the year 1866 Messrs. J. and P. Coats and Messrs. Clark and Co., both of Paisley, and both 
 having mills in America, introduced into this country short sample ring frames for the purpose of twisting 
 sewing cottons, and in February 1867, Messrs. J. and P. Coats ordered from Messrs. P. and J. McGregor, 
 of this city, eight sample frames of 238 spindles, each for doubling purposes. In May of the same year 
 Messrs. Clark ordered from the same firm a sample frame, and during that and immediately succeeding years 
 many repeat orders were executed by Messrs. McGregor. Messrs. Win. Higgins and Sons, of Salford, also 
 made machines on the American pattern for the same firms, and for the United States. In June, 1867, 
 Messrs. McGregor made for Messrs. Knowles, of Burnley, a ring spinning frame, all those previously referred 
 to being for doubling, and in October, 1869, they made for Messrs. John Dugdale and Bros., of Lowerhouse, 
 near Burnley, fourteen frames of 364 spindles each. The author is not aware of any earlier actual use in 
 this country on a large scale of ring frames either for spinning or doubling. At the latter end of 1872 
 Mr. James Blakey, a representative of Mr. Samuel Brooks, paid a visit to the United States, and there 
 investigated closely the use which was being made of the machine. It is extremely probable that shortly 
 before this time accuracy of workmanship was being better attained in the manufacture of these frames, and 
 at any rate the renaissance of this as a spinning machine began about 1866. Mr. Blakey very fully studied 
 the machine in its original home, and he became so imbued with a belief in its possibilities that he advocated 
 its modern use with great earnestness to Mr. Brooks, who, being convinced of the future success of the machine, 
 began its manufacture with considerable energy, and soon established a large business in it for doubling 
 sewing threads. It was not however until the difficulties arising from the use of the ordinary spindle were 
 overcome that the machine became unequivocally successful. This special point need not now be enlarged on, 
 as it will subsequently be dealt with in detail, It is worth noting, however, that the first extensive use 
 made of these frames was for doubling and not for spinning. 
 
240 
 
 THE RING SPINNING MACHINE. 
 
 (370) The general description and history of the machine just given will convey a fairly accurate idea 
 of its development, and the details of the machine can now be dealt with. The drawing rollers being common 
 to all spinning machines no further description than that given need be furnished ; but a reference to Fig. 
 188 will show that the roller stands, the thread board mechanism, and the relation of the spindle and ring 
 are the chief points requiring explanation. It will be convenient, therefore, to consider these details in their 
 order, and afterwards to deal with a few special points arising. As will be noticed, the roller brackets A 
 are formed so that a line drawn through the axes of the rollers is at an angle with the horizontal. This 
 has been found to be absolutely essential in order to obtain good work, and for this reason. It has been 
 noted, and is well known, that the number of turns per inch put into the yarn depends on the relative 
 speed of delivery of the rollers, and the revolution of the spindle. Now, in order to ensure that the twist 
 shall be put in the entire length of yarn from the spindle to the rollers, it is essential that no portion of 
 it shall be held in any way by any part of the mechanism, but should be quite free to receive the twist 
 from the spindle to the nip of the front rollers. But if the rollers were in a horizontal plane, a certain 
 portion of the yarn would be pressed against the bottom roller for about a fifth of its circumference. 
 This is detrimental, because the twist cannot run up to the nip of the rollers, but is remedied by giving 
 the roller stand the inclination referred to. In a lesser degree the same evil arises if the yarn passes 
 through the wire eye E in the thread board at too acute an angle. To obviate this, it is now the practice 
 to adjust the brackets A so that the nip of the front rollers is almost vertical to the spindle. The amount 
 of the inclination of the roller stand varies according to the class of yarn to be spun, and whether the 
 rollers are self-weighted or are pressed downwards by saddle and weights. If, for instance, weft is being 
 spun, the number of turns per inch being less in this way than in warp or twist, and the yarn being 
 correspondingly softer, the inclination is about 35°, while in the case of twist it will vary from 25° to 35°. 
 Different makers alter this inclination to suit different requirements, and there are variations existing in it 
 from 5° to 35°, but the angles given are usual ones. The thread boards are arranged, as described, to be 
 lifted simultaneously by means of a lever, this being necessary when the frame is being doffed or stripped 
 of its bobbins when the latter are full, the doffer being thus enabled to give a straight lift to the bobbin 
 and avoid any straining of the spindles. 
 
 (371) The chief feature is, however, the relation of the spindle and ring to each other, and their special 
 construction. It is essential that the spindle should be so fixed in its sustaining rail as to be truly vertical, and 
 when its construction is dealt with it will be seen how perfectly this is obtained. The ring must be attached to 
 the ring rail so as to be absolutely concentric with the spindle, and on the actually efficient performance of this 
 duty depends very largely the success of the machine. Bearing these two points in mind, it will be convenient to 
 deal first of all with the special construction of the spindle. As would naturally be expected, the first form used 
 for this purpose resembled a throstle spindle without the flyer, or a mule spindle, but eventually the shape adopted 
 generally was that which is shown in Fig. 189, the bobbin being also very light. A good many modifications took 
 place, but in every case the bobbin was pressed on to the spindle above the top bearing or bolster. In 1870, 
 
THE RING SPINNING MACHINE. 
 
 241 
 
 however, Mr. J. H. Sawyer, of Lowell, Mass., patented the spindle bearing his name, and which was introduced into 
 this country under the name of the "Booth-Sawyer." The main principle of this form was the provision of a 
 means by which the top bearing was carried up inside the bobbin B, thus sustaining it at a higher point than had 
 been before possible. Referring to Fig. 190 the bolster A is formed as a hollow tube extending upwards from the 
 rail, and having at the upper end a phosphor bronze bush, which acts as the bearing. A spiral groove is formed 
 in the bolster by means of which the oil, being fed at C and held in the chamber D, is carried upwards so as 
 effectually to lubricate the spindle. Special provision is made for the footstep, and both bolster and footstep are 
 supplied with covers. The Booth-Sawyer spindle is beyond doubt an efficient one, and constituted a very great 
 advance on those previously used. The position of the top bearing was higher than in any previous form, and it 
 does not require any long comment to demonstrate the value of this improvement. It must be noticed, however, 
 that it is necessary to oil every day, and that there are two bearings which are fixed in rails quite independently of 
 each other. In spite of these defects, however, the Booth-Sawyer spindle has done, and is doing, excellent service 
 in this country and elsewhere, and so far as output is concerned, is quite equal to any other spindle in the market. 
 
 (372) As has been previously stated, the most essential point in the successful construction of a ring frame is 
 the preservation of the exact concentricity of the spindle and ring. If this is destroyed a very detrimental effect is 
 produced, and it does not need to be pointed out that where there are two bearings to a spindle each of which 
 is attached to a different rail, the difficulty of preserving a correct vertical alignment is very great. For these 
 reasons the introduction of the Rabbeth spindle into this country by Messrs. Howard and Bullough about the year 
 1874 led to its wide adoption, and the practical supercession of the Sawyer, and gave a great impetus to this 
 system of spinning. The principle of the Rabbeth is that of the Sawyer so far as the position of the upper bearing 
 is concerned, but it has the further merit of being entirely self-contained. The latter feature was not new in the 
 annals of British invention, but it was never thoroughly worked out nor made a success in this country until the 
 firm just named took up the Rabbeth spindle. Students who desire to take up the history of this subject, can 
 refer to a patent granted to William Wright in 1836, and also to one obtained by David Cheetham in 1857. The 
 Rabbeth is entirely self-contained, its construction being that illustrated in section in Fig. 191. The spindle B 
 revolves in a case or bolster C made of cast iron, which acts as a bearing for the spindle both at its upper and 
 lower portions. The bolster is formed with a flange, as shown, and is accurately turned and bored all over. It 
 has its shank screwed with a fine thread, so that when passed through the hole in the spindle rail, it can be firmly 
 fixed in position by the nut shown. As the underside of the flange is quite square with the hole in the bolster, it 
 follows that the spindle rail being planed on the top, the bolster case C will be in a perfectly vertical position. 
 The spindle B is borne by a bronze bush at C, and by the footstep at F, the case being recessed so as to form a 
 chamber containing such a quantity of oil that the necessity for lubrication more than once in six months is 
 obviated. Fitting on the spindle is a sleeve with a warve or grooved pulley at its lower end as shown at E, the 
 sleeve being bored with a conical hole and being tightly pressed on the spindle. The driving band passes round 
 the warve and thus rotates the sleeve and consequently the spindle. A brass cup D is placed on the lower part of 
 the sleeve, into which the foot of the bobbin is pushed, the upper part fitting the spindle as shown at A. In this 
 
242 
 
 THE RING SPINNING MACHINE. 
 
 way the bobbin is positively driven, and the pull of the band being low down, the spindle can be run at a high 
 speed with great steadiness. The sleeve is prevented from lifting by the hook G, which is carried in a small 
 specially balanced frame suitably pivoted so as to allow of the sleeve being removed easily when required. This 
 device is a patented one of Messrs. Howard and Bullough's, and is one of the best for the purpose. Various 
 modifications of the Rabbeth E-pindle have been made, including the Dobson-Marsh, which provides for a readier 
 means of oiling by taking off a cap at the lower end of the spindle and thus allowing the dirty oil to run away, this 
 necessitating pumping out in the Eabbeth. In all essential features the Eabbeth may be taken as the best type of 
 self-contained spindle, in which the spindle proper is sustained by rigid bearings, and one of its chief merits is that 
 it can be readily adjusted so as to be quite true with the ring. As a matter of fact this was practically the only 
 advance noticeable in the Rabbeth over its predecessors, and was not perceived even by its inventor until after 
 spindles made under his first patent had been working some time. 
 
 (373) During the past few years, however, a new type has been introduced, of which there are now 
 several examples, and which is rapidly superseding all others. Everyone is aware of the tendency of a 
 rapidly revolving body, such as a humming top a little out of balance, to assume such a position that its 
 axis is out of the perpendicular while its revolution is going on with absolute steadiness. The high rate of 
 speed which is attained with ring spindles, running up to 11,000 revolutions per minute, produced as might 
 be expected, a certain amount of vibration which it is desirable to avoid. Consequently, a spindle was 
 produced in America to which the designation of the "top" or "elastic" spindle was given, and which was, while 
 held in a long bearing at the top of the bolster, free to move at its foot until it found its position of steadiness. 
 It was found, however, that the changes of position when the balance was disturbed were so abrupt that it 
 was necessary to restrain the movement to a certain extent. 
 
 (374) In Fig. 192 a spindle known as the " Whitin Gravity" is illustrated, being made in this country 
 by Mr. Wm. Ryder, of Bolton. The spindle B has fitted on to it the sleeve A, made shorter than usual. 
 On A the warve is formed, as well as a conical shoulder on which the lower end of the bobbin fits tightly. 
 The bolster C has the usual screwed shank, and passes upward into the sleeve. A noticeable feature of the 
 Whitin is the employment of a loose sleeve in which the spindle fits, and which has an external diameter 
 at the point D about inch less than the internal diameter of the bolster at that point. The lower part 
 of the sleeve is recessed so as to pass over a nipple G formed in the bolster, the size of the sleeve being 
 such as to allow of its adjustment in any direction. Ou the top of the nipple G a small pad of cork F is 
 placed, the object of which is to limit by its friction the movement of the sleeve and spindle, and also to 
 absorb vibration. The bolster is recessed so as to form a cavity surrounding the tube D, in which the 
 oil is placed, finding its way to the spindle by means of small holes bored in D. The spindle does not, 
 therefore, as in the Rabbeth, revolve in oil, and any sediment which may be in the latter is allowed to settle 
 in a cavity or recess at the foot H. The Whitin can be run without any difficulty at very high speeds. 
 Another spindle in which this principle is used has been largely adopted, and is known as the " Ferguslie." 
 The inner sleeve in this case has freedom of oscillation, which is controlled by a barrel-shaped spring placed 
 
THE KING SPINNING MACHINE. 
 
 243 
 
THE RING SPINNING MACHINE. 
 
 245 
 
 round the upper part of the bearing. It may be noted that the lower end of the inner sleeve is quite free, 
 and that the entire control conies from the spring at the top. There are many other forms of this type of 
 spindle, Messrs. Dobson and Barlow, for instance, employing a cork cushion in lieu of -a spring. Mr. John 
 
 J.N. 
 
 Fig. 192. 
 
 Dodd, of Messrs. Piatt Brothers and Co., Limited, has patented the spindle illustrated in Fig. 193, 
 which the author is informed is running at a very high velocity, and giving very good results. The spindle A 
 is carried in a tube or bolster D, formed with a rectangular nipple C at its lower end, in order to prevent 
 its turning with the rotation of the former. The spindle A is formed, as shown, of a special shape, being 
 
 R 
 
246 
 
 THE RING SPINNING MACHINE. 
 
 strengthened above the top of the bolster, so as to be stiffened somewhat where the bobbin fits. The main 
 arrangement of the bolster case, sleeve, etc., is similar to the Rabbeth, bub the bolster case extends upwards 
 a little above the bolster, and on the spindle a collar B is formed, by which the oil which works up above 
 the top of D is thrown off so as to catch on the bolster case and run down again into the chamber which 
 is formed at its lower end. The oil passes through holes in the tube, thus providing for an efficient 
 lubrication, and the tube is so fitted into the case as to be a little less than its internal diameter. It is 
 probable that in working D will be constantly surrounded with oil, which will form a pretty effective cushion. 
 At any rate it is found that high velocities can be attained with this spindle, combined with complete 
 steadiness. In Fig. 194 (see p. 249), the "Bee" spindle, which is the invention of the late Mr. George Bernhardt, 
 of Radcliffe, is illustrated. This gentleman gave a good deal of attention to this special class of spinning 
 machines, and was the inventor of many useful appliances in connection therewith. The chief feature of the 
 Bee spindle is the formation of the bearing in the shape of a long tube, which can be withdrawn from the 
 bolster case and emptied of oil without disturbing the spindle. The tube is held in position by a bayonet 
 catch, and can be withdrawn and replaced in a very short space of time. If desired, the tube can be 
 arranged to rotate as it is acted on by the revolving spindle, but this is not essential. The use of a 
 withdrawable tube is a very valuable feature in principle, and is worth favourable consideration. In passing 
 it may be stated that the adoption of spindles with elastic bearings has led to a shortening of the driving 
 sleeve, and a reduction of the height of the top bearing, as a comparison of Figs. 191 and 192 will show. 
 
 (375) The ring, the use of which gives its name to the system, is made of the form shown in the 
 drawings, and varies in diameter from 1 inch to 5 or 6 inches, as required, 2 inches being a very common 
 size. The diameter is, of course, determined by the counts being spun, the cop or spool produced being larger 
 in proportion to the coarseness of the counts. A table of the ordinary sizes employed will be found at the 
 end of this chapter. The important points in a ring are its perfect circularity, smoothness of surface, and 
 hardness, three features which tax the energies of manufacturers to obtain at the prices paid for these articles, 
 Formerly rings were produced out of iron of good quality, which was formed into a hoop and perfectly welded, 
 but latterly steel has come largely into use, and it is the practice to obtain the blank without a 
 joint. The rings are in some cases milled, and in others turned and bored to the required section, and are 
 subsequently case-hardened. A large percentage of the soft rings fail in the case-hardening, and the production 
 of a perfect article is only possible with a proportion of the blanks dealt with. In the great majority of cases 
 the ring is made single— that is, with one bead only (Fig. 195)— but Messrs. Thomas Coulthard and Co., of Preston, 
 produce a double ring, shown in Fig. 196, which can be reversed when needed. This firm provide a special holder 
 for their ring, which is fitted on to the rail, and is also formed with a vertical arm or projection which knocks 
 the fly off the traveller as the latter revolves. The fly is— as explained— the collection of loose fibres which 
 are thrown off from the surface of the yarn in its passage to the spindle, and which if left adhering to the 
 ring or traveller increases the drag and causes breakage. It may be repeated here that cleanliness is a most 
 important feature, and requires constant attainment if spinning is to be conducted successfully. A special 
 lubricant is provided for the ring and traveller, ordinary oils being useless. 
 
THE RING SPINNING MACHINE. 
 
 247 
 
 (376) The travellers are, as previously mentioned, made of a C shape, but this is not invariable, and are 
 of various weights to suit varying circumstances. There are two standards of weight used in manufacturing 
 travellers in this country, one known as the Scotch and the other as the United States. The Scotch standard 
 probably derived its name from the fact that it was originally, and still is, manufactured in Paisley, by Messrs. 
 Eadie Brothers. The difference between the two lies in the size of the bow for fine numbers from 1/0 to 30/ — 
 used in spinning 28's counts yarn and finer. The smaller bow is used in the Scotch standard, and it 
 enables a thicker steel to be used, giving greater strength to the traveller and preventing it being pulled off 
 the ring so easily. Thus, in spinning 32's, a number 2/0 to 3/0 Scotch standard can be used, whereas the 
 number in United States standard would be 3/0 to 4/0. For fine yarns a light traveller is necessary, while 
 for coarse counts or strong doubled yarn a proportionately heavier one is used. A good deal depends, 
 however, on the quality of cotton used, good Sea Island, for instance, enabling yarn to be spun with a traveller 
 three or four sizes heavier than that permissible with inferior cotton. The diameter of the ring used, the 
 
 Fig. 195. 
 
 2 
 
 i? 
 
 Fig. 196. 
 
 number of twists per inch, and the speed of the spindles are among the things which influence the choice 
 of the traveller used. It may be said that, although definite rules are made as to the weight of traveller 
 used for certain counts under fixed conditions, a careful overlooker can make a vast difference in the production 
 by selecting the exact size of traveller best adapted to particular yarns. 
 
 (377) Having thus described the essential portions of a ring spinning machine, some of the difficulties 
 and principles of the mechanism may be dealt with. It is quite certain that the full theoretical reasons for 
 the successful accomplishment of this work are not now forthcoming, but an approximation to them is possible. 
 The actual spinning process is merely a twisting together of the fibres of any material by the rapid revolution 
 of a flyer or spindle while the fibre is being delivered at a definite rate. In this case the twist is put in by 
 the rotation of the traveller, which, as shown, is actuated from the spindle. As it has never yet been 
 accomplished to take off the yarn from the spindle at the same rate as it is being wound on, it is necessary 
 that the twisted fibre should be collected on the spindle or on a bobbin super-imposed on it. In order to do 
 this, as was shown in Chapter X., it is essential that the eye or guide through which it is delivered to the 
 
248 
 
 THE RING SPINNING MACHINE. 
 
 spindle should travel either faster or slower than any fixed imaginary point on the spindle. The latter is the 
 invariable rule with the ring frame, and it will be seen that as the bobbin is revolving at a quicker rate 
 than the flyer eye, or in this case the traveller, it will take up the yarn and gradually wind it on to itself. 
 Of course, in the case of a mule this does not happen, the winding arrangement being there altogether different. 
 The amount of " lead " which the bobbin has should correspond approximately to the number of inches of 
 yarn delivered by the rollers. That is to say, if the yarn is receiving ten twists to the inch, the bobbin 
 should take up approximately, during ten revolutions, one inch of yarn. Now it is quite clear that if the 
 velocity of the bobbin varies, the speed at which the traveller is pulled round the ring will vary also, but 
 that, owing to the resistance caused by its weight and frictional contact with the ring, it will always tend to lag 
 behind the bobbin. A little examination will show that the weight of the traveller is really the determining, 
 or, at any rate, the most important, element in the case. As has been explained, the rotation of the traveller 
 is caused by the pull exercised on it by the yarn. Now the velocity at which ring spindles are revolved is 
 very great, averaging in ordinary cases at least 8,000 per minute. It is quite clear that a traveller rotating 
 at that speed will tend by centrifugal force to fly outwards, and thus cause its inner lip or edge to press 
 against the inside of the ring. Although it is quite true that this contact is only a slight one it exists, and 
 constitutes one of the elements in the case. But it is also evident that the greater the weight of the traveller 
 the greater will be the force that is exerted against the inside of the ring. While the author does not wish 
 to do more than express his own opinion in this matter, there seems to be substantial ground for belief that 
 the tangential pull on the yarn between the traveller and the point at which it reaches the bobbin will to 
 a great extent counterbalance the tendency to fly outwards. It therefore seems probable that the reasonable 
 explanation of the drag of the traveller is to be found in the resistance set up by its weight rather than by 
 its frictional contact with the ring. This is the principle upon which travellers are made, their weight being 
 carefully graded in order to suit various counts of yarn and velocities of spindles. There is another feature 
 in which the weight of the traveller is evidently of importance, and that is its relation to what is known as 
 ballooning. 
 
 (378) A glance at Fig. 188 will show that between the ring rail and the nip of the front rollers there 
 is about ten inches of yarn, which, when it is being twisted, is held by the traveller and the rollers, and 
 tends to fly outwards and assume a curved course, which from its shape is called a " balloon." 
 This is caused by the centrifugal action of the yarn and the resistance of the atmosphere, and 
 leads, unless checked, to a serious loss of twist. In addition to this as the distance between 
 the centres of the spindles is only 2 or 3 inches ordinarily, it is obvious that if this tendency 
 is unchecked contiguous ends will come into contact and frequent breakages occur. The author was 
 informed by Mr. Bernhardt that a careful trial made by him established the fact that, where the balloon is 
 unchecked and allowed to attain its greatest size, the breakages are six and a half times as numerous as 
 when its size is in some way limited. There are two methods of doing this, one by surrounding the spindle 
 with a guard which prevents the balloon attaining more than a certain fixed maximum diameter, and the 
 other by so adjusting the position of the thread board that the distance between the wire eye and the 
 
THE RING SPINNING MACHINE. 
 
 249 
 
 traveller is such that not more than a certain sized balloon can be formed. It is a well known fact that a 
 balloon is absolutely essential to good spinning, as its centrifugal action enables a lighter traveller to be used, 
 and the drag upon the yarn is thus reduced to a minimum. The use of a heavy traveller undoubtedly will 
 check ballooning, but the yarn will suffer, and therefore a well formed but not excessive balloon is of advantage. 
 Mr. Brooks employs a plate (L, Fig. 188) pierced with a number of holes and mounted on pokers, 
 which gradually rise higher as the bobbin fills, so that the balloon is checked by the hole in the 
 plate. Other makers, such as Messrs. Piatt Brothers and Co., Howard and Bullough, and Dobson and 
 Barlow, employ forked wire guards which serve the same purpose as the plates referred to. Fig. 194 
 represents the appliance used by Mr. Bernhardt, which is very effective and is worth attention. Instead 
 
 Fig. 194. 
 
 of depending upon a guard of the character referred to, the ballooning is checked by maintaining a defined 
 distance between the guide eyes and the ring rail. It is clear that as the latter rises, if the guides 
 tire stationary, there will be a greater tendency to balloon when the rail is at its lowest position than when at 
 its highest. More than that, the attainment of the full diameter of the cop is followed by more ballooning 
 than when the building is just beginning, and it is therefore advisable to slightly shorten the distance 
 between the guide and the point of the spindle. The guides are in this case mounted on a rod borne 
 by and attached to vertical pokers A- The vertical position of A is determined by the cam C, which 
 is slowly rotated as building proceeds. The shape of C is such that when spinning begins, the guide 
 eve A is about an inch above the nose of the bobbin, but gradually falls until within | inch of 
 
250 
 
 THE RING SPINNING MACHINE. 
 
 the same point, after which it slowly rises until the relative positions at the commencement and 
 finish are as indicated by the dotted and full lines. The rise begins as soon as the cop is formed of full 
 diameter, and one important feature in this invention is that the vertical reciprocations of the guide eyes 
 are independent of, less than, although simultaneous with, those of the ring rail. It is certainly remarkable 
 how effective this contrivance is in checking ballooning, and this without submitting the yarn to any injurious 
 rubbing action. The size of the balloon is accurately checked, while at the same time it is as large as can 
 be permitted under the existing conditions. The inventor stated that the effect of this arrangement is that 
 a bobbin of 6 inch lift can be employed, where in other cases not more than a 5 inch bobbin could be used. 
 The extra length of yarn so wound on is of great service in subsequent processes, giving rise to other 
 advantages which are well known. 
 
 (379) So far the mechanism employed has been designed to spin on bobbins placed on the spindles, but 
 there is another branch of the subject to which reference must be made. Although the attempt to spin on 
 bare spindles was made so far back as 1847, this special method of spinning is not even yet completely successful, 
 though it is quite true that many efforts have been made which have attained partial success. It may 
 perhaps help to the understanding of the difficulties of the case to remember that weft yarn is most urgently 
 needed in the form of cops. Now, yarn which is used for weft has many less twists per inch put into it 
 than warp yarn, and is in consequence much softer and more tender than the latter, breaking with less 
 strain, and being altogether more difficult to spin. It is, therefore, under conditions which are the most 
 unfavourable possible that the attempt to spin on the bare spindle in ring frames has to be made. In 
 forming a cop, the diameter on which the yarn is wound is constantly changing, and the largest diameter 
 is only a little smaller than the internal diameter of the ring, while the smallest will be about ^ of an 
 inch. Now, it will be easily understood that the drag exercised by the yarn on the traveller will be greater 
 when it is being w r ound on the larger diameter than when on the smaller, it being remembered that the 
 spindle is always revolving at a regular rate, and consequently taking up more yarn per revolution on the 
 body of the cop than on the spindle. Thus, if a regular rate of traverse of the ring rail were adopted it is 
 clear that at one point the yarn would be taken up too rapidly, or too slowly at another. In the mule 
 this difficulty is overcome by increasing the speed of the spindles when the yarn is being wound on the nose. 
 It is not possible to adopt any such method in the case of ring spinning, and the solution has been 
 attempted by the adoption of a mode of giving a very quick traverse at the beginning of its downward 
 stroke to the ring rail, so that less yarn is wound on at that point. Of course this difficulty more or less 
 exists even where spools and bobbins are used, but it is not so acute as when only the spindle is employed. 
 The speed of the traveller varies continually, being greater when the yarn is being wound on the larger 
 diameter and less when on the smaller. There is thus a greater resistance when winding is going on at the 
 nose, and breakages occur more frequently at that point. In addition to this there is the difference existing 
 in the way the pull is exerted on the traveller at both points, which will be readily understood by a 
 reference to Fig. 197. It will be seen that the direction of the draught of the yarn is in the first case from 
 
THE KING SPINNING MACHINE. 
 
 251 
 
 B to C, and is an angular or tangential one, whereas in the second case the pull is from A to C, and 
 is almost radial. As the yarn in proceeding from the rollers to the bobbin is passed through the traveller, 
 it will be clear that while the revolution of the spindle will in the first case draw the traveller round the 
 ring in the direction of the arrow, in the second case it will exercise no tractive power, or at. any rate very 
 little, on the traveller, tending rather to pull it against the ring. As the point A is, however, constantly 
 changing its position, a certain drag is given to the traveller, but it is a periodical one, for as soon as its 
 position is altered the old conditions are again established. In this way the yarn is in a sense twitched or 
 wrenched, and breakages occur in consequence. In addition to this difficulty there is another, arising from 
 the different speeds at which the traveller runs, to which reference has been made. Owing to this difference 
 more twist is put in when winding is going on at the largest diameter, and less when at the nose of the 
 
 Fig. 197. 
 
 cop. Now, the latter place is where it is most wanted, owing to the increased drag, and as weft yarn is 
 always more softly spun a decrease in the number of turns per inch is a fruitful source of breakage. The 
 difference amounts to between one and two per cent, and constitutes really the chief difficulty to be overcome. 
 
 (380) As this subject is one of some interest a few words may be profitably expended on it There is 
 some confusion existing as to the way in which the loss in twist should be arrived at. On the one hand it 
 is contended that the number of coils made in one lift of the ring rail should be counted, and the loss of 
 twist calculated from that. On the other hand, it is urged that the coils laid in a double lift of the rail 
 should be taken as a basis. This is the view held by Mr. Charles Lancaster, of Manchester, who has given a 
 good deal of attention to the subject, and with whom the author is inclined to agree. To arrive at a 
 conclusion it is necessary to ascertain the smallest and largest diameter of the surface of the bobbin, 
 calculating therefrom their respective circumferences. The mean of the latter will give the average length of 
 yarn wound per revolution, and the difference of the two the relative loss in twist. Mr. Lancaster put this 
 matter very clearly, and the demonstration may be given in his own words : " To prove this calculation 
 measure the length of a 'draw'— i.e., the yarn deposited in one up or one down motion of the ring rail— 
 
252 
 
 THE RING SPINNING MACHINE. 
 
 and multiply by the number of turns per inch, count the number of coils in this layer of yarn (which 
 represents the actual loss), and divide into total number of turns. Thus, if the up motion of the ring rail 
 deposits 72 inches of 20's yarn with 1675 calculated turns per inch, then 72 x 16-75 = 1,206 - 20 coils 
 = 1-8 per cent of loss; and if the down motion deposits 178 inches of yarn with 16-75 calculated turns, 
 then 178 x 16-75 = 2,981-5 -r- 46 coils = 1-6 per cent, ©r an average of one up and one down motion of 
 the ring rail of 1 7 per cent." * Of course the finer the yarn spun the less the percentage of loss of twist. 
 
 (381) Whatever be the mode of calculation adopted, whether only the single or double lift be taken into 
 account, the fact remains that there is a loss of twist, and that this is of most account when weft yarns are 
 being spun. It being most desirable to spin these upon the bare spindle, so that they may be used in the 
 shuttles, it will be seen that the subject is one of some importance. Various methods have been tried to 
 overcome the difficulty, one mode being to take the yarn away from the nose of the cop as quickly as 
 possible, but it has only been partially successful. Another, and. more successful plan, is to form a special 
 traveller, so arranged that the yarn in passing to the bobbin does not give a radial but a tangential pull to 
 the traveller. The final form of traveller adopted by Mr. William Lancaster, who has tried a large number 
 of shapes for this purpose, is arranged in this way, and to a certain extent frames made by him have been 
 successfully used. The mode of construction adopted by Mr. Lancaster is shown in Figs. 198 and 199. 
 In these the traveller is made at one end with an open fork, and at the other is C shaped, fitting the 
 ring as shown in Fig. 199. Referring to that figure it will be seen that the yarn is carried through the 
 C shaped eye, and then round the foot of the open fork B to the spindle A. The result is that the point 
 where the traveller rests on the spindle acts as a fulcrum, and the yarn exercises a pull on the end of the 
 arm carrying the C, this portion of the traveller practically becoming a lever. In this way the direct radial 
 pull upon the yarn is avoided, and the traveller is readily drawn round the ring. Its actual position on 
 the cop is shown in Fig. 198, where B is the fork, A the yarn, and C the spindle. In this form a number 
 of frames are working with considerable success. 
 
 (382) In Figs. 200 and 201 a special form of ring and traveller applied to a bare spindle is illustrated, 
 these being made by Messrs. Piatt Brothers and Co., Limited. The ring B has a groove A formed in it, 
 in which a traveller D made of the shape shown is placed. The traveller has a loop or hook E near one 
 extremity, and a second loop C nearer the centre. The yarn is first passed under the loop E, and then 
 through C, thus giving a drag to the traveller at the point E, and causing it to travel round the groove. 
 The loop C lies close up to the spindle when the yarn is at the nose of the cop, so that the yarn passes at 
 once on to the former. The machine so constructed has been in use for some time, and it is found possible 
 to stop it with the ring rail opposite the extreme point of the cop and re-start it without any considerable 
 breakage of ends. In considering this portion of the subject past experience will form a base on which to 
 found future efforts. A combination of a rapid traverse of the ring rail with some means of avoiding the 
 direct pull of the yarn might be effective, but the subject is one for experimental work and not theorising. 
 
 * Textile Manufacturer, Manchester, March 15th, 1890. 
 
THE RING SPINNING MACHINE. 
 
 253 
 
 The latter is more likely to retard than aid in the solution of the problem. A differential speed of the 
 spindles has been proposed, but no data exist by which a correct judgment can be formed. If by simple 
 means an approximation to an equal twist can be obtained a great step towards the solution of this extremely 
 
 Fig. 198. 
 
 difficult problem will have been made. The whole question is environed with difficulty and requires constant 
 attention to a number of little points, but the advance made during the past few years is so remarkable that 
 a good deal of hope can be entertained as to eventual success. In the meantime weft is being spun 
 
 Fig. 200. Fig. 201. 
 
 successfully on small wooden pirns which possess the great advantage of allowing the whole of the yarn to 
 be unwound from them, and thus save the waste often made by "stabbed" cops. A frame for this purpose, 
 made by Messrs. Howard and Bullough, is shown in Fig. 202, and about 400 grains of No. 20's yarn can 
 be wound on each. 
 
254 
 
 THE RING SPINNING MACHINE. 
 
 (383) With reference to the details of the machine it has latterly become the practice to drive both tin 
 drums positively, so that there is no variation in the twist of the yarn on different sides of the machine. 
 Such an arrangement — made by Messrs. Asa Lees and Co., Limited— is shown in Fig. 203, the course of the 
 ropes being clearly indicated by the figures attached. The lift of the spindles varies from 5 to 6 inches, 
 and their gauge from 2f to 2f inches. The diameter of the front roller is usually 1 inch. 
 
 (384) Akin to the ring spinning machine is that employed for doubling. It is, however, heavier in 
 construction, and has a different arrangement of rollers. The rings used are as large as three inches in 
 
 Fia. 203. 
 
 diameter, and the spindles have a lift of six inches. The travellers are of a different shape, being made to 
 engage with both the top and bottom flange, or bead of the ring. There are two systems of doubling pursued. 
 In the English system the delivery rollers are placed in front of longitudinal water troughs, so that the yarn 
 may be either passed through the water or not as preferred. In the Scotch system the rollers are placed 
 above the water troughs, and the bottom rollers can, by means of a special arrangements, be lowered into 
 the water. In both cases there are but one line of rollers usually, and, in the case of Scotch doublers 
 these are invariably brass covered. The rollers are much heavier than those used in spinning, as the delivery 
 
THE EING SPINNING MACHINE. 
 
THE KING SPINNING MACHINE. 
 
 257 
 
 of the yam is accomplished by the nip of the top and bottom rollers, the former not being weighted in any 
 way. In the Scotch frames the rollers are carried by short arms securely keyed on a longitudinal shaft, which, by 
 means of a worm and worm quadrant, can be oscillated so as to lower or raise the rollers into the water 
 trough. In the English system of wet doubling, the yarn is taken underneath a glass rod immersed in the 
 water in the trough, and then through the rollers. It is not necessary to deal further with the details of 
 this machine, as it is practically similar to the spinning machine. 
 
 (385) There is a large trade done in " double " yarns— that is, yarns composed of two threads twisted 
 together— these being used for the warps of some of the stronger calicoes, and in the finer grades for many other 
 purposes, such as the manufacture of lace. There is no difficulty in producing these, but the manufacture 
 of -sewing thread involves a more elaborate treatment. In carrying this out the yarn is first wound on a 
 machine provided with detector mechanism, and known as a doubling winding machine— this being described 
 in the next chapter. The object of this machine is to enable a two-fold yarn to be produced free from 
 knots of large size, from single, and from slack places in any of the strands, this producing " corkscrews." 
 The latter is the phrase used, when one end of the yarn being twisted has been more slackly wound than 
 the other, thus becoming bagged, and resulting in it being twisted round the other irregularly. These are 
 very objectionable, and not permissible in producing sewing thread, as they cause thick places which 
 catch in the eye of the needle. Having obtained the two-fold yarn, the next operation is that of " cabling"— 
 that is, the twisting together of three of the double yarns. These are, therefore, again wound on 
 to a bobbin or spool on a similar machine to that previously used, and are then twisted together into a six- 
 fold or "six- ply" thread. The advantages of doubling winding will be more fully explained when the machine 
 is described. < 
 
 (386) In order to enable some idea of the class and weight of the travellers used, the relative speeds of 
 front roller and spindles, and production, a table is appended to this chapter in which a few representative 
 counts are selected. Other tables give the result of a number of tests made with the Emerson Power Scale 
 and other instruments, -which enable the amount of driving power required to be ascertained. 
 
 (387) The consideration of the various machines employed in spinning being now concluded, a few 
 words may be said generally about the whole system. Before doing so, however, it may be as well to define 
 the meaning of one or two words which are habitually used to define the relative fineness of the yarn. 
 It will be noticed in the table appended to Chapter X. that the roving was described as such a " hank " 
 roving, while the yarn is said to be of certain "counts." Although apparently contradictory, these 
 terms are not really so, being simply different expressions of the same fact. The standard upon which 
 all definitions of the fineness of yarn are based is the " hank " of 840 yards. A hank is the thread 
 wound into coils of 54 inches circumference until a length of 840 yards is obtained. That forms 
 the basis by which the "counts" of yarn are calculated, and the "counts" are simply the number of 
 such "hanks" in one pound weight. In ascertaining the "hank" of roving a certain length is wrapped 
 into a coil and weighed. The weight is obtained in grains, and that sum is then divided into a constant 
 
258 
 
 THE RING SPINNING MACHINE. 
 
 number obtained as follows : The number of yards of roving taken is multiplied by 100 and divided by 12. 
 This practically means taking 8-33 as a constant number and multiplying it by the number of yards of 
 roving wound. The same procedure is pursued with the lap and sliver on the scutching, carding, and 
 drawing machines. It is no part of the scheme of the present work, however, to do more than glance at 
 these modes of calculation, as there are many books of rules already in existence, but it may just 
 be stated that the amount of twist which is put into any yarn is determined by the following method : 
 The square root of the count is taken as the basis of the calculation, and is multiplied for mule twist by 
 3-75, for ring frame or extra hard twist by 4, and for weft yarns by 3*25. The product of these calculations 
 give the twist per inch for any counts of yarn it is desired to spin. The three multipliers thus given 
 are sufficient for ordinary uses, but if yarn is spun for doubling purposes the multiplier is 2-75, and if for 
 hosiery purposes 2*50. 
 
 (388) In conducting the manufacture of cotton into yarn, it is desirable to remember that a gradual 
 reduction in its substance is wanted, and all the draughts throughout the whole series should be carefully 
 graded to ensure this. It is extremely undesirable to overstrain the cotton at any point, and this would be 
 the inevitable result, unless the whole of the speeds were designed to give a gradual reduction. This is a 
 factor which it is unwise to neglect, and by a little careful observation, the correct draughts throughout the 
 process can easily be arrived at. It is, however, essential, if it is desired to produce a good yarn, that the 
 mode of obtaining it should be carefully thought out before passing the cotton through the scutchers. 
 Practically, the hank drawing and hank sliver are the same, but the former is obtained from several slivers, 
 so that there is at this stage a considerable reduction. After this point the attenuation should be steadily 
 kept in view, until the completion of spinning. In conclusion, it may again be urged that cleanliness and 
 care in the use of spinning machines will well repay the spinner. It is worth his while to see that the 
 machinery he employs is well made to begin with, and is kept in good order subsequently. By doing so, 
 he will ensure the production of a good yarn, which cannot be spun in profitable quantities, without an 
 undue amount of waste, on machines which are neglected and allowed to fall out of repair. 
 
THE EING SPINNING MACHINE. 259 
 
 Table 4. 
 
 PRODUCTION OF RING SPINNING FRAMES FROM ACTUAL TESTS, 
 MESSRS. HOWARD AND BULLOUGH'S MACHINES. RABBETH SPINDLES. 
 
 Counts of 
 Yarn 
 
 Speed of 
 Spindle 
 per Minute. 
 
 Speed of Front 
 Roller 
 
 Diameter 
 of 
 
 Turns per 
 inch 
 
 Diameter 
 of 
 
 Number 
 of 
 
 Traveller. 
 U. S. Standard. 
 
 Production per spindle per week 
 of 56J hours. 
 
 to be Spun. 
 
 per Minute. 
 
 Front Roller 
 
 of Twist. 
 
 Ring. 
 
 In Pounds, 
 lbs. ozs. 
 
 In Hanks. 
 
 10's 
 
 6,020 
 
 158 
 
 i 
 
 1212 
 
 
 7's or 6's 
 
 5 4 
 
 524 
 
 16's 
 
 6,800 
 
 133J 
 
 1 
 
 1621 
 
 .11 
 
 4's or 3's 
 
 2 12 
 
 44 
 
 20's 
 
 7,300 
 
 132 
 
 1 
 
 17-60 
 
 If 
 
 2's or l's 
 
 2 -1\ 
 
 43| 
 
 24's 
 
 7,500 
 
 130 
 
 1 
 
 18-36 
 
 n 
 
 1/0 or 2/0 
 
 1 12£ 
 
 42| 
 
 28's 
 
 7,500 
 
 116J 
 
 1 
 
 20-49 
 
 14 
 
 2/0 or 3/0 
 
 1 5| 
 
 38 
 
 30's 
 
 7,500 
 
 119 
 
 1 
 
 20 00 
 
 H 
 
 3/0 or 4/0 
 
 1 4| 
 
 39 
 
 32's 
 
 7,500 
 
 111| 
 
 1 
 
 21-41 
 
 X4 
 
 4/0 or 5/0 
 
 1 2£ 
 
 37 
 
 34's 
 
 7,500 
 
 107 
 
 1 
 
 22-31 
 
 14 
 
 5/0 or 6/0 
 
 1 0 
 
 34£ 
 
 36's 
 
 7,500 
 
 101 
 
 1 
 
 23-63 
 
 14 
 
 6/0 or 7/0 
 
 1*4 
 
 33 
 
 38's 
 
 7,500 
 
 97 
 
 1 
 
 24-50 
 
 14 
 
 7/0 or 8/0 
 
 13i 
 
 31£ 
 
 40's 
 
 7,500 
 
 94£ 
 
 1 
 
 25-25 
 
 H 
 
 8/0 or 9/0 
 
 12 
 
 30J 
 
 Note. — With elastic spindles an increase of production occurs of ^about_20 per cent. 
 
 Table 5. 
 
 POWER TESTS OF RING SPINNING MACHINES MADE AT THE DWIGHT MANUFACTURING CO., 
 CHICOPEE, U.S.A., APRIL, 1885, BY MR. H. S. CHASE. 
 
 Date. 
 
 Time. 
 
 Make of Frame. 
 
 Spindle. 
 
 No. of 
 Spindles. 
 
 Counts. 
 
 Condition. 
 
 Spindle 
 Speeds. 
 
 H. P. 
 
 required 
 for Frame. 
 
 No. of 
 Spindles 
 per h.p. 
 
 April 9th 
 
 2-0 to 5-30 
 (8 tests) 
 
 Lowell Spinning 
 
 Rabbeth 
 
 t 
 
 192 
 
 28's 
 
 Bobbins from 
 \ full doffed to \ full 
 again. 
 
 7439 
 
 1-5915 
 
 1207 
 
 „ 10th 
 
 10-30 to 11-30 
 
 Do. 
 
 Do. 
 
 192 
 
 28's 
 
 Bobbins £ full till full 
 
 7324 
 
 1-5094 
 
 1272 
 
 „ 11th 
 
 8-15 to 11-30 
 
 Do. 
 
 Common 
 11 oz. 
 
 208 
 
 21's 
 
 Mean of 11 tests, 
 Bobbins empty, 
 running an hour. 
 
 6409-5 
 
 2-4930 
 
 83-4 
 
 „ 13th 
 
 9-0 to 2-30 
 
 JBiddeford Spinning 
 
 Sawyer 
 
 144 
 
 21's 
 
 Bobbins § full 
 till doffed and filling 
 again. 
 
 7184-5 
 
 1-2565 
 
 114-9 
 
260 
 
 THE RING SPINNING MACHINE. 
 
 Table 6. 
 
 TESTS MADE AT LONSDALE, RHODE ISLAND, U.S.A., BY MR. W. S. SOUTHWORTH, 
 NOW SUPERINTENDENT OF THE MASSACHUSETTS COTTON MILLS. 
 
 SAWYER SPINDLES. 
 
 REVOLUTIONS PEK 
 MINUTE. 
 
 POWER FOOT POUNDS PER SECOND 
 PER SPINDLE. 
 
 Number of 
 Spindles 
 to One 
 Horse-power. 
 
 Front Rollers. 
 
 Spindles. 
 
 Empty 
 Bobbins. 
 
 Full Bobbins. 
 
 Mean. 
 
 59-2 
 
 5,408 
 
 3140 
 
 8675 
 
 3-407 
 
 161-4 
 
 63-95 
 
 5,842 
 
 3-536 
 
 4-139 
 
 3-837 
 
 143-3 
 
 69-9 
 
 6,386 
 
 4-025 
 
 4933 
 
 4-479 
 
 122-8 
 
 75-85 
 
 6,929 
 
 4-659 
 
 5-655 
 
 5-157 
 
 1067 
 
 82-5 
 
 7,539 
 
 5-338 
 
 6-537 
 
 5-937 
 
 92-6 
 
 88-9 
 
 8,124 
 
 6-034 
 
 7-331 
 
 6-682 
 
 823 
 
 97-95 
 
 8,948 
 
 7-009 
 
 8-419 
 
 7 714 
 
 71-3 
 
 The weight of the Spindle was 3-9S ozs., of the Full Bobbin 2'23 ozs., 
 and of the Empty Bobbin 71 ozs. 
 
 Table 7. — Extracted from the Journal of the Franklin Institute. 
 
 TEST OF RING SPINNING SPJNDLES, MADE AT CALLAGHAN'S MILLS, ANGORA, U.S., 
 BY Mr. S. WEBBER, 13th MARCH, 1890. COUNTS SPUN 30' s. 
 
 
 Bates 
 
 Whitin 
 
 
 Spindle. 
 
 Spindle. 
 
 
 100 
 
 100 
 
 
 8360 
 
 8160 
 
 
 8.11 
 
 5.50 
 
 
 67-4 
 
 100 
 
 
 3144 
 
 2219 
 
THE RING SPINNING MACHINE. 
 
 26.1 
 
 Table 8.— Extracted from the Journal op the Franklin Institute. 
 TEST MADE BY ME. S. WEBBER, AT THE GLOUCESTER GINGHAM MILLS, 
 GLOUCESTER, NEW JERSEY, U.S., ON THE 17th MARCH, 1890. 
 COUNTS SPUN, 26's. 
 
 
 Bates 
 
 Excelsior 
 
 
 Spindle. 
 
 Spindle. 
 
 
 102 
 
 107 
 
 
 8039 
 
 8430 
 
 
 7-35 
 
 6-89 
 
 Spindles per H.P. ( do. ) 
 
 75 
 
 80 
 
 
 2-737 
 
 2-554 
 
 
 •462 
 
 •4fl 
 
 Do. H.P. for spindles and tin roller 
 
 2-264 
 
 2-064 
 
 
 •462 
 
 •462 
 
 Do. H.P. for spindles only 
 
 1-802 
 
 1-70 
 
 
 113 
 
 120 
 
 Note. — Tables 7 and 8 are merely given because they throw considerable light on the 
 question of the power required for ring frames. The Bates spindle is not described, as it ia 
 a new form and has not yet been thoroughly tried practically. 
 
CHAPTER XIII. 
 
 REELING, WINDING, AND SPOOLING MACHINERY. 
 
 (389) There are two main classes of goods in the manufacture of which yarn produced as described is 
 used. By far the greatest bulk is utilised in weaving fabrics of various kinds ; and. before it can be so 
 employed it necessarily requires treatment by a series of machines. With all the processes so involved it is 
 not intended to deal, but there is a second class of manufacture — the production of thread — which requires 
 special machines, and is worthy of separate treatment. It is also a very common practice in England to 
 form yarn into hanks, a number of which are packed together, and formed into a " bundle." In this shape 
 large quantities of yarn are shipped, being afterwards employed abroad in the manufacture of cloth. A 
 brief description of the machines used in this connection will therefore be given, and as the simplest mode 
 of dealing with the material, reeling will be treated first. 
 
 (390) The yarn, spun either in the form of a cop or on ring bobbins, can be formed into hanks by 
 means of a machine known as a "reel." It depends upon whether it is employed to wind the yarn from 
 cops or bobbins whether it is known as a " cop " or " bobbin " reel. In either case the hank is wound upon 
 a " swift " or " fly," consisting of a central barrel or roller, which has centres or axles formed at each end. The 
 latter revolve in bearings in, or attached to, the framing, and the " fly " can be driven either by hand or by a belt 
 from the line shaft or counter shaft. On the barrel is fitted a number of light wooden or iron frames, to the arms of 
 which are attached longitudinal bars or " staves " of timber. These are made about 2 inches wide, and are rounded 
 on their outer edges, being well polished and smoothed so as not to adhere to the yarn. The arms, as 
 ordinarily constructed, are made double with a central boss, so that each has two " staves ''' fixed to it. 
 When desired, the whole of the arms can be oscillated so as to bring the staves together, and the hanks 
 wound upon the swift are thus left loosely hanging upon them. By drawing them to one end they can be 
 easily slipped off when that end is raised. The number of hanks usually formed at one time is forty on 
 each swift, and ordinarily one swift only is used in a cop reel and two 'in a bobbin reel. The 
 appearance of the last named machine is well shown in Fig. 204, which is a representation of a double bobbin 
 reel as made by Mr. Joseph Stubbs. 
 
 (391) The general description thus given of the reel enables some of its details to be more particularly 
 described. If cops are to be " reeled " they are placed on " skewers " — which correspond in size to the upper 
 portion of mule spindles — fixed in a creel board. The cops are held at such an angle that the yarn draws 
 easily off the cop nose. The threads are slipped into slits formed in a guide plate fixed to a guide rail 
 sliding in suitable bearings. The same course is taken with the bobbin reel, but, in this case, the bobbins 
 
REELING, WINDING, AND SPOOLING MACHINERY. 
 
 263 
 
REELING, WINDING, AND SPOOLING MACHINERY. 
 
 265 
 
 are mounted in a somewhat different manner. Ring bobbins require a special arrangement to enable the 
 yarn to be easily drawn off without running into " snarls." The purpose of the guide rail is to traverse 
 the yarn so that the threads may be laid in one of two ways. Either the full hank of 840 yards is wound 
 into seven smaller ones — each containing 120 yards — known as "leas"; or it is " cros3 wound" — that is, a 
 rapid reciprocal motion is given to the guide rail, so that the coils are laid across each other throughout the 
 whole length. The latter is the usual procedure when it is intended to dye or bleach the yarn, and the 
 former when it is to be shipped. The diameter of the swift across the staves is usually sufficient to enable 
 a hank of 54 inches circumference to be wound. In France a hank of 56| inches is adopted, and the number 
 of coils in it are correspondingly arranged. 
 
 (392) If the hank is intended to be wound in seven "leas" the arrangement shown in Fig. 205 is used. 
 This is a partial side elevation of one end of a bobbin reel. The barrel B of the swift is made of a light 
 wrought iron tube, into each end of which plugs, reduced at end, are welded, S3 as to form the journals for 
 the barrel as described. On the end of the axle the fast and loose pulleys are placed, so that the machine can 
 be easily driven. The staves A are shown without their connecting arms. On the end of the barrel a worm 
 C is fixed, which gears with the wheel D ou the shaft, to which a lifting catch or pawl E is fastened. This 
 engages with the coarsely pitched rack F, and every revolution of the wheel D causes the pawl to raise F 
 one tooth. The teeth F are formed at the lower end of the bracket or "rack" G, which is guided by and 
 slides in the frame. The upper end of G is formed with seven steps, and a finger or pin, placed at H 
 in a bracket fastened to K, is constantly pressed against the face of G by means of a spring exercising a 
 longitudinal pull on K. The raising of G to the extent of one of the teeth F is sufficient to allow the pin 
 H to slip on to the next step, and thus the yarn is wound on to a fresh portion of the surface of the swift. 
 This takes place regularly until seven small hanks are wound, when the machine is automatically stopped. 
 
 (393) The length of yarn in each of these "skeins" or "leas" is ordinarily 120 yards, and it is, therefore, 
 necessary to cause the wheel D to make one revolution every time the swift has made 80 revolutions. The 
 length of the hank being 1| yards— 54 inches— that number ensures 120 yards being wound prior to the 
 rack G being lifted one tooth. If it is desired to shorten the hanks, a smaller wheel must be substituted 
 for D, and to get the desired amount of exactitude, it is sometimes necessary to use a series of change 
 wheels. 
 
 (394) It was shown that in order to remove the hanks from the reel, it is customary to close up the swift, 
 and, after gathering the hanks at one end, to lift it and thus remove them. There are two chief objections to this 
 course. First, a considerable danger exists of the yarn being soiled by contact with the greasy bearing ; and 
 second, the task of lifting a heavy swift with 40 hanks of yarn on it is sometimes too great for the attendant, who 
 is generally a woman. It is customary, therefore, especially in bobbin reeling, to fit the machine with a " doffing 
 motion" — the operation of stripping a spindle or other surface of yarn being known as " doffing." The staves are 
 fixed on the ends of the arms of an iron spider, and two of them are sustained by a hiDged frame which can be 
 released so as to oscillate in a forward direction, thus u dropping " the two staves attached to it. This is called 
 
266 
 
 REELING, WINDING, AND SPOOLING MACHINERY. 
 
 the "drop motion." The hanks are thus released, and can easily be drawn up to the doffing motion. There are 
 three forms of this. The first consists of a wheel, grooved on its periphery aud fitting in a circular bracket turned 
 to correspond. The centre boss of the " doffing wheel " bears one end of the swift, and a segment is removed from 
 the wheel, so as to leave a space into which one side of the hanks can be placed. By giving the wheel a half turn 
 the hanks are brought to the front of the swift, and can be easily removed. Another form, which was introduced 
 by Mr. Joseph Stubbs, was called the " gate " doffing motion, owing to the fact that a hinged bracket similar to a 
 gate was used, by removing which the end of the swift was left free. The movement of opening the gate oscillated 
 a lever, on which was a cross bar enabling the swift to be sustained during the operation of doffing. A further 
 improvement by the same firm bears the name of the "bridge" doffing motion, and is shown in Fig. 204. It 
 
 Fig. 206. 
 
 simply consists of a small bracket bridging a gap formed in the frame end, in which a longitudinal slot is made, 
 and at each end of it pivots are formed upon which it can be oscillated. The end of the swift barrel A (Fig. 206) 
 is fitted into a round shell B, in which the lubricant is retained, and a nipple on which slides in the slot in the 
 bridge bracket. The doffing is effected by simply allowing the hank to be drawn into the gap named, and then 
 by a smart push making the bridge bracket rest upon its pivots at the other side of the gap. This enables 
 the hanks to be easily lifted, after which a pull is sufficient to restore the swift to its working position. 
 The position of the bridge in its working position and during doffing, is shown on the left and right hand 
 side respectively of Fig. 204. This motion is an undoubted improvement on its predecessors, and oiling of 
 the hanks is practically unknown. 
 
 (395) Messrs. Guest and Brooks have recently introduced the skeining motion shown in Fig. 207. In this 
 case the rack G is driven, not by a lifting tooth, but by means of the pinion E gearing with a finely-pitched 
 toothed rack F. In this way a continuous motion is given to G. At the upper end of the latter, a bracket 
 or arm M is formed, having fixed at one end a centre pin O, on which the bracket, or arm, P can be oscillated. 
 The position of P is fixed by means of a bolt and nut passing through it and the slot R. The stepped 
 portion of G, instead of being cast, is obtained by the use of six bars L, which have a certain vertical movement 
 given to them by small pins engaged in the slot Q formed in the arm P. The pins are fastened in the bars, 
 and it is clear that the vertical elevation of the arm P will shorten or lengthen the steps formed by the 
 difference in the length of the bars L. In this way skeins, or leas, of any desired length can be wound, 
 it being obvious that, if the steps be shortened or lengthened, the engagement of the pin K 1 with them 
 
REELING, WINDING, AND SPOOLING MACHINERY. 
 
 267 
 
 successively, will take place at proportionate intervals, and K 1 being fixed in the bracket K which is attached 
 to the guide rail H, a shorter or longer lea will be formed prior to the traverse of H taking place. 
 
 (396) The hanks being reeled, they are, if cross reeled, dyed or bleached, and, if in leas, bundled. 
 This operation is effected in a machine called a "bundling press" (Fig. 208) consisting of two strong frames securely 
 fastened together by stays, and in which the bearings for the necessary driving straps are formed. Bundles 
 
 
 
 
 
 
 
 77 
 
 
 
 
 V 
 
 
 7 k ^ 
 
 Fig. 205. 
 
 are usually either 51bs. or lOlbs. weight each, and are generally fastened with five strings. To the upper 
 part of each of the frames wrought-iron plates, extending upwards, are fastened, narrow spaces being left 
 between each pair of plates, so that the strings or bands for tying up the bundles can be easily passed round 
 them. To the upper end of one set of plates cover bars are hinged, which can be pulled down on to the top of 
 
268 
 
 REELING, WINDING, AND SPOOLING MACHINERY. 
 
 the other set, where they ar^ locked by bars hinged to the latter. In the space between the two sets of vertical 
 plates an iron table rises and falls, and it will be readily understood that the elevation of the table, when 
 the top plates are closed and locked, compresses the bundles. The extent to which the pressure is exerted 
 depends on the throw of two eccentrics fixed on the main shaft, these being connected by means of strong 
 rods to the underside of the sliding table. By this arrangement the amount of pressure is strictly limited 
 and cvnnot become excessive. After the bundle is pressed it is tied up and the pressure released, the top 
 
 Fig. 207. 
 
 bars unlocked, and the bundle removed, in addition to which a knocking off or stop motion is fitted. In 
 an improved form of press, invented by Mr. Thomas Coleby, the top plates are automatically and simultaneously 
 released. 
 
 '(397) The procedure thus followed is that which is adopted in the case of yarns for export only. Where it 
 is intended to twist them into thread a special machine is employed to wind the several strands together prior 
 to doubling. Machines of this class are called "doubling winding" machines, and they enable a more perfect 
 
REELING, WINDING, AND SPOOLING MACHINERY. 
 
 271 
 
 thread to be produced than is otherwise possible. When yarn is "doubled" by twisting together threads 
 drawn singly from cops or bobbins placed in a creel, there are two chief evils existing. If one of the threads 
 breaks, a certain length of the single thickness may be wound on the doubling bobbin, with the result that a 
 faulty place in the finished article is found. There is, in addition, the difficulty that the broken thread 
 may become wrapped round the top roller, producing a " roller lap," which is so much waste. The production 
 of "single" and of "roller laps" is undesirable, and should be avoided if possible. Further, if the two threads 
 in passing through the feed rollers are not both at the same tension, one becomes loosely twisted round the 
 other in a manner which is technically known as "corkscrewing," as explained in paragraph 385. When thread is 
 used for sewing machine, lace, or similar purposes, either of these faults is very objectionable. By using a 
 machine in which the strands to be twisted are wound together before being so treated, and in which 
 detector mechanism is employed, a finished thread is produced, which is generally quite free from the defects 
 named. 
 
 Fig. 209. 
 
 (398) In Fig. 209 a perspactive view of a doubling winding machine made by Mr. Joseph Stubbs, and 
 in Fig. 210 a transverse section of the same machine, are given. Mounted on a shaft, extending 
 longitudinally of the machine, is a series of drums A, which drive by frictional contact flanged bobbins B. 
 The latter are held in the head of forked cradles C, and revolve freely upon a small spindle. The lower 
 ends of C are subjected to the pull of weights J, connected with them by chains, as shown by the dotted 
 lines. Coupled to the tail of the cradle C is a double frame E, which carries at its outer extremity a 
 swinging or oscillating box or frame, in which are placed a series of small wires-known as detector wires 
 
272 
 
 REELING, WINDING, AND SPOOLING MACHINERY. 
 
 corresponding in number to the strands to be wound. The wires are formed at their upper ends G with 
 a curl, and their lower ends F are straight. Immediately below the box a three winged wiper H revolves 
 at a rapid rate. The operation of this mechanism is as follows. The cops to be wound have skewers thrust 
 into them, which fit in adjustable cast iron brackets fixed on a longitudinal rod in the bracket O, fastened 
 to the "bottom box." In the case of bobbins, special provision is made for holding them. In any case, 
 the yarn is drawn upwards through a guide plate fixed as shown, over a flannel-covered curved rail Y, the 
 friction of which is sufficient to ensure a sufficient tension being put upon the yarn. Each " end " is then 
 taken through one of the detector eyes G and upwards over a light roller X, then through a guide wire 
 W, secured to the rod or rail Z. To the latter a reciprocal lateral motion is given, corresponding in length 
 to the length of the bobbin between the flanges— in other words, to its " lift." After passing the guide wire 
 W the yarn is taken to the bobbins B, and as the two bobbins are by reason of their position on each side 
 of the drum A driven in opposite directions, the yarn is taken on to them at different sides of the centre 
 of the bobbin barrel. So long as the " ends " are being wound, the lower end F of the detector wire is 
 kept out of the path of the wiper H, but when, from the failure, breakage, or slack tension of an « end," 
 this sustaining power is withdrawn, the end F of the wire affected comes in the path of H. This causes the 
 oscillating box to swing on its centres, and thus to release the holding down catch I, which usually keeps 
 the pivoted frame E pressed downwards. This release is followed by a certain movement of the cradle C, 
 set up by the pull of the weight J, and brings the bobbin B on to a brake surface D, by which its 
 motion is instantaneously arrested. To piece up, the bobbin can be drawn forward into the position shown 
 on the right hand side of the drawing in dotted lines, so that it can be turned back as much as 
 required. The position of the parts before and after an " end " has failed is clearly shown on each side 
 of the drawing respectively. It only remains to be said that a box T is fixed on the position shown, on which the 
 wound bobbins can be placed prior to removal. Although the yarn is wound at a speed of 4,000 to 5,550 
 inches per minute, a broken end is usually arrested before it reaches the bobbin. 
 
 (399) In preparing thread for the lace trade it is the practice to remove the loose fibres, or "ooze," 
 projecting from its surface. This is done by a machine called a "gassing" frame, a sectional view of one 
 head of which, as made by Mr. Stubbs, is shown in Fig. 211. This represents one side of a machine only. 
 The bobbin B is driven by frictional contact with a drum A, revolving rapidly, and is held in a weighted 
 frame C, hinged at its inner end. C is raised by a bracket or arm D, mounted on the same pin. At the 
 inner end of D is a slot in which a finger fixed on the stem of the burner E engages. The burner derives 
 its gas from a tube G running along the frame, and is fixed in a swivel joint, being generally of the Bunsen 
 type. The thread is drawn from the bobbin K, mounted on a freely revolving spindle, and is passed two 
 or three times, as shown, over the grooved bowls H, these being formed with four grooves for the purpose. 
 A guide I, receiving a longitudinal reciprocatory motion, guides the thread on to the surface of the bobbin 
 B. As the thread passes rapidly through the gas flame from the upper end of the burner E, the "ooze" 
 is rapidly singed off. When an end breaks or is " burnt down " the lever D is raised so as to lift the 
 
REELING, WINDING, AND SPOOLING MACHINERY. 
 
 273 
 
 frame C and bobbin B out of contact with the drum A, and is sustained by a catch during the time of 
 piecing. The same movement causes the burner E to be pushed at one side out of the path of the thread, 
 and the restoration of the parts to the position shown again brings it gradually under the thread, but not 
 until after the winding has commenced. 
 
 (400) In addition to these machines, where lace yarns are made it is sometimes the practice to use a 
 '•clearing frame." This is an ordinary vertical spindle winding machine, but the yarn is passed through an 
 adjustable nick, which is finely set, so as to catch or stop any knots or other unevenness in the yarn. This 
 
 Fig. 210. 
 
 calls the attendant's notice to the defect, and the thread is re-pieced, so as to remove the lump or knot. 
 The best and most widely used " clearers " are those known as " Suggitt's " patent, and consist of two cast 
 iron plates, one fixed and the other adjustable. Vertical faces are formed on these, which come up to one 
 another throughout their whole length, thus providing an opening or fine nick through which the yarn can 
 be drawn. 
 
 (401) During the past few years it has become customary to dispense with the large flanged bobbins, 
 such as are shown in Figs. 210 and 211, and to wind the yarn into a similar shape on a wooden or paper 
 
274 
 
 REELING, WINDING, AND SPOOLING MACHINERY. 
 
 tube or spool. To do this it is necessary to give a very rapid reciprocal traverse to the guide rail, which 
 is obtained by using a quick pitched cam, one revolution of which will give the double traverse required. 
 In this way, instead of the yarn being wound in fine spirals, it is wrapped in coarsely pitched layers, and 
 it is found that when wound in this manner a cylindrical spool or bobbin can be obtained which does not 
 require the large wooden flanges to prevent it from unravelling at the ends. This object is attained in a 
 winding machine made by Mr. Samuel Brooks by forming a slot, corresponding to the cam course, on the 
 surface of the pulley driving the bobbin. The yarn is taken through the groove on its way to the bobbin, 
 
 K 
 
 J.N. 
 
 Fig. 211. 
 
 and the groove thus acts as a guideway or course. Messrs. Dobson and Barlow employ a quickly pitched 
 cam, and have recently adapted the principle to gassing machines. Messrs. John Hetherington and Sons 
 also make a machine on the same principle, but all the different methods employed have — where a guide rail 
 is actuated — the fault that the working of the cam is rather noisy, and there is still room for an effective 
 noiseless motion of this character. 
 
 (402) Sewing thread requires a special set of machines to fit it for the market. It is sold in one of 
 two forms, either bright or soft finished. Bright thread is polished by being subjected to the action of 
 a rapidly revolving brush. Some of the machines for this purpose made by Messrs. Shepherd and 
 
KEELING, WINDING, AND SPOOLING MACHINERY. 
 
 277 
 
 Ayrton are illustrated, and will serve to show the principle of this class of appliances. The doubled 
 thread is formed into a beam, having first been wound on to special bobbins, 360 of which 
 are placed in a creel, and the threads from them laid side by side on the beam, which is a 
 cylindrical barrel with large flanges at its ends. The thread is then collected into a chain, or loose 
 untwisted rope, and is bleached or dyed by means of a special plant which it is not necessary to 
 describe. Having been so treated, the material is wound on to a beam shown in the machine illustrated 
 in Fig. 212, which is provided with a special adjunct in a machine known as a holding back machine, 
 by which the required tension is put on the thread. After being beamed for the second time the 
 
 Fig. 212. 
 
 thread is passed through the machine shown in Fig. 213. The beam on which it has been wound is 
 shown at the right hand side of this illustration, and contains, as stated, 360 threads. These are first 
 taken through a size box, in which a pure size or starch is placed, and are then passed through the 
 bristles of two cylindrical brushes. The brushes revolve at a high velocity, and thoroughly polish the thread 
 without altering its shape, it being very desirable to preserve its rotundity. At the end of the machine, 
 after being dried, the threads are wound on three brass beams, each divided equally by a central 
 flange. 1 20 threads are wound on each beam, 60 of these being in each of the divisions. These beams 
 T 
 
278 
 
 REELING, WINDING, AND SPOOLING MACHINERY. 
 
 are placed, with the threads on them, contiguous to a special form of winding machine, where they 
 are wound on to wooden spools or bobbins, each of which, when full, contains l^lb. of the finished 
 threads. These are used to feed the spooling or balling machines afterwards described. In preparing 
 soft thread — that is, unpolished thread — a similar procedure is followed, except that, after bleaching or 
 dyeing, the threads, after being dried, are wound on to the second beaming machine. This system is — 
 with special modifications adopted by various manufacturers — the one universally employed. The polishing 
 machine will polish 1201bs. weight of 30's 3-cord thread in 10 hours, and soft thread can be produced 
 in the same numbers at a rate of 5,fi701bs. in 56 hours. The cost in wages of this system is much lower 
 than that of the older method of hank polishing, in addition to which fewer knots are made in the 
 thread, owing to the longer lengths treated continuously. 
 
 (403) When thread is finally produced, by the processes described, in a suitable condition for sale, it is 
 necessary to form it into small reels or bobbins, or into balls, each containing from 100 to 500 yards. The 
 reels on which thread is wound for sale to the consumer are small bobbins in which a short barrel is used, 
 with a head or flange at each end. The flange is bevelled on its inner side, and the length of the opening 
 between the flanges is greater at their peripheries than at their roots. The reels are filled with thread 
 by the action of a machine of great ingenuity called the "spooling machine." This was originally invented 
 by the late Mr. Wm. Wield, and is now made by his successors, Messrs. Shepherd and Ayrton. A perspective 
 view of it is given in Fig. 214, and, as there shown, it has eight heads. The empty spools are placed in a 
 trough, the mouth of which terminates immediately behind the winding head. The latter consists of two 
 spindles which grip the spool in the centre, being formed conically at their extremities, so that they get a 
 firm grip of the hole in the centre of the barrel. The operative mechanism in this machine is fixed in the 
 double frame, or " headstock," shown at the right hand of the machine, and drives, by means of longitudinal 
 shafts and wheels, the spindles of the whole of the heads. The thread is guided by steel guides, threaded 
 on their underside to correspond with the pitch of the spirals formed by the thread, upon which during 
 winding they rest. The guide rods, upon which the guides are fixed, receive an oscillatory movement after 
 the reels are filled, so as to leave the space free for the removal and replacement of the spools. In addition 
 to this they have a reciprocal horizontal traverse equal in length to the length of the spool, and gradually 
 increasing as the surface upon which the thread is wound increases, owing to the bevel of the heads of the 
 reels. This reciprocal movement is obtained from the revolution of a finely pitched screw on a roller, with 
 which two half nuts alternately engage, one on each side of its centre. As these are thrown into gear they 
 give a traverse to the guide rail in each direction, and it will be easily understood that the period of their 
 engagement determines the length of the guide traverse. In commencing to wind a set of reels the first 
 operation is to place them between the spindles. One reel falls out of each trough on to a plate, which 
 rises so as to hold the reel or spool between the open spindles. The spindles close upon the spool, which 
 immediately begins to revolve and draw thread from its bobbin, which, with its fellows, is held in a suitable 
 creel. The thread is passed through a spring tension clip, which holds it sufficiently to keep it tight, and 
 
REELING, WINDING, AND SPOOLING MACHINERY. 
 
 281 
 
 afterwards over the guide referred to. Winding goes on until the required definite length is wound on, when it 
 automatically ceases. Immediately this occurs a knife placed in an arm descends and cuts a nick in one 
 end of the spool, and the thread is drawn into this nick. In this way the end is secured, aud, as soon as 
 this is effected the thread is drawn over a knife and cut. The spindles then open and the spools fall down 
 a shcot. Another set of spools is then fed, as described, and the ends of the thread are so held that, 
 immediately the spindles begin to revolve, they are drawn on to the spools, winding thus beginning 
 automatically. Owing to the perfect automaticity of the machine a high rate of speed is obtained, and 26 
 gross of spools, each containing 200 yards of thread, can be produced from a machine in 101 i 10U rs. 
 
 (404) There are spooling machines in which the operations of feeding and emptying the spools are 
 carried out manually, but, as thread making is now mostly carried out in large establishments, their use is 
 not great. In some cases, especially for "crochet" cottons, the thread is wound into balls. In this case 
 it is wound on short cylinders, revolved at a slow speed, round which a flyer rotates. Through an eye in 
 the flyer the yarn is passed, and is wound on to the cylinders by the superior speed of the flyers. To the 
 former an alternate oscillating movement is given, by which the coils of thread are wound in coarse spirals. 
 In the end a barrel shaped spool is formed. As a rule the "balling" machine is worked by hand, but a 
 machine has been made by which the operation is nearly an automatic one. The use of balling machines 
 is, however, limited, and there is not the necessity for an automatic machine, such as exists in spooling 
 thread, 
 
) 
 
 CHA-PTER XIV. 
 
 MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 (405) It will be easily understood that there are a number of accessories required' to complete the 
 equipment of a mill before the machinery previously described can be fully utilised. It is neither necessary 
 nor profitable to deal with the whole of these, but some of them may be advantageously described. Among 
 the earliest needs in the process of spinning are the cans which are used for the reception of the sliver as 
 it leaves the carding engine. These are made of tin sheets, which are rolled into short cylinders and 
 soldered together, the various lengths being similarly connected. The cans are about 10 inches in diameter 
 and 4 feet long, and are strengthened at the top and bottom by iron hoops. In spite of this precaution 
 they are often bulged or dinted in conssquence of the rough way in ''which they are handled. To obviate 
 this defect Mr. Lang .Bridge has for a few years past made the can with corrugations extending longitudinally 
 of it, the additional strength thus given being advantageous without adding anything to the weight. 
 
 (406) The rollers used in the various operations of spinning and drawing are, as has been pointed out, 
 mainly of two types. The lower lines are generally fluted and the upper lines smooth surfaced. The former are 
 usually made of a fine grained iron, and the flutes are carefully made so as to be very smooth, their pitch 
 depending upon the character of the work to be done. The lower lines of drawing rollers are, as was shown, 
 continuous, and, it being manifestly impossible to make them in one length, they are jointed or coupled at 
 suitable intervals. The coupling is made by forming the roller with a square nipple at one end and a 
 correspondingly formed socket at ( the other. By fitting the nipple of one roller into the socket of the other 
 a firm and perfect union is effected. The rollers are coupled, so that they are perfectly in line throughout, 
 and when placed in the frame they revolve steadily. The top rollers, as previously shown, are formed in 
 short lengths, and are smooth on their peripheries. In order to give a soft yet firm grip to the yarn, as 
 it is delivered, it is customary to cover the top rollers with a sheath of woollen cloth and leather. This is 
 in many cases done by hand, the cloth and leather being cut to length and formed into a sheath in this 
 way, after which it is drawn on to the roller. Such a mode of procedure has all the defects of handwork, 
 and a description of a complete set of machines made by Messrs. Dronsfield Brothers will not be without 
 interest. 
 
 (407) The first of the series is shown in Fig. 215, and is employed to spread the paste upon the cloth. 
 The cloth is fed from a roll, and can be delivered by. a slight addition of mechanism in measured lengths. 
 As it is drawn forward it passes through a paste box formed of sliding plates D, adjoining the spreading 
 plate B. By means of the adjustable screw C the vertical position of the latter can be fixed so as to give 
 
MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 283 
 
 any amount of paste required. The cloth is cut into lengths and wrapped on the roller, to which it 
 adheres, the joint being carefully made so as to leave no gap or thick place. After this surface is 
 prepared and dried a leather sheath is drawn .over it. 
 
 (408) The leather used for covering rollers is specially prepared from sheep skins, and is very thin and soft. 
 It is carefully polished or glazed on one side, and must be free from any roughnesses or defects. In spite of 
 all the care bestowed on their preparation, "roller skins" are often uneven in thickness, and in order to 
 correct this fault, the machine shown in Fig. 216 is used. The skins are cut up by a special appliance into 
 strips of the necessary width to cover the boss of the roller, and these are subjected to a grinding action on 
 their unpolished side. The strips are held at one end by a clamp on the drum A, which is revolved slowly, 
 and which can be set in as desired by the wheel F and screw. As the roller A revolves, it brings the 
 skins in contact with a grinding roller B, covered with sand or glass paper. In this way the leather is 
 ground down to one- thickness throughout the strip, and the chance of unevenness in the roller is thus 
 diminished. A fan is fixed to draw away the dust and deposit it in a suitable receptacle. After the strips 
 
 Fia. 215. 
 
 are so ground, they are passed to a splicing machine— that is, a machine in which they are cut to the necessary 
 length to form a sheath. The edges in this operation are bevelled, so that in overlapping no thick place is 
 formed. The splicing machine in its complete form is shown in Fig. 217. The leather strip A is placed on 
 the table face up, and is carried forward by the feed rollers B. The extent of the roller traverse is determined 
 by the position of a stop D, which limits the oscillatory motion of a double clip handle C. This is made m 
 two parts, like a pair of tongs, each end being centred on the spindle on which the wheel M is placed. By 
 squeezing the handle together M is gripped and can be rotated. The handle C is ordinarily in the position 
 shown, and, when it is moved forward while gripping the wheel, it carries the latter with it until the stop 
 D is reached, when the motion ceases. Thus any length of leather can be fed by one stroke of the handle. 
 When the leather is fed the pressing bars F are brought on to it, and the knife K held in the 
 frame H at a suitable angle is also brought into position. H slides on a cross surface prepared for it, and 
 by drawing it across the leather while held in position, the latter is cut to the required bevel, which remains 
 constant throughout the whole of the working of the machine. 
 
284 
 
 MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 (409) When the short lengths of leather are obtained, they are cemented along their bevelled edges 
 with a special cement, and are firmly pressed together by a light screw press. In this way a sheath is 
 formed large enough to draw over the boss of the roller, but a little longer than it. The covering'so formed 
 is then pulled over the roller by the machine shown in Fig. 218, winch is the type commonly used, however 
 the covering is prepared. The leather tubes are placed upon the spring A, consisting of a thin cylinder of 
 sheet metal, which is divided into several ribs as shown. The roller to be covered is placed end up on the 
 
 Fig. 218. Fig. 219. 
 
 recessed stop B, and by a revolution of the handle C the spring is drawn over the roller leaving the sheath 
 behind it. The special construction of the spring enables it to pass over the boss of the roller and draw out 
 of the leather tube. A small portion of the tube projects beyond the boss at each end, and this it is 
 necessary to wrap over so as to firmly secure the covering. This operation is effected by placing the roller 
 in suitable holders, and subjecting the projecting ends of the tube to an end pressure. For this purpose the 
 rollers are revolved by being brought into frictional contact with a rotating cylinder. The most complete 
 machine for this purpose is shown in Fig. 219. The rollers are held in arms B B on the cylinder A, the 
 bearings or steps in the arms being specially constructed, so as to provide a very thin surface to sustain the 
 roller. The ends of the leather being cemented, they are turned over by means of a rod or bar, and are thus 
 perfectly secured. A fan F is placed under the hood of the machine, and takes away any fumes produced 
 by the process of ending. The cylinder is made of thin steel, and is run at from 700 to 1,000 revolutions 
 per minute. 
 
 (410) Having covered the rollers they are subjected to a rolling pressure, so as to render them perfectly 
 cylindrical. The machine shown in Fig. 220 is a special one of Messrs. Dronsfield Brothers, and consists of a 
 
MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 285 
 
 Fig. 216. 
 
 Fig. 217. 
 
MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 287 
 
 steam chest to which steam is admitted. The upper side of the chest is planed so as to be quite true, aud 
 upon it the rollers are placed. Above the steam chest a table or plate A is imposed, having a reciprocal 
 motion to and fro over the steam chest, derived from the cranks N. Four rollers are fed at one time, and 
 after being subjected to the action of the pressure plate during four of its double movements, are delivered 
 at the other end of the machine. Owing to the heat of the surface on which they are rolled, and the 
 peculiar movement given to them, the rollers emerge in a truly cylindrical form. Ten rollers can be thus 
 rolled per minute, and no difficulty is experienced in attending to the machine. It is, of course, essential 
 that there should be no unevenness of the rollers, and the treatment accorded them by the series of machines 
 described ensures this being avoided. 
 
 Fig. 220. 
 
 (411) It is sometimes the practice to grind the leather covered rollers so as to remove any flats formed 
 during working. Messrs. John Hetherington and Sons make a machine for this purpose. By it the rollers, 
 while held in suitable bearings, are subjected to the action of a revolving grinding disc, covered with glass 
 paper, which traverses the whole surface of the roller and grinds it up perfectly true. The rollers so 
 produced are quite cylindrical, and a large number of the machines are in use. 
 
 (412) The bobbins which are used in the various machines employed are made of specially selected 
 timber, which is kept in stock until it is thoroughly well seasoned. The bobbins are carefully turned, and 
 are smoothly fiuished on their surface, so that the cotton does not adhere to them when it is wound upon 
 
288 
 
 MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 them. Their shape and general construction is well shown in Fig. 221. In this A B and C represent 
 various types of roving bobbins, spools, or " tubes," these being drawn from samples supplied by Messrs. 
 Wilson Brothers, Limited. The tubes are shown of three designs. The one shown at A is single ended — 
 that is, can only be used one end up. In the foot of the tube — which is enlarged— four notches are cut 
 which engage with the projections on the top of the driving bevel pinion described in Chapter X., by means 
 ©f which it is positively driven. A similar construction is shown in C, but this is a shorter tube, suitable 
 for a roving frame, where the lift is less than that of the slubbing frame. B is double ended, and can be 
 used either end up, as desired. It will be noticed that all these tubes are shelled out internally, so as to 
 be very light, and they are so constructed at the top that they fit easily upon the spindle or collar. In 
 this way, while they are steadily held, they can slide without undue friction, which is a somewhat important 
 point. The bosses of the tubes, as shown, are hooped with metal rings or shields. The object of this is 
 to protect them from damage when, after doffing, they are placed upon the spindles, this operation being 
 often very roughly carried out. The tubes are, as stated in Chapters X. and XL, placed in the creels of 
 the roving frames, mule and ring frames, on " skewers," the construction of which is shown at D and E, 
 These are made of ash usually, and are finely pointed, so as to revolve easily and freely. 
 
 /Tl\ 
 
 =E±E 
 i > 
 
 i 
 i 
 
 i 
 
 (413) Bobbins for ring frames are made as shown in F, G and H (Fig. 222). The forms illustrated in F 
 and G are intended for use with Rabbeth spindles, and that marked G is hooped at its lower end for the reasons 
 indicated in the previous paragraph. The bobbin or spool H is used for spinning weft on ring frames, and 
 is much smaller than the type employed for twist yarn. It is a common practice to fit shields to all kinds 
 of bobbins, several makers doing so in one form or another. A special form of ring bobbin is made by 
 
 
 ¥ 
 
 
 
 
 i i 
 
 ,LJ._ 
 \ ) 
 
 
 
 
 ! Q 
 
 
 H r 1 
 
 I j 
 H j 1 
 
 1 ! 
 1 1 
 
 jUj 
 
 1 | 
 1 i 
 
 J 
 
 
 1 
 
 1 i 
 1 \ 
 
 
 1/ LU 
 
 Fig. 222. 
 
MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 Messrs. Wilson Brothers, of Barnsley, in which the grip at the foot is entirely done away with, The bobbin 
 is a double flanged one, something like the type shown by the letter I, but has a projecting lower boss or 
 nipple which loosely fits the spindle cup. This is the invention of Mr. W. K. Sidebottom, of Stockport, and 
 at the time of writing it is undergoing an extensive trial. So far as this has gone the results are 
 favourable, and no loss of twist has been detected although the grip contact does not exist. The bobbin shown 
 by the letter I (Fig. 223), is the form employed for doubling purposes on ring frames, and is driven by the slot 
 shown in the detached plan view. The bobbin L is the form used on throstle spinning frames, as adapted 
 for long collars, somewhat resembling in principle the Mason collar described in Chapter X. 
 
 • — i-J- --, 
 
 J.N. h- 1 — -^3 
 Fig. 223. 
 
 (414) An important improvement in ring bobbins has been j recently adopted by Messrs. Wilson Brothers, 
 Limited. This is a mode of enamelling or coating them with a composition which is entirely impervious to 
 damp. The plan is an American one, but a series of tests made by the author show that bobbins treated 
 in this way can be subjected to the action of hot or cold water or oil without being in the least affected. 
 It is a very usual practice in preparing yarns for weaving purposes to " condition " them — that is, to allow 
 them to absorb a certain amount of moisture. This is often done while they are wound on the spool or 
 bobbin, and the result is that the latter speedily lose their form and become out of balance. By coating 
 them as described this evil is avoided, and yarn can be conditioned with impunity while on the bobbins. 
 
 (415) In order to ascertain the counts of yarn, a machine known as a " wrap reel " is employed. This 
 consists of a small fly or swift similar in form to the swift employed in the reels described in the last 
 chapter, but smaller. This is revolved by a sun and planet arrangement of wheels which is, in principle, 
 
292 
 
 MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 like the differential motion described in Chapter X. A short hank of yarn — one lea or 120 yards — is wound 
 on the wrap reel, the time when the exact length is wound being denoted by the sounding of a bell, when, 
 as the winding is a manual operation, the machine can be stopped. The hank so formed is taken off the 
 reel and weighed, and the weight of a full hank can thus be easily ascertained. By the aid of a table the 
 counts of any of the short hanks wrapped can be easily ascertained. By means of a small machine, the 
 strength of the yarn can be tested, the pull upon it being obtained by a weighted arm. An indicating 
 apparatus is provided, by which the weight of the pull is registered. 
 
 (416) During the past few years one or two simple graduated indicators or scales have been introduced, 
 by which the weight of a piece of cloth can be readily obtained. One of these, " Staub's," has been 
 introduced into this country by_Messrs. George Thomas and Co., and by its aid the counts of either the 
 
 warp or weft in a piece of cloth can be readily ascertained. It differs in form from the scale shown in 
 Fig. 224, but is based upon the same principles. In the form shown in Fig. 224— which is Niess' scale, 
 and is controlled in England by Mr. Charles Lancaster — a light hinged arm is formed at one end with a 
 hook, on which a length of 40 yards of yarn can be hung. This causes the arm to be depressed, and a 
 pointer finger traverses the face of a graduated quadrant, a glance at which is sufficient to show the counts 
 of yarn. These yarn balance are simple and reliable, and are being used in increasing numbers, 
 
 (417) It is customary to fit to spinning machines indicators by which the production is registered. One 
 or two of these, as made by Messrs. G. Orme and Co., are described, but it may be as well to say in passing that 
 
 Fig. 224. 
 
MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 293 
 
 these appliances are largely used, and are very instrumental in preventing disputes as to the remuneration of the 
 operatives in cases where this is determined by the work done. The indicators are attached to the back shaft, 
 and can be made in two forms, either to indicate the number of hanks produced in thousands, or the number 
 of draws made. The first is shown in Fig. 225, the second in Fig. 226, and the details of the mechanism 
 in Figs. 227 and 228. Referring to the latter, an arm B is fixed on a shaft, forming a centre for it, being 
 constructed with two points C and D, acting as catches. On the shaft on which B is centred is a sector A, 
 gearing with a worm on the back shaft. As was pointed out in Chapter X, the back shaft makes an equal 
 number of revolutions in each direction at each draw, so that the sector is caused to oscillate, and partially 
 rotate the shaft. In this way the arm B is also oscillated in the same direction as the sector. The 
 triangular-shaped surface E is fastened on its shaft, and the point D, on the arm B, comes in contact with 
 the notch shown in E, when the end of B is being raised. Thus E is rotated, and when B is reversed as 
 
 Fro. 226. 
 
 described, the point C engages with E, and continues its rotation. While this is occurring the other end 
 of B is descending, so as to assume a position to act on the next point of the triangle. The rotation of 
 E is therefore continuous, and it makes a complete revolution every three draws. On the triangular wheel 
 E is a flange or disc F, in which is secured a pin G. The wheel M is fixed in the position shown, and 
 is constructed with fourteen teeth, half of which are the full width of M, the other half being only half 
 that width, but are a little longer. As F revolves the pin G comes in contact with one of the long teeth 
 in M, and moves it forward. If the disc F were quite circular the overlapping of the broad teeth, as a 
 reference to Fig. 228 will show, would prevent any movement of M. A notch H is therefore cut in the 
 disc, so that only when one of the broad teeth is opposite the notch can any motion of M take place. The 
 motion of M is thus prevented from taking place except when required, and is communicated to the finger 
 of the indicator by the gearing shown. From this description it will be noticed that there are seven 
 operating and seven locking teeth in the wheel M, and in arranging the gearing this fact is considered, 
 u 
 
294 
 
 MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 The figures on the dial represent thousands of hanks, the number being arrived at from a calculation based 
 on the number of spindles and the length of draw of the mule. Where required to meet special local 
 cases, the indicator can be arranged to indicate the number of draws made by the mule. In Figs. 229 and 
 230 the indicator used for slubbing, roving, and drawing frames is shown. Instead of using a graduated 
 
 Fig. 229. 
 
 dial and finger the figures are arranged on discs, of which there are three, one disc registering the decimal 
 part of the hanks passed. The worm shown in Fig. 230 is driven by direct attachment to the front roller. 
 The three' discs are driven from one another, there being a very similar locking motion to that described in 
 
 Fig. 230. 
 
 connection with the mule indicator. The effect of this arrangement is that the first disc has to make a 
 complete revolution before the second is moved one figure. When the second has completed its revolution 
 it in turn moves the third. The discs are locked after each movement, so that until again unlocked no 
 
MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 295 
 
 motion can occur. The indicator is arranged to indicate up to 100 hanks, with decimal parts of each hank. 
 Owing to their special construction no fly can enter the working parts, although there is easy access to 
 them. 
 
 Fig. 227. Fig. 228. 
 
 (418) It was stated in Chapter XT. that it was customary to paste or starch the bottoms of cops, in 
 order to render them adhesive and to stiffen them. Usually the starch used is carried about in buckets, 
 and the method is both dirty and wasteful. Mr. Lang Bridge makes the apparatus shown in Fig. 231, which 
 
 Fig. 231. 
 
 consists of a copper pan in which the starch is boiled, and round the inside of which a copper steam coil is 
 placed. An agitator or dasher is constantly revolved in the manner shown, and a small gun metal pump is 
 driven from the same shaft. By a system of pipes the starch is raised to the various mule rooms, and is 
 
296 
 
 MISCELLANEOUS MACHINES AND ACCESSORIES. 
 
 discharged over enamelled basins placed as shown, the orifice of the pipes being closed by a self-closing tap. 
 The spinner can at any time get a supply of starch, and any surplus returns by gravitation to the mixing 
 tank, where it is again used up. It is obvious that this method possesses many advantages over the Crude 
 mode previously described. 
 
 (419) In concluding these pages the author is fully conscious of many shortcomings, which are inevitable 
 in a task of this magnitude, but he believes that something has been done to formulate present knowledge 
 and practice. Many things could be added, but the intention with which the book was commenced has been 
 carried out, and it is confidently believed that the information given and the treatment accorded to the various 
 machines will be found of value to many students. Any suggestions of improvements or enlargements will 
 be gratefully received, so as to enable future issues to be more valuable and useful. 
 
APPENDIX. 
 
 Description of the Arrangement op Machinery in the Mill op the Standard Spinning Company, 
 
 Limited, Rochdale. 
 
 It will be interesting to many persons to have some particulars of the arrangement of one of the most 
 recently constructed Lancashire mills. The Standard Spinning Company's mill is not only one of the latest 
 but also one of the largest yet built. It consists of five floors and a basement. Each of the main rooms 
 is 250 feet long by 125 feet wide, and adjoining the building on the ground floor is a shed 240 feet long 
 by 40 feet wide, in which most of the cards are placed. The remaining four floors contain the mules 
 Placed a little apart from the main building is the scutching or blowing room, which is 70 feet by 60 feet, 
 and has placed above it two mixing rooms. The general arrangements are shown hi Fig. 232, which is a 
 plan of the ground floor, showing the arrangement of the machinery. 
 
 Referring now to that figure, and dealing first with the mixing and scutching arrangements, the former 
 are shown in the small detached drawing. The arrangement of mixtures and cross lattices is well shown. 
 The three longitudinal lattices shown convey the cotton to the mixing bin, the cross lattice receiving it from 
 the bale breaker, which is placed in the room above. There are four porcupine feed tables employed, each 
 with an extra length of lattice, which deliver the cotton into the dust trunks, by which it is conveyed to 
 the openers fixed in the ground floor room. Of the opening machines there are four, each of which is fed 
 by its special tube or trunk, as clearly shown. The openers are provided with lap attachments, so that the 
 cotton is formed into that shape at as early a point as possible. Adjoining the openers, with their feed end 
 close to the lap machine, six scutching machines with single beaters are placed. These are fed with three 
 laps, and the cotton is, after being treated by them, again formed into laps, which are fed to the six finisher 
 scutchers placed immediately behind the first six. The finishing machines are fed with four laps each 
 the doubling being considerable. It will be noticed that the whole of the arrangements are made so that 
 the cotton moves steadily forward without much handling. In this respect the design is admirable, and this 
 part of the work has been carried out by Messrs. Lord Brothers. 
 
 The carding machines are of the revolving flat type, made by Messrs. John Hetherington and Sons. 
 There are in actual use 128, and each is made with a cylinder 50 inches diameter, being fed from 40-inch 
 laps. The drawing frames adjoin the carding engines, as shown, and are nine in number, each machine 
 having four heads with seven deliveries each, the latter being indicated by the thick black dots. These 
 machines supply drawn slivers to twelve slubbing machines, fitted with long collars, and each containing 90 
 
298 
 
 APPENDIX. 
 
 spindles, their lift being 10 inches. The gauge of these machines is four spindles in 19 inches. Tha 
 slubbing frames can be distinguished by the dotted lines behind them, which represent the position of the 
 cans, and each of them is fed by the drawing machines placed relatively to them as shown by the curved arrows. 
 It will be noticed that the same readiness of access has been kept in view as in the case of the scutching 
 machines, and the necessary carriage of the cans is reduced to a minimum. In addition to the slubbing 
 frames there are 18 intermediate frames, each containing 132 spindles of 10-inch lift and a gauge of six 
 spindles in 19| inches. The equipment of this room is completed by 52 roving machines of 168 spindles 
 each, 7-inch lift, and a gauge of eight spindles in 20£ inches. The whole of the drawing and roving 
 machines are made by Mr. John Mason, and the latter are fitted throughout with Mason's long collars. Before 
 leaving this department a few words may be said about the driving. The machinery is driven from a second 
 motion shaft, driven by ropes from the engine, the engine house and rope race being indicated in the 
 drawing. The carding machines are driven by counter-shafts from the line shaft shown, as are also the 
 drawing frames. The roving machinery, on the contrary, is all directly driven from the line shafts, two of 
 which are specially arranged for the purpose, as clearly shown. The belts are long and have a half twist, 
 but the advantages of direct driving are so great that this slight disadvantage is not worth taking into 
 account 
 
 The mules are of an improved Parr-Curtis type, made by Messrs. Taylor, Lang, and Co., Limited. 
 They are almost equally divided between twist and weft mules. Of the former there are 44 in all, each of 
 which is made of a spindle guage of If inch. Half of them contain 1,038, and the other half 1,044 
 spindles each, in all 45,804 twist spindles. There are also 44 mules for weft, the guage of the spindles 
 being 1£ inch. Twenty-two of these contain 1,260 and twenty-two 1,272 spindles each respectively, giving a 
 total of 55,704 weft spindles. The total number of spindles, therefore, in the mill is 101,508. The numbers 
 spun are from 40's to 50's twist, and 50's to 70's weft. 
 
299 
 
 ■ MUMS 
 
LIST OF ILLUSTRATIONS. 
 
 Note. — In order to facilitate reference to the illustrations, they have been so placed as to be easily found, 
 
 without turning back. It has not, however, always Been possible to place them in consecutive and proper 
 
 order. To preserve the sequence, they are numbered in the order in which they are referred to in the 
 text, although — especially in Chapter XL— they are sometimes referred to in paragraphs widely apart. 
 
 Fig. Page. 
 
 1, 2 The cotton gin 16 
 
 3 Elephant opener ... ... ... ... ... ... ... ... ••• ••• 17 
 
 4 Bale breaker ... ... ... ... ... ... ... ... 17 
 
 5 Dobson and Barlow's bale breaker ... ... ... ... ... ... ... 19 
 
 6,7 Diagrams of mixing arrangements ... ... ... ... . . ... ... 20 
 
 8 Diagram of mixing arrangements ... ... ... ... ... ... ... ... 21 
 
 9 Taylor, Lang, and Company's opening machine 25 
 
 10 Dobson and Barlow's opening machine ... .... ... ... ... 25 
 
 11, 12 Lord Brothers' porcupine cylinders ... ... ... ... ... ... ... 26 
 
 13 Diagram of mixing and opening ... ... ... ... ... ... ••• ••• 27 
 
 14 Piatt Brothers and Company's opening machine 28 
 
 15 Crighton and Sons' opening machine 29 
 
 16 Section of opener grid, ordinary type 30 
 
 17 Crighton and Sons' improved opener ... ... ... ••• ••• 29 
 
 18 Longitudinal section of Crighton's improved grid 30 
 
 19 Cross section of Crighton's improved grid 30 
 
 20 Lord Brothers' combined porcupine and Crighton opening machine 33 
 
 21 Piatt Brothers and Company's improved dust trunk 34 
 
 22 Lord Brothers' single scutching machine... ... ... ... ... ••• ••• 36 
 
 23 Lord Brothers' single scutching machine, end view ... ... ... ... ... 38 
 
 24 Howard and Bullough's improved grid for scutching machine... 38 
 
 25 Crighton and Sons' scutching machine ... ... ... ... ... ••• ••• 39 
 
 26 Crighton and Sons' leaf extractor 40 
 
 27 Piatt Brothers and Company's scutcher diagram of dead plate 41 
 
 28, 29, 30, 31 Lord Brothers' piano feed motion 43 
 
302 
 
 LIST OF ILLUSTRATIONS. 
 
 Fia Page. 
 
 32 Piatt Brothers and Company's old form of pedal nose ... ... ... 44 
 
 33 Piatt Brothers and Company's new form of pedal nose ... ... ... ... 44 
 
 34 Old and new arrangement of pedal bowls ... ... ... ... 44 
 
 35 Piatt Brothers and Company's rope driving for cones ... ... ... ... ... 45 
 
 36 Piatt Brothers and Company's pedal regulator ... ... ... ... ... ... 46 
 
 37, 38 Dobson and Barlow's pedal regulator ... ... ... ... ... ... ... 49 
 
 39,40 Asa Lees and Company's pedal regulator ... ... ... ... ... ... 49 
 
 41 Asa Lees and Company's rope driving for cones ... ... ... ... ... 48 
 
 42 Plan of mixing room lattices. Piatt Brothers and Company ... ... 50 
 
 43 Plan of scutching room. Piatt Brothers and Company ... ... ... ... 50 
 
 44 Ashworth Brothers' revolving flat carding engine ... ... ... ... ... 63 
 
 45 Vertical section of coder ... ... ... ... ... ... ... 59 
 
 46 Diagram of roller carding engine... ... ... ... ... ... ... ... 56 
 
 47 Perspective view of Mason's roller carding engine ... ... ... ... ... 57 
 
 48 John Hetherington and Sons' stripper for roller carding engiue ... ... ... 60 
 
 49 Lord Brothers' setting bracket for roller carding engine ... ... ... ... 60 
 
 50 Leigh's flexible bend 65 
 
 51 Hetherington's old construction of flat ... ... ... ... ... ... ... 66 
 
 52 Hetherington's new construction of flat 66 
 
 53 Hetherington's transverse section of bend milling apparatus ... ... ... ... 67 
 
 54 Hetherington's side elevation of bend milling apparatus ... ... .. ... 67 
 
 55 Piatt Brothers' new setting of flats 69 
 
 56 Piatt Brothers' old setting of flats ... 69 
 
 57 Perspective view Piatt's card 68 
 
 58 Diagram of Dobson and Barlow's bend 71 
 
 59 Front view of Dobson and Barlow's bend 71 
 
 60 Front view of Howard and Bullough's bend 70 
 
 61 Section of Howard and Bullough's bend... 73 
 
 62 Front view of Knowles' bend 73 
 
 63 Diagram of Knowles' bend - 74 
 
 64 Ashworth's bend 75 
 
 65 Side elevation of Brooks' carding engine... ... ... ... ... ... ... 76 
 
 66 Front view of milling arrangement of Brooks' carding engine ... 77 
 
 67 Sectional view of milling arrangement of Brooks' carding engine ... ... ... 77 
 
 68 Side elevation of Wellman card 80 
 
LIST OP ILLUSTRATIONS. 
 
 303 
 
 Fig. 
 
 
 Page. 
 
 69 
 
 Dobsou and Barlow's dish feea 
 
 83 
 
 70 
 
 Lap before acted on by licker-in 
 
 89 
 
 71 
 
 Lap after being acted on by licker-in 
 
 89 
 
 72 
 
 Dobson and Barlow's doffer covers 
 
 84 
 
 73 
 
 Dobson and Barlow's pedestal 
 
 87 
 
 74 
 
 Ashworth Brothers' driving arrangement... 
 
 87 
 
 75 
 
 Enlarged view of doffer fleece ... ... ... ... ... 
 
 89 
 
 76 
 
 Diagram of card setting 
 
 92 
 
 77 
 
 Diagram of Garnett teeth for licker-in ... 
 
 93 
 
 78 
 
 Diagram of setting of teeth 
 
 95 
 
 79 
 
 Enlarged view of needle pointed teeth ... 
 
 97 
 
 80 
 
 Enlarged view of side ground tooth 
 
 97 
 
 81 
 
 Enlarged view of side ground tooth 
 
 97 
 
 82 
 
 Whiteley's fillet winding drum 
 
 99 
 
 83 
 
 Riveted and sewn flats 
 
 101 
 
 84 
 
 Dronsfield's fillet stretcher for flats 
 
 103 
 
 .35 
 
 Perspective view of Whiteley's clip 
 
 103 
 
 86 
 
 Transverse section of flat with Whiteley's clip ... 
 
 103 
 
 87 
 
 Longitudinal section of flat with Whiteley's clip 
 
 ... , 103 
 
 88 
 
 Transverse section of Tweedale's fastener 
 
 103 
 
 89 
 
 Sykes' slow motion ... 
 
 106 
 
 90 
 
 Transverse section of Hetherington's slow motion 
 
 106 
 
 91 
 
 End view of Hetherington's slow motion... 
 
 106 
 
 92 
 
 Side view of card with Hetherington's slow motion 
 
 106 
 
 93 
 
 Side view of Brooks' slow motion... 
 
 107 
 
 94 
 
 End view of Brooks' slow motion... 
 
 107 
 
 95 
 
 Side view of Knowles' slow motion 
 
 108 
 
 96 
 
 Sectional view of Knowles' slow motion ... 
 
 108 
 
 97 
 
 Dronsfield's grinding roller... ... 
 
 108 
 
 98, 99 
 
 End views of Dronsfield's grinding roller 
 
 ... <• 109 
 
 100, 101, 102 
 
 Views of emery filleting ... ... ... ... ... ... 
 
 109 
 
 103 
 
 Horsfall grinding roller 
 
 110 
 
 104 
 
 Diagram of flat and wire ... 
 
 Ill 
 
 105 
 
 Knowles' flat grinding apparatus ... 
 
 Ill 
 
 106 
 
 Hetherington's flat grinding apparatus ... 
 
 112 
 
304 
 
 LIST OF ILLUSTKATIONS. 
 
 Fig. Page. 
 
 107 Edge's flat grinding apparatus 114 
 
 108 Higginson's flat grinding apparatus ... ... ... ... ... ... ... 115 
 
 109 Piatt's flat grinding apparatus ... ... ... ... ... ... 116 
 
 110 Dronsfield's roller grinding machine ... ... ... 118 
 
 111 Whiteley's stripping brush ... ... ... ... ... ... ... ... 119 
 
 112 Dobson and Barlow's sliver lap machine... ... ... ... ... ... ... 123 
 
 113 Dobson and Barlow's ribbon lap machine ... ... ... ... ... ... 121 
 
 114 Transverse section of Heilmann combing machine ... ... ... ... ... 127 
 
 115 Enlarged section of Heilmann combing machine ... ... ... ... ... 122 
 
 116 Enlarged section of nipper mechanism of Heilmann combing machine ... ... 125 
 
 117 Front view, Hetherington's improved nipper ... ... ... ... ... ... 130 
 
 118 Sectional view, Hetherington's improved nipper... ... ... ... ... ... 130 
 
 119 Perspective view, Dobson and Barlow's combing machine ... ... ... ... 131 
 
 120 Transverse section, Dobson and Barlow's combing machine ... ... ... ... 134 
 
 121 Side view, detaching mechanism, Dobson and Barlow's combing machine ... ... 133 
 
 122 Plan, detaching mechanism, Dobson and Barlow's combing machine ... ... ... 133 
 
 123 End view, Brooks' drawing frame ... ... ... ... ... ... ... 139 
 
 124 Transverse section, Brooks' drawing frame ... ... ... ... ... ... 139 
 
 125 Front view, Brooks' drawing frame ... 139 
 
 126 Elevation and section, Leigh's loose boss rollers ... .. ... ... ... 138 
 
 127 Howard and Bullough's electric stop motion ... ... ... ... ... ... 146 
 
 128 Front view, Mason's slubbing frame ... ... ... ... ... .. ... 149 
 
 129 Sectional elevation, Mason's long collar ... ... ... ... ... ... ... 151 
 
 130 Sectional elevation, Higgins' spindle ... ... ... ... ... ... ... 153 
 
 131 Elevation of Higgins' spindle ... ... ... ... ... ... 153 
 
 132 Diagram of winding on roving frames ... ... ... ... ... ... ... 156 
 
 133 Diagram of winding on roving frames ... ... ... ... ... ... ... 156 
 
 134 Back view of roving frame ... ... ... ... ... ... ... ... 159 
 
 135 Plan, Johnson's cone motion ... ... ... ... ... ... ... ... 161 
 
 136 Elevation, Johnson's cone motion ... ... ... ... ... ... ... 161 
 
 137 Section of differential motion ... ... ... ... ... ... ... ... 163 
 
 138 Curtis and Rhodes's differential motion ... ... ... ... ... ... 164 
 
 139 Tweedale's differential motion ... ... ... ... ... ... ... ... 165 
 
 140 .Front view of building motion ... ... ... ... ... ... ... ,..167 
 
 141 jiack view of building motion ... . ... ... , 169 
 
LIST OF ILLUSTRATIONS. 
 
 305 
 
 Fig. 
 
 
 Page. 
 
 142 
 
 Plan of building motion ... 
 
 169 
 
 143 
 
 Elevation of Paley's traverse motion 
 
 173 
 
 144 
 
 End view of Paley's traverse motion 
 
 173 
 
 145 
 
 Plan of Paley's traverse motion 
 
 173 
 
 146 
 
 Section of Paley's traverse motion ... 
 
 173 
 
 147 
 
 Diagram of variations of traverse ... 
 
 174 
 
 148 
 
 Diagram of mnle (essential parts) ... 
 
 178 
 
 149 
 
 Front view of Piatt's mule .., 
 
 181 
 
 150 
 
 Back view of Piatt's mule ... 
 
 181 
 
 151 
 
 Diagram of setting of a pair of mules 
 
 180 
 
 152 
 
 Diagram of driving bands for mule 
 
 185 
 
 153 
 
 Longitudinal section of mule driving mechanism ... 
 
 185 
 
 154 
 
 Back view of mule driving mechanism 
 
 185 
 
 155 
 
 End view of rope attachment to end frame 
 
 187 
 
 156 
 
 Diagram of cam shaft and connections ... ... ... ... 
 
 191 
 
 157 
 
 Plan view of duplex driving ... ... ... ... 
 
 191 
 
 158 
 
 Diagram of belt guiding mechanism 
 
 ' 195 
 
 159 
 
 Counter faller regulator ... ... ... ... ... ...... 
 
 198 
 
 160 
 
 Backing-off mechanism 
 
 197 
 
 161 
 
 Diagram of copping arrangement ... ... 
 
 205 
 
 162 
 
 Diagram of taking-in and holding out 
 
 201 
 
 163 
 
 Diagram of building of cop ... 
 
 207 
 
 164 
 
 Diagram of coils on nose of cop 
 
 207 
 
 165 
 
 Diagram of copping rail arrangement 
 
 204 
 
 166 
 
 Diagram of winding barrel movement 
 
 208 
 
 167 
 
 Diagram of movement of quadrant arm 
 
 211 
 
 168 
 
 Diagram of winding mechanism 
 
 212 
 
 169 
 
 Diagram of winding chain tightening motion 
 
 215 
 
 170, 171 
 
 Diagram of position of scrolls beginning and end of set ... 
 
 216 
 
 172 
 
 Diagram of winding-on motion for chain ... 
 
 221 
 
 173 
 
 Diagram of ordinary arrangement of cam shaft ... 
 
 220 
 
 174 
 
 Section of pendant plate and clutch 
 
 221 
 
 175 
 
 Front view of pendant plate 
 
 221 
 
 176 
 
 Side view of Hetherington's mule ... ... 
 
 . ... ... 222 
 
 177 
 
 Back view of Hetherington's mule ... 
 
 223 
 
306 
 
 LIST OF ILLUSTRATIONS. 
 
 Fig. 
 
 
 Page. 
 
 1 7R 
 
 1 ( o 
 
 Elevation of Dobson and Hardman's nosing motion 
 
 224 
 
 1 7Q 
 1(3 
 
 Enlarged view of Dobson and Hardman's nosing motion ... 
 
 225 
 
 ISA 
 
 lOU 
 
 Dobson and Barlow's governing motion ... 
 
 227 
 
 lol 
 
 Dub's governing motion 
 
 229 
 
 
 Side elevation of Curtis' mule without cam shaft 
 
 230 
 
 loo 
 
 Plan of Curtis' mule without cam shaft 
 
 230 
 
 104 
 
 Inclined carriage slips for mules 
 
 231 
 
 loO 
 
 Front view of Brooks' ring spinning frame 
 
 237 
 
 loo 
 
 End view of Brooks' ring spinning frame 
 
 235 
 
 187 
 
 Transverse section of Brooks' ring spinning frame 
 
 236 
 
 loo 
 
 Longitudinal partial section of one spindle and roller stand 
 
 243 
 
 i on 
 
 lyy 
 
 Common nag spindle 
 
 243 
 
 1 QA. 
 
 iyu 
 
 .Booth bawyer ring spindle 
 
 243 
 
 iyi 
 
 Kabbeth ring spindle 
 
 245 
 
 192 
 
 Wnitin gravity ring spindle 
 
 245 
 
 193 
 
 Dodd ring spindle 
 
 245 
 
 194 
 
 Bernhardt's bee spindle and anti-balloon er 
 
 249 
 
 lyo 
 
 Single ring ... 
 
 247 
 
 196 
 
 lil "l 1 i ii • i i i i 
 
 (Joulthard s double ring and holder 
 
 247 
 
 197 
 
 "V. 
 
 Diagram of winding on ring frames 
 
 251 
 
 198 
 
 Elevation of spindle with Lancaster's traveller ... ... ... 
 
 253 
 
 199 
 
 Perspective view of ring and Lancaster's traveller 
 
 253 
 
 ZOO 
 
 Plan ot Piatt s ring and traveller 
 
 253 
 
 OA1 
 
 section ot Piatt s ring and traveller 
 
 253 
 
 oao 
 
 TT nTTTn ...J „„J T) 11 ^ 1 J Pi • • ty 
 
 Howard and Pulloughs weft spinning frame 
 
 255 
 
 OAQ 
 ZOO 
 
 A T J /"n > i • • /% . • ii 
 
 Asa Lees and Co. s rope driving for tin rollers... 
 
 254 
 
 204 
 
 Stubbs' bobbin reel 
 
 263 
 
 OAK 
 
 zOo 
 
 Elevation of seven-lea arrangement 
 
 267 
 
 206 
 
 Section of shell for swift end 
 
 266 
 
 207 
 
 Guest and Brooks' skeining motion 
 
 268 
 
 208 
 
 Elevation of bundling press 
 
 269 
 
 209 
 
 Perspective view of doubling winding machine ... 
 
 271 
 
 210 
 
 Transverse section of doubling winding machine 
 
 273 
 
 211 
 
 Section of one head of gassing machine ... 
 
 274 
 
 212 
 
 Thread beaming machine ... 
 
 277 
 
LIST OF ILLUSTRATIONS. 307 
 
 Fig. Page. 
 
 213 Thread polishing machine ... ... ... ... ... ... ... 275 
 
 214 Wield's spooling machine ... ... ... ... ... ... ... ... ... 279 
 
 215 Dronsfield's cloth pasting machine ... ... ... ... ... ... ... 283 
 
 216 Dronsfield's leather grinding machine ... ... ... ... ... ... ... 285 
 
 217 Roller leather splicing machine ... ... ... ... ... ... ... ... 285 
 
 218 Roller pulling machine ... ... ... ... ... ... ... 284 
 
 219 Roller ending machine ... ... .. ... ... ... ... ... ... 284 
 
 220 Roller trueing machine ... ... ... ... ... ... ... ... ... 287 
 
 221 Roving bobbins 289 
 
 222 Ring spinning bobbins ... ... ... ... ... ... ... ... ... 288 
 
 223 Ring doubling and throstle bobbins ... ... ... ... ... ... ... 291 
 
 224 Niess' yarn scale 292 
 
 225 Mule indicator for hanks ... ... ... ... ... ... ... ... ... 293 
 
 226 Mule indicator for draws ... ... ... ... ... ... ... ... ... 293 
 
 227 Side view of indicator mechanism ... ... ... ... ... ... ... ... 295 
 
 228 End view of indicator mechanism ... ... ... ... ... ... ... ... 295 
 
 229 Front view of indicator for slubbing frames ... ... ... ... ... ... 294 
 
 230 Back view of indicator for slubbing frames... ... ... ... ... ... ... 294 
 
 231 Bridge's paste pump... ... ... ... ... ... ... ... ... ... 295 
 
 232 Plan of card room of Standard Spinning Company Limited ... ... ... ... 299 
 
GLOSSAEY. 
 
 Changes- In a mule the alteration of the motion of the 
 various parts at the end of the outward and 
 inward runs. 
 
 Chase- The extent of the traverse of the winding 
 
 faller wire. 
 
 Cop. The spool of yarn formed on a mule. 
 
 Counts- The number of hanks of yarn in one pound 
 
 weight. 
 
 Creel. A frame in which feed bobbins are placed. 
 
 Doffer. In carding, the drum removing the fleece from 
 
 the cylinder ; the person removing bobbins 
 or cops from the spindles. 
 
 Doffing- The process of removing finished material 
 
 from the machines. 
 
 Doubling- The combination of two or more laps, slivers, 
 or threads ; as a separate process the twisting 
 together of strands of yarn. 
 
 Draught. The amount of attenuation of a lap or sliver. 
 
 Draw- The longitudinal traverse of a mule carriage. 
 
 Droppings. The impurities removed from cotton during 
 opening or scutching. 
 
 End- One strand of sliver, roving, or yarn. 
 
 Fillet- A narrow strip of cloth. 
 
 Fly. The loose short fibres given off during 
 
 spinning. 
 
 Gauge- The distance from centre to centre of spindles 
 
 or rollers. 
 
 Governing. The regulation of the traverse of the quadrant 
 nut. 
 
 Halching. The entanglement of the coils of yarn at a cop 
 nose. 
 
 Hank- A length of 840 yards of yarn. 
 
 Lap. A rolled fleece of cotton. 
 
 Lea. One seventh of a complete hank. 
 
 Lead. The excess of the revolution of a bobbin, flyer, 
 
 or traveller over each other. 
 Licking. The adhesion of cotton fibres to any surface. 
 
 Lift. The extent of the traverse of a guide eye or 
 
 bobbin. 
 
 Motes. Fragments of broken seed or leaf. 
 
 NepS- Small knots or tangles of fibres. 
 
 Nose- The extreme upper point of a cop. 
 
 Piecing. The union of two ends of sliver, roving, or yarn. 
 
 Poker. The vertical rod sustaining a bobbin or ring 
 
 rail. . 
 
 Roller Laps. Coils of roving or yarn wrapped on rollers 
 after breakage. 
 The attenuated and partially twisted sliver. 
 
 Roving. 
 
 Selvedge. 
 Shaper. 
 
 Single. 
 
 Skeining. 
 Sliver. 
 
 Slubhing. 
 
 Slubs. 
 
 Snarls. 
 Staple. 
 
 Stretch. 
 Stripping. 
 
 Twist. 
 
 Warp. 
 Weft. 
 
 Yarn. 
 
 The edge of a lap or sliver. 
 
 The mechanism by which the shape of a cop 
 
 is determined. 
 A length of sliver, roving, or yarn in which 
 
 only one strand exists. 
 The process of winding yarn into hanks. 
 The attenuated fleece of cotton from carding 
 
 or combing machine. 
 The sliver after having passed through the 
 
 first roving machine. 
 Thick pieces of cotton attached to or twisted 
 
 into the yarn, caused by accumulation of fly. 
 Small twisted loops of yarn. 
 The length of individual fibres in any grade 
 
 of cotton. 
 
 The longitudinal traverse of a mule carriage. 
 Removing the imbedded impurities from card 
 clothing. 
 
 The number of turns per inch in a thread or 
 yarn ; yarn used for warps. 
 
 Yarn forming the longitudinal threads in cloth. 
 Yarn forming the transverse threads in cloth. 
 
 The fully twisted roving. 
 
GENERAL INDEX. 
 
 A 
 
 Par. Page. 
 
 Acceleration of winding velocity in mule 
 
 330 
 
 211 
 
 Action of building motion in roving machines ... 
 
 252 
 
 168 
 
 Action of building ratcheb wheel in roving 
 
 
 
 machines 
 
 257 
 
 171 
 
 Action of combing machine 
 
 198 
 
 126 
 
 Action of copping mechanism 
 
 322 
 
 205 
 
 Action of mule at end of draw 
 
 289 
 
 189 
 
 Action of fallers in mule 
 
 303 
 
 194 
 
 Action of plate wheel in roving machines 
 
 244 
 
 162 
 
 Action of rollers of mule 
 
 267 
 
 177 
 
 Advantages of rotation of backing-off wheel 
 
 296 
 
 190 
 
 Air current, conveyance of cotton by 
 
 63 
 
 32 
 
 Air current, effect of passages on 
 
 79 
 
 41 
 
 Air current in scutchers, velocity of 
 
 78 
 
 40 
 
 American cotton 
 
 21 
 
 13 
 
 Amount of lift in roving machines 
 
 233 
 
 154 
 
 Angularity of brackets in ring frames 
 
 370 
 
 210 
 
 Angularity of thread in mule3 
 
 360 
 
 229 
 
 Asa Lees and Company s rope driving for nng 
 
 
 
 frames 
 
 383 
 
 254 
 
 Asa Lees and Company's rope driving for scutchers 
 
 92 
 
 48 
 
 Ashworth Brothers' cylinder setting 
 
 129 
 
 75 
 
 Ashworth Brothers' cylinder driving 
 
 149 
 
 85 
 
 Ashworth Brothers' revolving flat carding machine 
 
 129 
 
 75 
 
 Attachment of cards to cylinders and doffeis ... 
 
 164 
 
 96 
 
 Attachment of cards to flats by rivets 
 
 166 
 
 101 
 
 Attachment of cards to flats by sewing 
 
 166 
 
 101 
 
 Attachment of cards to flats by clips ... 
 
 166 
 
 101 
 
 Attachment of carriage end frame bands 
 
 284 
 
 187 
 
 Attachment of pressers 
 
 228 
 
 148 
 
 Attachment of roving to mule spindles 
 
 267 
 
 177 
 
 B 
 
 
 
 Back shaft connection with scroll shaft 
 
 315 
 
 202 
 
 Back shaft connection of quadrant with 
 
 327 
 
 209 
 
 Back shaft clutch, shape of teeth 
 
 284 
 
 187 
 
 Back shaft clutch, disengagement of 
 
 293 
 
 190 
 
 
 Pap. 
 
 Page. 
 
 Back shaft, driving of 
 
 ... 284 
 
 184 
 
 Back shaft, driving of, ordinary method 
 
 ... 351 
 
 221 
 
 Back shaft, position of scrolls 
 
 ... 284 
 
 187 
 
 Backing-off chain, tightening motion 
 
 ... 307 
 
 198 
 
 Backing-off clutch, engagement of 
 
 ... 299 
 
 193 
 
 Backing-off clutch, release of 
 
 ... 312 
 
 200 
 
 Backing-off, compression of spring 
 
 ... 300 
 
 193 
 
 Backing-off, constant rotation of wheel 
 
 ... 296 
 
 190 
 
 Backing-off, driving of wheel 
 
 ... 282 
 
 194 
 
 Backing-off, effect of driving wheel 
 
 ... 283! 
 
 184 
 
 Backing-off lever, release of 
 
 ... 301 
 
 194 
 
 Backing-off, operation of 
 
 ... 270 
 
 177 
 
 Backing-off, holdiog out catch during 
 
 ... 310 
 
 200 
 
 Backing-off, parts at end of 
 
 ... 311 
 
 200 
 
 Bale breaker 
 
 28 
 
 17 
 
 Bale breaker, construction of rollers 
 
 33 
 
 19 
 
 Bale breaker, Dobson and Barlow's 
 
 34 
 
 19 
 
 Bale breaker, draught of 
 
 30 
 
 18 
 
 Baling of cotton 
 
 27 
 
 16 
 
 Balling machines 
 
 ... 404 
 
 281 
 
 Bands, check , . ... 
 
 ... 315 
 
 202 
 
 Bands, tension of spindle 
 
 ... 280 
 
 183 
 
 Bands, mule end frame 
 
 284 
 
 187 
 
 Bands, course of rim 
 
 ... 281 
 
 183 
 
 Beaters, balancing scutcher 
 
 68 
 
 36 
 
 Beaters, blow of 
 
 69 
 
 37 
 
 Beaters, construction of scutcher 
 
 68 
 
 36 
 
 Beaters, space between grid and arms of ... 
 
 59 
 
 31 
 
 Beaters, pulsations of 
 
 70 
 
 37 
 
 Beaters, two and three winged 
 
 69 
 
 36 
 
 Beaters, velocity of opener 
 
 55 
 
 30 
 
 Beaters, velocity of Lord's opener 
 
 58 
 
 31 
 
 Beaters, velocity of scutcher 
 
 69 
 
 36 
 
 Bearings, Higgins' roving spindle 
 
 ... 230 
 
 152 
 
 Belts, main driving speeds 
 
 13 
 
 10 
 
 Bend, Mason's concentric 
 
 ... 113 
 
 60 
 
 Bend, Dobson and Barlow's 
 
 ... 125 
 
 69 
 
 Bend, easy adjustment of flexible 
 
 ... 134 
 
 78 
 
 Bend, Hetherington's setting of 
 
 ... 121 
 
 66 
 
310 GENERAL INDEX. 
 
 
 Par. 
 
 Page. 
 
 
 Par. 
 
 Page. 
 
 Ben<il, Hetherington's trueing of 
 
 121 
 
 66 
 
 Cans, Bridge's corrugated 
 
 405 
 
 282 
 
 Ti 3 TT 3 J T> 1 1 1 J 
 
 Bend, Howard and Bullough s 
 
 127 
 
 70 
 
 Cans, Piatt's full stop motion 
 
 221 
 
 145 
 
 Bend, Knowles' 
 
 128 
 
 73 
 
 Cans, position in coiler 
 
 110 
 
 55 
 
 Bencl, Legh s flexible 
 
 119 
 
 65 
 
 Cans, sliver 
 
 405 
 
 282 
 
 T\ T 1 ill ft "11 
 
 Bend, Piatt s flexible 
 
 122 
 
 67 
 
 Carding, importance of 
 
 190 
 
 119 
 
 Bend, Piatt's inspection of setting of 
 
 137 
 
 79 
 
 Card clothing, attachment to flats by rivets 
 
 166 
 
 101 
 
 Bend, position of flexible 
 
 120 
 
 66 
 
 Card clothing, attachment to flats by sewing ... 
 
 166 
 
 101 
 
 Bend, setting brackets for 
 
 113 
 
 60 
 
 Card clothing, attachment to flats by clips 
 
 166 
 
 101 
 
 Bend, setting flexible 
 
 119 
 
 65 
 
 Card clothing, attachment to flats by Piatt's clip 
 
 169 
 
 105 
 
 Bend, theory of flexible 
 
 118 
 
 64 
 
 /~i T "111 " _j i * £ £ 3 1 * 
 
 Card clothing, construction of foundation 
 
 154 
 
 91 
 
 Bobbins, coated 
 
 414 
 
 291 
 
 Card clothing, counts of wire 
 
 156 
 
 92 
 
 Bjbbins, doubling and throstle 
 
 A 1 O 
 
 291 
 
 Card clothing, counts used 
 
 157 
 
 93 
 
 Bobbins, driving roving 
 
 232 
 
 IDO 
 
 Card clothing, defects of side grinding 
 
 159 
 
 94 
 
 Bobbins, lead, reisons for 
 
 237 
 
 156 
 
 Card clothing, deflection of fiats 
 
 167 
 
 102 
 
 Bobbins, lift of 
 
 233 
 
 154 
 
 Card clothing, desirability of light grinding ... 
 
 163 
 
 95 
 
 Bobbins and flyer leads 
 
 240 
 
 lyo 
 
 Card clothing, improved side grinding 
 
 162 
 
 95 
 
 Bobb'ns, principle of driving roving 
 
 239 
 
 157 
 
 Card clothing, machine for winding fillets 
 
 165 
 
 96 
 
 Bobbins, retardation of roving 
 
 238 
 
 157 
 
 Card clothing, manufacture of fillets 
 
 155 
 
 91 
 
 Bobbins, ring frame 
 
 413 
 
 288 
 
 Card clothing, mode of attaching fillets 
 
 164 
 
 96 
 
 Bobbins, roving 
 
 ... 412 
 
 287 
 
 Card clothing, Piatt s fastener for 
 
 169 
 
 105 
 
 Bobbins, Sidebotham's patent 
 
 413 
 
 291 
 
 Card clothing, preparation before fixing 
 
 164 
 
 96 
 
 Brazilian cotton 
 
 20 
 
 13 
 
 Card clothing, principles of setting 
 
 158 
 
 93 
 
 Brooks' adjustment of flats in card ... ... 
 
 131 
 
 II 
 
 Card clothing, setting teeth ... 
 
 156 
 
 92 
 
 Brooks' drawing machine 
 
 208 
 
 137 
 
 Card clothing, shape of teeth 
 
 159 
 
 94 
 
 Brooks' ring spinning machine 
 
 367 
 
 234 
 
 Card clothing, side grinding of teeth 
 
 159 
 
 94 
 
 Brooks' revolving flat card 
 
 130 
 
 76 
 
 Card clothing, striation of teeth 
 
 161 
 
 94 
 
 Brooks' slow motion for card 
 
 174 
 
 107 
 
 Card clothing, teeth of licker-in 
 
 157 
 
 93 
 
 Building motion, action of 
 
 252 
 
 168 
 
 Card clothing, Tweedale's clip for 
 
 168 
 
 102 
 
 Building motion, construction of 
 
 ..... 251 
 
 167 
 
 Card grinding, best speed of cylinder 
 
 170 
 
 105 
 
 Building motion, objects of ... 
 
 Zbv 
 
 166 
 
 Card grinding, Brooks' slow motion for 
 
 174 
 
 107 
 
 Building motion, reversal of lift by 
 
 OKA 
 
 
 Card grinding, construction of brackets 
 
 178 
 
 110 
 
 Building motion, roving frame 
 
 250 
 
 166 
 
 Card grinding, Dronsfield's emery fillets 
 
 176 
 
 109 
 
 Bundling press 
 
 one 
 £>90 
 
 Zbl 
 
 Card grinding, Edge's flat apparatus 
 
 182 
 
 113 
 
 
 
 
 Card grinding, Hetherington's flat apparatus . . . 
 
 181 
 
 112 
 
 
 
 
 Card grinding, Hetherington's slow motion 
 
 172 
 
 106 
 
 c 
 
 
 
 Card grinding, Higginson's flat apparatus 
 
 183 
 
 1 1 A 
 
 114 
 
 
 
 
 Card grinding, Horsfall roller 
 
 177 
 
 109 
 
 Cages, Crighton s construction of 
 
 76 
 
 39 
 
 Card grinding, Knowles' and Tatham's flat apparatus 1 80 
 
 111 
 
 Cages, position of 
 
 67 
 
 35 
 
 Card grinding, Knowles' slow motion 
 
 175 
 
 108 
 
 Calender rollers of carding engines 
 
 ... 109 
 
 55 
 
 Card grinding, machine for rollers 
 
 186 
 
 117 
 
 Calculation of counts 
 
 ... 387 
 
 257 
 
 Card grinding, machine for Well man flats 
 
 187 
 
 118 
 
 Calculation of hank roving 
 
 ... 387 
 
 257 
 
 Card grinding, Piatt's flat apparatus 
 
 184 
 
 116 
 
 Cam shaft, effect of first half turn of ... 
 
 ... 292 
 
 190 
 
 Gard grinding, principles of flat 
 
 179 
 
 110 
 
 Cam shaft, effect of second half turn of 
 
 ... 345 
 
 218 
 
 Card grinding, rollers used in 
 
 176 
 
 108 
 
 Cam shaft, ordinary position of 
 
 ... 350 
 
 220 
 
 Card grinding, Sykes' slow motion 
 
 171 
 
 105 
 
 Cam shaft, position of cams on 
 
 ... 291 
 
 189 
 
 Carding machine, action of cylinder 
 
 151 
 
 86 
 
 Cans, arrangement in drawing machine 
 
 ... 215 
 
 143 
 
 Carding machine, action of licker-in 
 
 150 
 
 85 
 
GENERAL INDEX 
 
 3U 
 
 Par. Page. 
 
 Carding machine, Ashworth's 
 
 129 
 
 74 
 
 Carding machine, Ashworth's cylinder setting ... 
 
 129 
 
 74 
 
 Carding machine, Ashworth's driving 
 
 149 
 
 85 
 
 Carding machine, Ashworth's setting of pedestals 
 
 148 
 
 85 
 
 Carding machine, attenuation of fleece 
 
 152 
 
 86 
 
 Carding machine, Brook's 
 
 130 
 
 76 
 
 Carding machine, Brook's adjustment of flats ... 
 
 131 
 
 77 
 
 Carding machine, condition of fibres 
 
 153 
 
 88 
 
 Carding machine, construction of bend 
 
 113 
 
 60 
 
 Carding machine, construction of calender rolls .. 
 
 109 
 
 55 
 
 Carding machine, construction of coiler 
 
 110 
 
 55 
 
 Carding machine, construction of cylinder 
 
 107 
 
 54 
 
 Carding machine, construction of dish feed 
 
 143 
 
 81 
 
 Carding machine, construction of doffer 
 
 108 
 
 54 
 
 Carding machine, construction of doffer comb . . . 
 
 108 
 
 54 
 
 Carding machine, construction of licker-in 
 
 106 
 
 54 
 
 Carding machine, construction of pedestals 
 
 147 
 
 84 
 
 Carding machine, construction of setting brackets 
 
 113 
 
 60 
 
 Carding machine, construction theory of bend .., 
 
 118 
 
 64 
 
 Carding machine, character of working settings... 
 
 133 
 
 78 
 
 Carding machine, development of 
 
 104 
 
 53 
 
 Carding machine, Dobson and Barlow's 
 
 125 
 
 69 
 
 Carding machine, Dobson and Barlow's covers for 
 
 145 
 
 82 
 
 Carding machine, Dobson and Barlow's pedestal 
 
 
 
 setting 
 
 148 
 
 85 
 
 Carding machine, driving of parts of 
 
 146 
 
 84 
 
 Carding machine, driving of rollers ... ; 
 
 113 
 
 60 
 
 Carding machine, ease of flexible bend adjustment 
 
 134 
 
 78 
 
 Carding machine, effect of licker-in 
 
 143 
 
 82 
 
 Carding machine, feeding laps 
 
 105 
 
 53 
 
 Carding machine, Hetherington's setting of bend. 
 
 121 
 
 66 
 
 Carding machine, Hetherington's trueing apparatus 
 
 121 
 
 66 
 
 Carding machine, Howard and Bullough's 
 
 127 
 
 70 
 
 Carding machine, Howard and Bullough's pedestal 
 
 
 
 setting 
 
 148 
 
 85 
 
 Carding machine, inclination of teeth on rollers . . 
 
 112 
 
 56 
 
 Carding machine, Knowles's 
 
 128 
 
 73 
 
 Carding machine, Leigh's flexible bend 
 
 119 
 
 65 
 
 Carding machine, method of setting flats 
 
 132 
 
 77 
 
 Carding machine, movement of cylinder centre... 
 
 135 
 
 79 
 
 Carding machine, object of 
 
 103 
 
 53 
 
 Carding machine, Piatt's bend setting 
 
 122 
 
 67 
 
 Carding machine, Piatt's inspection of setting ... 
 
 137 
 
 79 
 
 Carding machine, position of chain attachment.'. . 
 
 123 
 
 68 
 
 Carding machine, position of flexible bend 
 
 120 
 
 64 
 
 Carding machine, position of mote knives 
 
 144 
 
 82 
 
 Carding machine, position of under casings 
 
 144 
 
 82 
 
 
 Par. 
 
 Page. 
 
 Carding machine, removal of neps and short fibre 
 
 150 
 
 85 
 
 Carding machine, revolving flat 
 
 115 
 
 61 
 
 Carding machine, revolving, adjusting heel of flats 
 
 117 
 
 62 
 
 Carding machine, revolving, construction of flats 
 
 116 
 
 61 
 
 Carding machine, revolving, mode of shaping flats 
 
 116 
 
 61 
 
 Carding machine, revolving, number of flats ... 
 
 115 
 
 61 
 
 Carding machine, revolving, testing flats „. ... 
 
 117 
 
 62 
 
 Carding machine, roller and clearer 
 
 111 
 
 56 
 
 Carding machine, roller dirt stripper ; ... 
 
 111 
 
 56 
 
 Carding machine, setting flexible bend 
 
 119 
 
 65 
 
 Carding machine, setting licker-in and doffer ... 
 
 136 
 
 79 
 
 Carding machine, ultimate draught 
 
 152 
 
 86 
 
 Carding machine, velocity of cylinder 
 
 107 
 
 54 
 
 Carding machine, velocity of doffer 
 
 108 
 
 54 
 
 Carding machine, velocity of doffer comb 
 
 108 
 
 54 
 
 Carding machine, velocity of rollers 
 
 112 
 
 56 
 
 Carding machine, velocity of Wellman 
 
 141 
 
 81 
 
 Carding machine, Wellman 
 
 138 
 
 79 
 
 Carding machine, Wellman, Dobson, and Barlow's 
 
 139 
 
 80 
 
 Carding machine, Wellman, effect of setting of flats 
 
 141 
 
 81 
 
 Carding machine, Wellman, future of 
 
 142 
 
 81 
 
 Carding machine, Wellman, principles of 
 
 138 
 
 79 
 
 Carding machine, Wellman, setting flats of 
 
 140 
 
 81 
 
 Card stripping, importance of 
 
 188 
 
 118 
 
 Card stripping, method of 
 
 189 
 
 119 
 
 Card stripping, reasons for 
 
 188 
 
 118 
 
 Capital employed in spinning 
 
 3 
 
 5 
 
 Carriage of mule, connection with square 
 
 278 
 
 183 
 
 Carriage of mule, construction of 
 
 278 
 
 183 
 
 Carriage of mule, gain of 
 
 288 
 
 189 
 
 Carriage of mule, improved slips for 
 
 360 
 
 229 
 
 Carriage of mule, reciprocal motion of 
 
 269 
 
 177 
 
 Chain attachment to flats 
 
 123 
 
 68 
 
 Chain, backing-off tightening 
 
 307 
 
 198 
 
 Chain, winding 
 
 331 
 
 212 
 
 Chain, winding tightening motion , 
 
 333 
 
 213 
 
 Cleanliness, importance of 
 
 16 
 
 11 
 
 Clearers for drawing frames 
 
 212 
 
 142 
 
 Clearers, Dobson and Barlow'a 
 
 212 
 
 142 
 
 Clearer?, Ermen's revolving 
 
 212 
 
 142 
 
 Clearers, roving frames 
 
 226 
 
 148 
 
 Clearers, rollers of carding engines 
 
 112 
 
 56 
 
 Click motion 
 
 341 
 
 217 
 
 Click motion, defects of old 
 
 342 
 
 217 
 
 Click motion, holding out rod and 
 
 343 
 
 217 
 
 Coiler, construction of 
 
 110 
 
 56 
 
 Collars, Mason's long 
 
 229 
 
 152 
 
312 GENERAL 
 
 
 Pab. 
 
 Page. 
 
 Combined opening machines, Dobson and Barlow's 
 
 47 
 
 25 
 
 Combined opening machines, Piatt's 
 
 52 
 
 28 
 
 Combined opening machines, Lord's 
 
 58 
 
 31 
 
 Combined mixing, opening, and scutching 
 
 63 
 
 32 
 
 Combined openiDg and scutching 
 
 93 
 
 48 
 
 Combing machine, action of 
 
 198 
 
 126 
 
 Combing machine, combing cylinder 
 
 196 
 
 125 
 
 Combing machine, detaching mechanism 
 
 197 
 
 126 
 
 Combing machine, Dobson and Barlow's 
 
 202 
 
 130 
 
 Combing machine, Imbs' 
 
 205 
 
 135 
 
 Combing machine, nippers of, Dobson & Barlow's 
 
 203 
 
 134 
 
 Combing machine, nipper guard 
 
 201 
 
 130 
 
 Combing machine, preparation of sliver for 
 
 192 
 
 120 
 
 Combing machine, Piuel, Lecceur, & Hetherington' 
 
 s 205 
 
 135 
 
 Combing machine, speed of 
 
 200 
 
 129 
 
 Combing machine, waste from 
 
 206 
 
 136 
 
 Comparative spindle speeds 
 
 9 
 
 8 
 
 Condenser, Theisen's patent 
 
 11 
 
 9 
 
 Cones, Asa Lees' driving for 
 
 92 
 
 48 
 
 Cones, Piatt's driving for 
 
 87 
 
 45 
 
 Cones, roving frame 
 
 242 
 
 158 
 
 Cones, scutching machine velocity 
 
 83 
 
 42 
 
 Cones, shape of 
 
 249 
 
 166 
 
 Cones, speed 
 
 249 
 
 166 
 
 Construction of combing cylinder 
 
 196 
 
 125 
 
 Construction of drawing machine 
 
 208 
 
 137 
 
 Construction of roving frames 
 
 226 
 
 147 
 
 Constructive methods, early 
 
 7 
 
 7 
 
 Constructive methods, modern 
 
 8 
 
 7 
 
 Cops, chase of 
 
 317 
 
 203 
 
 Cops, form of 
 
 316 
 
 202 
 
 Cops, layers of yarn in 
 
 317 
 
 203 
 
 Cops, paper tubes for 
 
 316 
 
 202 
 
 Cops, winding traverse in building 
 
 317 
 
 203 
 
 Copping motion, action of 
 
 322 
 
 205 
 
 Copping motion, loose copping rail 
 
 321 
 
 205 
 
 Copping motion, object of rail 
 
 308 
 
 199 
 
 Copping motion, theory of 
 
 319 
 
 203 
 
 Copping motion, traverse of plates 
 
 320 
 
 204 
 
 Cotton, American 
 
 21 
 
 13 
 
 Cotton, Brazilian 
 
 20 
 
 13 
 
 Cotton, cleaning of. 
 
 39 
 
 23 
 
 Cotton, commercial qualities 
 
 23 
 
 14 
 
 Cotton, Egyptian 
 
 19 
 
 13 
 
 Cotton gin 
 
 24 
 
 15 
 
 Cotton, Indian 
 
 22 
 
 13 
 
 Cotton, mixing 
 
 36 
 
 21 
 
 INDEX. 
 
 
 Par. 
 
 Page. 
 
 Cotton, Sea Island 
 
 18 
 
 13 
 
 Cotton fibre, structure of 
 
 17 
 
 12 
 
 Cotton fibre, strength of 
 
 17 
 
 12 
 
 Cotton mill, cost of 
 
 6 
 
 7 
 
 Cotton, pneumatic conveyance of 
 
 63 
 
 32 
 
 Cotton spinning industry 
 
 3 
 
 5 
 
 Counts of yarn, definition of 
 
 387 
 
 257 
 
 Counts of wire, how calculated 
 
 156 
 
 92 
 
 Counts of wire commonly used 
 
 157 
 
 93 
 
 Creel, roving machine 
 
 22G 
 
 147 
 
 Crighton opening machine 
 
 53 
 
 29 
 
 Crighton opening, combined 
 
 63 
 
 32 
 
 Crighton opening, double 
 
 61 
 
 32 
 
 Crighton opening, distance of grids 
 
 59 
 
 31 
 
 Crighton opening, lubrication of footsteps 
 
 57 
 
 31 
 
 Crighton opening, position of fans 
 
 54 
 
 29 
 
 Crighton opening, production of 
 
 60 
 
 32 
 
 Crighton opening, shape of grids 
 
 56 
 
 30 
 
 Curtis and Rhodes' differential motion 
 
 247 
 
 164 
 
 Curtis' mule 
 
 358 
 
 228 
 
 D 
 
 
 
 Dead pi ite in scutching machine 
 
 75 
 
 39 
 
 Dead plate, effect of position of 
 
 80 
 
 41 
 
 Dead plate, Piatt's arrangement of 
 
 81 
 
 41 
 
 Dead plate, position of 
 
 77 
 
 39 
 
 Definition of lead 
 
 237 
 
 156 
 
 Deflection of flats *. 
 
 167 
 
 102 
 
 Detaching mechanism of combers 
 
 197 
 
 126 
 
 Development of carding machine 
 
 104 
 
 53 
 
 Differential motion, action of plate wheel in 
 
 244 
 
 162 
 
 Differential motion, Curtis and Rhodes' 
 
 247 
 
 164 
 
 Differential motion, mode of driving plate wheel 
 
 246 
 
 163 
 
 Differential motion of roving machines 
 
 243 
 
 161 
 
 Differential motion, relative velocity of plate wheel 
 
 246 
 
 164 
 
 Differential motion, theory of 
 
 244 
 
 162 
 
 Differential motion, Tweedale's 
 
 248 
 
 165 
 
 Dirt roller of carding engine 
 
 111 
 
 56 
 
 Dobson and Barlow's bale breaker 
 
 34 
 
 19 
 
 Dobson and Barlow's combing machine 
 
 202 
 
 130 
 
 Dobson and Barlow's covers for carding engines... 
 
 145 
 
 82 
 
 Dobson and Barlow's detaching mechanism 
 
 202 
 
 133 
 
 Dobson and Barlow's governing motion 
 
 354 
 
 225 
 
 Dobson and Barlow's nosing motion ... 
 
 353 
 
 223 
 
 Dobson and Barlow's opening machine 
 
 47 
 
 25 
 
GENEKAL INDEX. 
 
 313 
 
 Par. 
 
 Page. 
 
 Dobson and Barlow's revolving flat card 
 
 125 
 
 69 
 
 Dohson and Barlow's setting cylinders 
 
 148 
 
 35 
 
 Dobson and Barlow's under casings 
 
 144 
 
 82 
 
 Dobson and Barlow's Wellman machine 
 
 139 
 
 80 
 
 Doffer, carding machine 
 
 108 
 
 54 
 
 Doffer, velocity of 
 
 108 
 
 54 
 
 Doffer comb 
 
 108 
 
 54 
 
 Doffing motion for reels 
 
 394 
 
 265 
 
 Double fans in opening machines 
 
 52 
 
 28 
 
 Doubling of laps in scutchers 
 
 97 
 
 52 
 
 Doubling machine 
 
 384 
 
 284 
 
 Doubling winding machine, objects of 
 
 397 
 
 271 
 
 Doubling winding machine, Stubbs' 
 
 398 
 
 271 
 
 Draught of bale breaker 
 
 30 
 
 18 
 
 Draught of carding machine 
 
 152 
 
 86 
 
 Draught in drawing machine 
 
 211 
 
 141 
 
 Draught, effect of 
 
 211 
 
 141 
 
 Draught of machines, definition 
 
 29 
 
 18 
 
 Draught of scutching machine 
 
 98 
 
 52 
 
 Draught of scutching where occurring 
 
 101 
 
 52 
 
 Drawing machine, arrangement of sliver cans ... 
 
 215 
 
 143 
 
 Drawing machine, Brooks' stop motion 
 
 219 
 
 144 
 
 Drawing machine, centres of rollers 
 
 210 
 
 141 
 
 Drawing machine, clearers for 
 
 212 
 
 142 
 
 Drawing machine, construction of 
 
 208 
 
 137 
 
 Drawing machine, deliveries of 
 
 208 
 
 137 
 
 Drawing machine, Dobson and Barlow's, clearer for 
 
 212 
 
 142 
 
 Drawing machine, draughts in 
 
 211 
 
 141 
 
 Drawing machine, driving rollers of 
 
 209 
 
 138 
 
 Drawing machine, doubling of slivers in 
 
 215 
 
 143 
 
 Drawing machine, effect of doubling in 
 
 216 
 
 143 
 
 Drawing machine, effect of staple 
 
 210 
 
 141 
 
 Drawing machine, Ermen's revolving clearer 
 
 212 
 
 142 
 
 Drawing machine, essential features in 
 
 214 
 
 142 
 
 Drawing machine, Howard and Bullough's electric 
 
 
 
 stop motion 
 
 223 
 
 145 
 
 Drawing machine, Leigh's loose boss rollers 
 
 208 
 
 138 
 
 Drawing machine, number of doublings 
 
 216 
 
 143 
 
 Drawing machine, number of doublings permissible 
 
 217 
 
 144 
 
 Drawing machine, objects of 
 
 207 
 
 137 
 
 Drawing machine, Piatt's full can stop motion . . . 
 
 221 
 
 145 
 
 Drawing machine, reasons for stop motion 
 
 219 
 
 144 
 
 Drawing machine, rollers for 
 
 208 
 
 138 
 
 Drawing machine, roller laps ... 
 
 212 
 
 142 
 
 Drawing machine, roller relieving motion 
 
 213 
 
 142 
 
 Drawing machine, size of rollers 
 
 224 
 
 146 
 
 Drawing machine, slubs 
 
 212 
 
 142 
 
 
 Par. 
 
 Page. 
 
 Drawing machine, velocity of rollers 
 
 ... 209 
 
 138 
 
 Drawing machine, velocity of rollers 
 
 ... 224 
 
 146 
 
 Driving, Ashworth's, of carding machine ... 
 
 ... 149 
 
 84 
 
 Driving belts, speed of 
 
 13 
 
 10 
 
 Driving bobbins of roving machine 
 
 ... 232 
 
 153 
 
 Driving carding engines 
 
 ... 146 
 
 84 
 
 Driving rollers and clearers 
 
 ... 113 
 
 60 
 
 Driving rollers of roving machine 
 
 ... 231 
 
 152 
 
 Driving ropes, size and speed of 
 
 14 
 
 10 
 
 Driving, spindles of roving machine 
 
 ... 231 
 
 152 
 
 Dronsfield's emery fillets 
 
 ... 176 
 
 109 
 
 Dronsfield's roller covering machine 
 
 ... 409 
 
 284 
 
 Dub's governing motion 
 
 ... 356 
 
 226 
 
 Duplex driving of mules 
 
 ... 287 
 
 188 
 
 Dust trunks, construction of ... 
 
 64 
 
 32 
 
 Dust trunks, Piatt Brothers 
 
 65 
 
 33 
 
 Dust trunks, position of 
 
 64 
 
 32 
 
 Dust trunks, use of 
 
 63 
 
 32 
 
 E 
 
 Early inventions 1 5 
 
 Edge's flat grinding apparatus 182 131 
 
 Egyptian cotton 19 13 
 
 Elephant opener 28 16 
 
 Engines, steam, types of 11 8 
 
 Ermen's revolving clearer 212 142 
 
 Essential features of drawing frames 214 142 
 
 Extent of machine making trade 3 5 
 
 F 
 
 Fans in opening machine 
 
 52 
 
 28 
 
 Feed motion dish for carding engine 
 
 . 106 
 
 54 
 
 Feed motion dish for carding engine 
 
 . 143 
 
 81 
 
 Feed motion, Lord's piano 
 
 82 
 
 42 
 
 Feed motion, cones in scutching 
 
 84 
 
 43 
 
 Feed motion, velocity of cones in scutching 
 
 83 
 
 42 
 
 Feed rollers, draught of 
 
 98 
 
 52 
 
 Feed rollers, drawing action of 
 
 85 
 
 44 
 
314 
 
 GENERAL INDEX. 
 
 
 Par. 
 
 Page. 
 
 
 Par. 
 
 Page. 
 
 Feed rollers, scutcher 
 
 85 
 
 44 
 
 Grids, Howard and Bullough's air bars for 
 
 74 
 
 38 
 
 Feeding carding machines 
 
 . 105 
 
 53 
 
 Grids, pitch of projections on 
 
 60 
 
 32 
 
 Feeding scutching machines from laps 
 
 95 
 
 51 
 
 Grids, position in opening machine 
 
 59 
 
 31 
 
 Fibres, position in fleece 
 
 . 153 
 
 88 
 
 Grids, position in scutching machine 
 
 72 
 
 37 
 
 Fillets attaching to cylinders 
 
 . 164 
 
 96 
 
 Grids, shape of opening machine 
 
 56 
 
 30 
 
 Fillets attaching to flats 
 
 . 166 
 
 101 
 
 Grids, setting bars in 
 
 73 
 
 38 
 
 Fillets, Dronsfield's emery ... 
 
 . 176 
 
 109 
 
 Grinding, defects of side 
 
 160 
 
 94 
 
 Fillets, foundation for card 
 
 . 154 
 
 91 
 
 Grinding, desirability of light 
 
 163 
 
 95 
 
 Fillets, manufacture of card 
 
 155 
 
 91 
 
 Grinding, Horsfall roller for 
 
 177 
 
 109 
 
 Fillets, Piatt's fastener for 
 
 . 169 
 
 105 
 
 Grinding, improved side 
 
 162 
 
 95 
 
 Fillets, preparation of ... 
 
 164 
 
 96 
 
 Grinding, principles of flat 
 
 179 
 
 110 
 
 Fillets, setting teeth in 
 
 . 156 
 
 92 
 
 Grinding, roller brackets for 
 
 178 
 
 110 
 
 Fillets, Tweedale's clip for card 
 
 . 168 
 
 102 
 
 Grinding, roller 
 
 186 
 
 117 
 
 Fillets, winding on 
 
 . 165 
 
 96 
 
 Grinding, side 
 
 159 
 
 94 
 
 Fillets, Whiteley's clip for card 
 
 . 166 
 
 101 
 
 Grinding, slow speed of cylinder during 
 
 170 
 
 105 
 
 Flats, adjustment of heel in 
 
 117 
 
 62 
 
 Grinding, striation of teeth 
 
 161 
 
 94 
 
 Flats, attaching chain to ... = 
 
 . 123 
 
 68 
 
 Grinding, Wellman flat ■ 
 
 187 
 
 118 
 
 Flats, attaching clothing to 
 
 . 166 
 
 101 
 
 
 
 
 Flats, Brooks' adjustment of 
 
 . 131 
 
 77 
 
 
 
 
 Flats, character of working setting 
 
 . 133 
 
 78 
 
 H 
 
 
 
 Flats, construction of 
 
 . 116 
 
 61 
 
 
 
 Flats, deflection of 
 
 . 167 
 
 102 
 
 
 
 
 Flats, Edge's grinding apparatus for 
 
 . 182 
 
 113 
 
 
 
 
 Flats, Hetherington's grinding apparatus for 
 
 . 181 
 
 112 
 
 Hank, definition of 
 
 387 
 
 257 
 
 Flats, Higginson's grinding apparatus for ... 
 
 183 
 
 114 
 
 Hank, roving calculation of 
 
 387 
 
 257 
 
 Flats, Knowles' grinding apparatus for ... . 
 
 . 180 
 
 111 
 
 Heating of mills 
 
 15 
 
 11 
 
 Flats, number of 
 
 . 115 
 
 61 
 
 Heilmann combing machine 
 
 195 
 
 122 
 
 Flats, Piatt's grinding apparatus 
 
 . 184 
 
 116 
 
 Hetherington's flat-grinding apparatus 
 
 181 
 
 112 
 
 Flats, Piatt's inspecting device for ... ..; . 
 
 . 137 
 
 79 
 
 Hetherington's Heilmann comber 
 
 195 
 
 122 
 
 Flats, shaping 
 
 116 
 
 61 
 
 Hetherington's mule 
 
 352 
 
 222 
 
 Flats, setting 
 
 . 132 
 
 77 
 
 Hetherington's production of mule 
 
 
 233 
 
 Flats, setting, Wellman 
 
 . 140 
 
 80 
 
 Hetherington's setting of flexible bend 
 
 121 
 
 66 
 
 Flats, testing heel of 
 
 . 117 
 
 62 
 
 Hetherington's slow motion 
 
 172 
 
 106 
 
 Flyers, attachment of pressers to 
 
 . 228 
 
 148 
 
 Hetherington's trueing apparatus for card 
 
 121 
 
 66 
 
 Flyers, construction of roving 
 
 . 227 
 
 148 
 
 Higgins' spindle bearing 
 
 230 
 
 152 
 
 Flyers, lead of 
 
 . 240 
 
 158 
 
 Higginson's flat grinding apparatus 
 
 183 
 
 114 
 
 Flyers, retardation of 
 
 240 
 
 157 
 
 Holding-out catch 
 
 Horsfall grinding roller 
 
 Howard and Bullough's air bars 
 
 309 
 177 
 74 
 
 199 
 109 
 
 38 
 
 G 
 
 
 
 Howard and Bullough's carding engine 
 
 127 
 
 70 
 
 
 
 Howard and Bullough'3 clip for fillets 
 
 Howard and Bullough's differential motion 
 Howard and Bullough's electric stop motion 
 
 168 
 248 
 223 
 
 102 
 165 
 145 
 
 Gassing machine 
 
 . 399 
 
 272 
 
 Howard and Bullough's electric stop motion 
 
 263 
 
 174 
 
 Gauge of spindles in roving machines 
 
 . 227 
 
 148 
 
 Howard and Bnllough's production of ring frame 
 
 
 259 
 
 Gin, cotton ... ... " 
 
 24 
 
 15 
 
 Howard and Bullough's weft ring frame 
 
 382 
 
 253 
 
 Gin, Macarthy cotton 
 
 25 
 
 15 i 
 
 Humidity of mills 
 
 15 
 
 10 
 
GENERAL INDEX. 
 
 315 
 
 Importance of cleanliness 
 
 Importance of efficient carding . . . 
 Importance of stripping cards 
 
 Imbs' combing machine 
 
 Inclination of carding roller teeth 
 Inclination of spindle in mule 
 Increase in production of machines 
 
 Indian cotton 
 
 Indicators for mules 
 
 Indicators for slubbing machines ... 
 
 Jack frame 
 Jack shaft... 
 Jacking . . . 
 
 K 
 
 Knowles' revolving flat carding engine 
 
 Knowles' slow motion 
 
 Knowles and Tatham's grinding apparatus. 
 
 Lap attachment to scutching machine .. 
 
 Lap, doubling of 
 
 Lap, effect of licker-in on 
 
 Lap, feeding on scutching machine 
 
 Lap, feeding on carding engine 
 
 Lap, selvedges of 
 
 Lap, weight and hank of 
 Leaf extractor, (Brighton's 
 Leigh's flexible bend 
 Leigh's loose boss top roller 
 Licker-in, action of... . ... 
 
 
 
 
 Par 
 
 Page. 
 
 
 
 Licker-in, construction of 
 
 106 
 
 54 
 
 Par. 
 
 Page. 
 
 Licker-in, setting of ■ 
 
 136 
 
 79 
 
 16 
 
 11 
 
 Licker-in, teeth of > 
 
 157 
 
 93 
 
 190 
 
 119 
 
 Lift of roving bobbins 
 
 .. 233 
 
 154 
 
 188 
 
 118 
 
 Lift, amount of 
 
 233 
 
 154 
 
 205 
 
 135 
 
 Lift, reversal of 
 
 .. 254 
 
 171 
 
 112 
 
 56 
 
 Lift, ring rail 
 
 367 
 
 236 
 
 280 
 
 183 
 
 Lift, shortening of roving frame 
 
 .. 235 
 
 155 
 
 
 Q 
 
 Locking lever in mule 
 
 .. 305 
 
 196 
 
 22 
 
 13 
 
 Long collar, Mason's 
 
 229 
 
 152 
 
 417 
 
 292 
 
 Long lever in mule 
 
 290 
 
 189 
 
 417 
 
 294 
 
 Lord Brothers' opening machine 
 
 58 
 
 61 
 
 
 
 Lord Brothers' piano feed motion 
 
 82 
 
 A O 
 
 
 
 Lord Brothers' scutching machine 
 
 68 
 
 OO 
 
 
 
 Lord Brothers' velocity of opening beaters 
 
 58 
 
 Q1 
 
 ol 
 
 
 
 M 
 
 IVI 
 
 
 
 225 
 
 147 
 
 
 
 
 241 
 
 158 
 
 
 
 
 361 
 
 231 
 
 
 
 
 
 
 Machine making industry, employment in ... 
 
 3 
 
 5 
 
 
 
 Machinery, productive power of 
 
 4 
 
 6 
 
 
 
 Main driving of mills 
 
 12 
 
 9 
 
 
 
 Margin between yarn and cotton 
 
 5 
 
 6 
 
 
 
 Mason's long collars 
 
 229 
 
 152 
 
 
 
 Methods, earlier, of machine construction ... 
 
 2 
 
 5 
 
 128 
 
 73 
 
 Methods, earlier, of machine construction ... 
 
 7 
 
 7 
 
 175 
 
 108 
 
 Methods, modern, of machine construction... 
 
 8 
 
 7 
 
 180 
 
 111 
 
 Mill, cost of 
 
 6 
 
 7 
 
 
 
 Mill, construction of modern 
 
 10 
 
 8 
 
 
 
 Mixing arrangements 
 
 35 
 
 20 
 
 
 
 Mixing by machine 
 
 37 
 
 21 
 
 
 
 Mixing, principles of . 
 
 36 
 
 21 
 
 
 
 Mixing, staples of cottons in 
 
 38 
 
 22 
 
 
 
 Moisture in cotton 
 
 27 
 
 16 
 
 67 
 
 35 
 
 Mote knives, position and setting 
 
 144 
 
 82 
 
 97 
 
 52 
 
 Mule 
 
 264 
 
 176 
 
 143 
 
 82 
 
 Mule, back shaft driving of 
 
 ... 284 
 
 184 
 
 95 
 
 51 
 
 Mule, back shaft clutch teeth of 
 
 ... 284 
 
 187 
 
 105 
 
 53 
 
 Mule, back shaft disengagement of clutch ... 
 
 ... 293 
 
 190 
 
 99 
 
 52 
 
 Mule, back shaft scrolls on 
 
 ... 284 
 
 187 
 
 100 
 
 52 
 
 Mule, backing-off, driving of wheel 
 
 ... 282 
 
 184 
 
 77 
 
 40 
 
 Mule, backing-off, effect of 
 
 ... 282 
 
 184 
 
 119 
 
 65 
 
 Mule, backing-off, engagement of clutch 
 
 ... 299 
 
 193 
 
 208 
 
 138 
 
 Mule, backing-off, operation of 
 
 ... 270 
 
 177 
 
 150 
 
 85 
 
 Mule, backing-off, rotation of wheel ... ... 
 
 ... 296 
 
 190 
 
GENERAL INDEX. 
 
 
 Par. 
 
 Page 
 
 Mule, backing-off, release of clutch 
 
 312 
 
 200 
 
 Mule, backing-off, release of lever 
 
 301 
 
 194 
 
 Mule, backing-off, compression of spring 
 
 300 
 
 193 
 
 Mule, backing-off, tightening motion of chain 
 
 307 
 
 198 
 
 Mule, bands attaching to end frames 
 
 234 
 
 187 
 
 Mule, cam shaft effects, first half turn 
 
 292 
 
 190 
 
 Mule, cam shaft effects, second half turn 
 
 345 
 
 218 
 
 Mule, cam shaft, position of cams on 
 
 291 
 
 189 
 
 Mule, cam shaft, position of ordinary 
 
 350 
 
 220 
 
 Mule, click motion, description of 
 
 341 
 
 217 
 
 Mule, click motion, defects of old 
 
 342 
 
 217 
 
 Mule, click motion, holding out rod, and 
 
 343 
 
 217 
 
 Mule carriage, angularity of yarn during traverse of 
 
 360 
 
 229 
 
 Mule carriage, connection with square 
 
 278 
 
 183 
 
 Mule carriage, construction of 
 
 278 
 
 183 
 
 Mule carriage, extent of traverse of 
 
 269 
 
 177 
 
 Mule carriage, gain of 
 
 288 
 
 189 
 
 Mule carriage, reciprocal motion of 
 
 269 
 
 177 
 
 Mule carriage, relation of rollers to 
 
 276 
 
 180 
 
 Mule cop, chase of ... ; 
 
 317 
 
 203 
 
 Mule cop, form of 
 
 316 
 
 202 
 
 Mule cop, layers of yarn in 
 
 317 
 
 203 
 
 Mule cop, paper tubes for 
 
 316 
 
 202 
 
 Mule cop, position of nose of 
 
 306 
 
 197 
 
 Mule copping motion, action of 
 
 322 
 
 205 
 
 Mule copping motion, loose rail in 
 
 321 
 
 205 
 
 Mule copping motion, object of rail 
 
 308 
 
 199 
 
 Mule copping motion, theory of 
 
 319 
 
 203 
 
 Mule copping motion, traverse of plates in 
 
 320 
 
 204 
 
 Mule, Curtis' 
 
 358 
 
 228 
 
 Mule, driving arrangement of bands for 
 
 281 
 
 183 
 
 Mule, driving, back shaft 
 
 284 
 
 184 
 
 Mule, driving, dimensions of pulleys for 
 
 281 
 
 183 
 
 Mule, driving, duplex 
 
 287 
 
 188 
 
 Mule, driving, duplex, dimensions of pulleys for 
 
 287 
 
 188 
 
 Mule, driving, gear of taking-in shaft ., 
 
 285 
 
 187 
 
 Mule, driviug, improved, for taking-in side shaft 
 
 286 
 
 188 
 
 Mule, driving rollers from rim shaft 
 
 283 
 
 184 
 
 Mule, driving scroll shaft 
 
 285 
 
 187 
 
 Mule, driving spindles 
 
 280 
 
 183 
 
 Mule fallers, action of 
 
 303 
 
 194 
 
 Mule fallers, actuating mechanism of winding 
 
 305 
 
 196 
 
 Mule fallers, construction and position of 
 
 303 
 
 194 
 
 Mule fallers, difference in upward and downward 
 
 
 
 traverse of 
 
 317 
 
 203 
 
 Mule fallers, position of winding before unlocking 
 
 346 
 
 218 
 
 Mule fallers, regulating mechanism of counter ... 
 
 304 
 
 195 
 
 
 Par. 
 
 Page. 
 
 Mule fallers, regulation of unlocking winding . . 
 
 346 
 
 219 
 
 Mule fallers, release of strain on rods 
 
 . 347 
 
 219 
 
 Mule, fine yarn 
 
 361 
 
 230 
 
 Mule governing, action of motion 
 
 338 
 
 216 
 
 Mule governing, amount required 
 
 340 
 
 216 
 
 Mule governing, construction of motion 
 
 . 337 
 
 215 
 
 Mule governing, Dobson and Barlow's motion . . 
 
 354 
 
 225 
 
 Mule governing, Dub'e motion 
 
 356 
 
 226 
 
 Mule governing, necessity for 
 
 . 336 
 
 214 
 
 Mule governing, release of motion 
 
 339 
 
 216 
 
 Mule, Hetherington's 
 
 352 
 
 222 
 
 Mule, holding out catch mechanism of 
 
 309 
 
 199 
 
 Mule, holding out position duriug backing-off 
 
 310 
 
 200 
 
 Mule, holding out catch release of 
 
 313 
 
 201 
 
 Mule, holding out rod effect on click motion . . 
 
 343 
 
 217 
 
 Mule, jacking motion 
 
 361 
 
 231 
 
 Mule, long lever 
 
 290 
 
 189 
 
 Mule, lucking lever, posit'on of 
 
 305 
 
 196 
 
 Mule, locking point, relation to cop nose 
 
 806 
 
 197 
 
 Mule, locking taking-in friction 
 
 309 
 
 200 
 
 Mule, Mendoza lever 
 
 351 
 
 221 
 
 Mule, Mendoza locking 
 
 352 
 
 222 
 
 Mule nosing motion, Dobson and Hardman's .. 
 
 353 
 
 223 
 
 Mule nosing motion, Piatt's 
 
 333 
 
 213 
 
 Mule nosing peg 
 
 332 
 
 213 
 
 Mule, Piatt's reasons for selecting 
 
 275 
 
 179 
 
 Mule, production of, 1835-1890 
 
 4 
 
 6 
 
 Mule production, tables of 
 
 
 233 
 
 Mule, primary parts of 
 
 266 
 
 176 
 
 Mule, regulation of releasing motions 
 
 314 
 
 201 
 
 Mule rim shaft, driving bands on 
 
 281 
 
 183 
 
 Mule rim shaft, driving back shaft from 
 
 284 
 
 184 
 
 Mule rim shaft, driving rollers from 
 
 283 
 
 184 
 
 Mule rim shaft, reversal of ... 
 
 302 
 
 194 
 
 Mule rim shaft, velocity of 
 
 286 
 
 188 
 
 Mule rollers, action of 
 
 267 
 
 177 
 
 Mule rollers, construction of 
 
 277 
 
 180 
 
 Mule rollers, driving of 
 
 283 
 
 184 
 
 Mule rollers, disengagement of clutch 
 
 294 
 
 190 
 
 Mule rollers, engagement of clutch 
 
 345 
 
 218 
 
 Mule scroll, diameters of 
 
 315 
 
 202 
 
 Mule scroll, connection with back shaft 
 
 315 
 
 202 
 
 Mule scroll, driving of shaft 
 
 285 
 
 187 
 
 Mule scroll, position of, on back shaft 
 
 284 
 
 189 
 
 Mule scroll, position of check 
 
 315 
 
 202 
 
 Mule scroll, revolution of shaft 
 
 315 
 
 201 
 
 Mule spindles, attaching roving to 
 
 268 
 
 177 
 
GENERAL INDEX. 
 
 317 
 
 
 Pab. 
 
 Page. 
 
 Mule spindles, construction of 
 
 280 
 
 183 
 
 Mule spindles, dimensions of 
 
 280 
 
 183 
 
 Mule spindles, tffect of taper of 
 
 324 
 
 206 
 
 Mule spindles, fitting bands on 
 
 280 
 
 183 
 
 Mule, number of spindles on 
 
 4 
 
 6 
 
 Mule, reversal of spindles 
 
 302 
 
 194 
 
 Mule, velocity of spindles 
 
 280 
 
 183 
 
 Mule spinning, definition of spinning 
 
 264 
 
 176 
 
 Mule, stages in working of 
 
 272 
 
 178 
 
 Mule stages, definition of 
 
 272 
 
 178 
 
 Mule stages, end of first 
 
 289 
 
 189 
 
 Mule stages, end of second 
 
 295 
 
 190 
 
 Mule stages, end of third 
 
 311 
 
 200 
 
 Mule stages, end of fourth 
 
 344 
 
 218 
 
 Mule stages, end of fifth 
 
 288 
 
 188 
 
 Mule stages, end of fifth 
 
 345 
 
 218 
 
 Mule stages, end of sixth 
 
 273 
 
 179 
 
 Mule stages, varying operation of parts during ... 
 
 274 
 
 179 
 
 Mule strap guide, lever mechanism of 
 
 297 
 
 193 
 
 Mule strap guide, mode of releasing 
 
 298 
 
 193 
 
 Mule strap guide, release of 
 
 295 
 
 190 
 
 Mule strap guide, re-locking, &c 
 
 345 
 
 218 
 
 Mule, taking-in, action of back shaft during 
 
 315 
 
 202 
 
 Mule, taking-in, locking of clutch 
 
 309 
 
 200 
 
 Mule, taking-in, position of clutch during backing off 310 
 
 200 
 
 Mule, taking-in, release of clutch ... 
 
 313 
 
 201 
 
 Mule, taking-in, speed of carriage during 
 
 315 
 
 202 
 
 Mule, Threlfall's fine 
 
 362 
 
 231 
 
 Mule, twist yarn produced 
 
 363 
 
 232 
 
 Mule, tin roller, construction of 
 
 279 
 
 183 
 
 Mule, tin roller, driving of 
 
 331 
 
 212 
 
 Mule winding, action at end of 
 
 271 
 
 178 
 
 Mule winding, acceleration of velocity during . . . 
 
 329 
 
 210 
 
 Mule winding, application of theory 
 
 329 
 
 210 
 
 Mule winding, connection of chain with tin roller 
 
 331 
 
 212 
 
 Mule winding, construction of quadrant mechanism 
 
 330 
 
 210 
 
 Mule winding, chain tightening motion 
 
 333 
 
 213 
 
 Mule winding, chain rewinding on scroll 
 
 348 
 
 219 
 
 Mule winding, difference in velocity of 
 
 323 
 
 206 
 
 Mule winding, effect of taper of spindle on 
 
 324 
 
 206 
 
 Mule winding, elevation of initial point of 
 
 318 
 
 203 
 
 Mule winding, mode of rotating quadrant screw 
 
 335 
 
 214 
 
 Mule winding, position of parts during 
 
 271 
 
 177 
 
 Mule winding, theory of 
 
 325 
 
 208 
 
 Mule winding, theory of action of quadrant arm 
 
 328 
 
 209 
 
 Mule, weft yarn 
 
 363 
 
 232 
 
 Mule, waste spinning 
 
 364 
 
 232 
 
 N 
 
 
 Par. 
 
 Page. 
 
 Neps, removal of 
 
 150 
 
 85 
 
 Nipper guard 
 
 201 
 
 130 
 
 Nipper, Dobson and Barlow's 
 
 203 
 
 134 
 
 Nosing motion, Dobson and Barlow's 
 
 353 
 
 223 
 
 Nosing motion, Piatt's 
 
 333 
 
 213 
 
 Nosing peg 
 
 332 
 
 213 
 
 Number of doublings in drawing 
 
 216 
 
 143 
 
 Number of persons employed 
 
 3 
 
 6 
 
 Number of roving machines for various counts ... 
 
 225 
 
 147 
 
 Number of spindles at work 
 
 3 
 
 5 
 
 o 
 
 
 
 Opening, conditions of, successful 
 
 42 
 
 23 
 
 Opening, mode of 
 
 41 
 
 23 
 
 Opening, object of 
 
 40 
 
 23 
 
 Opening machine, combination with mixing room 
 
 63 
 
 32 
 
 Opening machine, construction of dust trunks for 
 
 64 
 
 32 
 
 Opening machine, conveyance of cotton to 
 
 63 
 
 32 
 
 Opening machine, Crigh ton's 
 
 53 
 
 29 
 
 Opening machine, Dobson and Barlow's 
 
 47 
 
 25 
 
 Opening machine, distance between beater arms 
 
 
 
 and grid 
 
 59 
 
 31 
 
 Opening machine, double fans in 
 
 52 
 
 28 
 
 Opening machine, essential features of 
 
 43 
 
 23 
 
 Opening machine, forms of 
 
 44 
 
 24 
 
 Opening machine, Lord Brothers' combined 
 
 58 
 
 31 
 
 Opening machine, lubrication of footstep in 
 
 57 
 
 31 
 
 Opening machine, pitch of projections on grid . . . 
 
 60 
 
 32 
 
 Opening machine, Piatt's 
 
 52 
 
 28 
 
 Opening machine, Piatt's improved dust trunks 
 
 
 
 for 
 
 65 
 
 33 
 
 Opening machine, porcupine rollers for 
 
 48 
 
 26 
 
 Opening machine, porcupine position and speed of 
 
 49 
 
 27 
 
 Opening machine, porcupine used as feed 
 
 50 
 
 27 
 
 Opening machine, position of dust trunks 
 
 64 
 
 32 
 
 Opening machine, position of fans 
 
 54 
 
 29 
 
 Opening machine, production of Crighton 
 
 59 
 
 32 
 
 Opening machine, shape of grids 
 
 56 
 
 30 
 
 Opening machines, Taylor, Lang and Co.'s 
 
 46 
 
 24 
 
 Opening machines, velocity of beaters in 
 
 55 
 
 30 
 
 Opening machines, velocity of beaters in Lord's 
 
 58 
 
 31 
 
 Operation of twist wheel in roving machine 
 
 241 
 
 158 
 
318 
 
 GENERAL INDEX. 
 
 
 Par. 
 
 Page. 
 
 
 
 
 
 
 
 Par. 
 
 Page 
 
 Paley's traverse motion 
 
 261 
 
 173 
 
 Quick traverse winding machines, Brooks' 
 
 401 
 
 273 
 
 Parallelisation of fibres in carding 
 
 151 
 
 86 
 
 Quick traverse, Dobson and Barlow 
 
 401 
 
 273 
 
 Persons employed 
 
 3 
 
 5 
 
 Quick traverse, Hetherington's 
 
 401 
 
 273 
 
 Pedal motion, Asa Lees 
 
 91 
 
 47 
 
 
 
 
 Pedal motion, Howard and Bullough's 
 
 86 
 
 44 
 
 
 
 
 Pedal motion, Piatt's 
 
 88 
 
 46 
 
 R 
 
 
 
 Pedal motion, Lord's 
 
 82 
 
 42 
 
 
 
 
 Pedal motion, operation of 
 
 84 
 
 43 
 
 
 
 
 Pedal motion, with rollers 
 
 85 
 
 44 
 
 Reeling machines, construction of 
 
 390 
 
 262 
 
 Pinel. Lecceur, and Hetherington's combing 
 
 
 
 Reeling machines, doffing motions 
 
 394 
 
 266 
 
 machine 
 
 205 
 
 135 
 
 Reeling machines, formation of hanks on 
 
 391 
 
 265 
 
 Pitch of drawing frame rollers 
 
 210 
 
 141 
 
 Reeling machines, Guest and Brooks' skeining 
 
 
 
 Plate wheel, action of 
 
 244 
 
 162 
 
 motion 
 
 395 
 
 266 
 
 Plate wheel, driving of 
 
 Z30 
 
 106 
 
 Reeling machines, seven lea motion 
 
 392 
 
 265 
 
 
 Ribbon lap machine 
 
 194 
 
 121 
 
 Plate wheel, relative velocity of 
 
 
 
 Rigidity of machine framing 
 
 8 
 
 7 
 
 Piatt's carding machine 
 
 122 
 
 67 
 
 Ring doubling machine, English system 
 
 384 
 
 284 
 
 Piatt's dust trunks 
 
 65 
 
 33 
 
 Ring doubling machine, manufacture of thread on 
 
 385 
 
 257 
 
 Piatt's flat grinding apparatus 
 
 184 
 
 116 
 
 Ring doubling machine, Scotch system 
 
 384 
 
 254 
 
 Piatt's flexible bend setting 
 
 122 
 
 67 
 
 Ring spinning machine, angularity of roller 
 
 
 
 Piatt's full can stop motion 
 
 221 
 
 145 
 
 brackets 
 
 370 
 
 240 
 
 Piatt's inspection of carding setting 
 
 137 
 
 79 
 
 Ring spinning machine, Asa Lees' rope driving ... 
 
 383 
 
 254 
 
 Piatt's mule 
 
 275 
 
 169 
 
 Ring spinning machine, ballooning in 
 
 378 
 
 248 
 
 Piatt's opening machine 
 
 52 
 
 28 
 
 Ring spinning machine, balloon guards 
 
 378 
 
 249 
 
 Piatt's scutching machine 
 
 88 
 
 46 
 
 Ring spinning machine, Bee spindle 
 
 374 
 
 246 
 
 Pneumatic conveyance of cotton 
 
 62 
 
 32 
 
 Ring spinning machine, Bernhardt's anti-balloon 
 
 
 
 Pohshing machines for thread 
 
 402 
 
 274 
 
 guide 
 
 378 
 
 249 
 
 Porcupine rollers, construction of 
 
 48 
 
 26 
 
 Ring spinning machine, Booth Sawyer spindle . . . 
 
 371 
 
 241 
 
 Porcupine rollers, position and speed of 
 
 49 
 
 27 
 
 Ring spinning machine, centrifugal action of 
 
 
 
 
 traveller 
 
 377 
 
 248 
 
 Porcupine rollers used as feed 
 
 
 97 
 
 Ring spinning machine, common spindle 
 
 371 
 
 240 
 
 Preparation of card fillets 
 
 164 
 
 96 
 
 Ring spinning machine, construction of 
 
 367 
 
 234 
 
 Preparation of card slivers ... 
 
 192 
 
 120 
 
 Ring spinning machine, concentricity of ring and 
 
 
 
 Principles of flat grindiDg 
 
 179 
 
 111 
 
 spindle 
 
 371 
 
 240 
 
 Principles of mixing 
 
 36 
 
 21 
 
 Ring spinning machine, Coulthard's double ring 
 
 375 
 
 246 
 
 Principles of setting card teeth 
 
 158 
 
 93 
 
 Ring spinning machine, definition of ring spinning 
 
 366 
 
 234 
 
 Principles of twisting 
 
 234 
 
 154 
 
 Ring spinning machine, diameter of rings 
 
 375 
 
 246 
 
 Production of mule spindles, 1835-90 
 
 4 
 
 6 
 
 Ring spinning machine, diameter of front rollers 
 
 383 
 
 254 
 
 Production, tables of mule 
 
 
 233 
 
 Ring spinning machine, differential drag of 
 
 
 
 Production of polishing machines 
 
 402 
 
 274 
 
 traveller 
 
 379 
 
 250 
 
 Production of roving machines 
 
 
 175 
 
 Ring spinning machine, Dobson Marsh spindle ... 
 
 372 
 
 242 
 
 Production of spooling machines 
 
 403 
 
 281 
 
 Ring spinning machine, Dodd spindle 
 
 374 
 
 245 
 
 Ring spinning machine, early use of 
 
 368 
 
 239 
 
 Productive power of machinery 
 
 4 
 
 6 
 
 Ring spinning machine, effect of weight of 
 
 Pugh's under-clearer spring 
 
 226 
 
 148 
 
 traveller 
 
 378 
 
 249 
 
GENERAL 
 
 
 Par. 
 
 Page. 
 
 Ring spinning machine, elastic spindles 
 
 373 
 
 242 
 
 Ring spinning machine, form of travellers for 
 
 
 
 bare spindles 
 
 381 
 
 252 
 
 Ring spinning machine, frictional resistance of 
 
 
 
 traveller 
 
 377 
 
 248 
 
 Ring spinning machine, gauge of spindles 
 
 383 
 
 254 
 
 Ring spinning machine, Howard and Bullough's 
 
 
 
 weft 
 
 382 
 
 253 
 
 Ring spinning machine, influence of weight of 
 
 
 
 traveller 
 
 377 
 
 248 
 
 Ring spinning machine, Lancaster's system of 
 
 
 
 weft 
 
 381 
 
 252 
 
 Ring spinning machine, lift of ring rail 
 
 367 
 
 236 
 
 Ring spinning machine, lift of spindles 
 
 383 
 
 254 
 
 Ring spinning machine, loss of twist in 
 
 380 
 
 251 
 
 Ring spinning machine, manufacture of rings ... 
 
 375 
 
 246 
 
 Ring spinning machine, Piatt's bare spindle 
 
 382 
 
 252 
 
 Ring spinning machine, Rabbeth spindle 
 
 372 
 
 241 
 
 Ring spinning machine, self-contained spindles . . . 
 
 372 
 
 241 
 
 Ring spinning machine, spinning on bare spindles 
 
 379 
 
 250 
 
 Ring spinning machine, tables of productions . . . 
 
 
 259 
 
 Ring spinning machine, tables of power 
 
 
 260 
 
 Ring spinning machine, unsteady running spindles 
 
 373 
 
 242 
 
 Ring spinning machine, velocity of spindles 
 
 373 
 
 242 
 
 Ring spinning machine, Whitin gravity spindles 
 
 374 
 
 242 
 
 Rollers, bale breaker 
 
 33 
 
 19 
 
 Rollers, calender 
 
 109 
 
 55 
 
 Rollers, cloth pasting machine 
 
 407 
 
 282 
 
 Rollers, construction of 
 
 406 
 
 282 
 
 Rollers, covering machines for 
 
 409 
 
 284 
 
 Rollers, drawing frame 
 
 208 
 
 138 
 
 Rollers, ending machines for 
 
 409 
 
 284 
 
 Rollers, grinding 
 
 186 
 
 117 
 
 Rollers, grinding machines for finished 
 
 411 
 
 287 
 
 Rollers, grinding machine for skins 
 
 408 
 
 283 
 
 Rollers, inclination of teeth on 
 
 113 
 
 60 
 
 Rollers, jointing of 
 
 406 
 
 282 
 
 Rollers, pitch of centres of 
 
 210 
 
 141 
 
 Rollers, relieving motion for 
 
 213 
 
 142 
 
 Rollers, rolling machine for 
 
 410 
 
 284 
 
 Rollers, size of 
 
 224 
 
 146 
 
 Rollers, splicing machine for 
 
 408 
 
 283 
 
 Rollers, velocity of... .« 
 
 209 
 
 138 
 
 Rollers, velocity of 
 
 224 
 
 146 
 
 Ropes, speed of driving 
 
 13 
 
 10 
 
 Rope driving 
 
 13 
 
 10 
 
 Rope driving for scutchers, Asa Lees' 
 
 91 
 
 48 
 
 INDEX. 319 
 
 
 Par. 
 
 Page. 
 
 Rope driving for scutchers, Piatt's 
 
 87 
 
 45 
 
 Roving machines, action of building motion 
 
 252 
 
 168 
 
 Roving machines, action of plate wheel 
 
 244 
 
 162 
 
 Roving machines, action of ratchet wheel 
 
 257 
 
 171 
 
 Roving machines, amount of lift 
 
 233 
 
 154 
 
 Roving machines, building motion for 
 
 250 
 
 166 
 
 Roving machines, clearers for ... 
 
 226 
 
 148 
 
 Roving machines, construction of 
 
 226 
 
 147 
 
 Roving machines, construction of building motion 
 
 251 
 
 167 
 
 Roving machines, construction of collars 
 
 229 
 
 152 
 
 Roving machines, construction of differential 
 
 
 
 motion 
 
 243 
 
 161 
 
 Roving machines, construction of speed cones . . . 
 
 249 
 
 166 
 
 Roving machines, construction of spindles 
 
 227 
 
 148 
 
 Roving machines, cone motion for 
 
 242 
 
 158 
 
 Roving machines, Curtis and Rhodes' motion . . . 
 
 247 
 
 164 
 
 Roving machines, definition of lead in 
 
 237 
 
 156 
 
 Roving machines, difference in bobbin and flyer 
 
 
 
 leads ... 
 
 . 240 
 
 158 
 
 Roving machines, effect of winding in 
 
 235 
 
 155 
 
 Roving machines, effect of diminishing rod 
 
 255 
 
 171 
 
 Roving machines, effect of ratchet wheel change 
 
 259 
 
 172 
 
 Roving machines, Higgins' bearing for spindles of 
 
 230 
 
 152 
 
 Roving machines, Howard and Bullough's electric 
 
 
 
 stop motion 
 
 263 
 
 174 
 
 Roving machines, jack frame 
 
 225 
 
 147 
 
 Roving machines, locking motion 
 
 260 
 
 173 
 
 Roving machines, Mason's long collar 
 
 229 
 
 152 
 
 Roving machines, method of driving bobbins ... 
 
 232 
 
 153 
 
 Roving machines, method of giving lift 
 
 233 
 
 154 
 
 Roving machines, method of driving spindles and 
 
 
 
 rollers 
 
 241 
 
 158 
 
 Roving machines, method of driving plate wheel 
 
 246 
 
 163 
 
 Roving machines, necessity for 
 
 225 
 
 147 
 
 Roving machines, necessity for retardation of 
 
 
 
 bobbin 
 
 238 
 
 157 
 
 Roving machines, number employed 
 
 225 
 
 147 
 
 Roving machines, number of rollers in 
 
 226 
 
 147 
 
 Roving machines, object of building motion 
 
 250 
 
 166 
 
 Roving machines, object of creel 
 
 226 
 
 148 
 
 Roving machines, operation of twist wheel 
 
 241 
 
 158 
 
 Roving machines, Paley's traverse motion 
 
 261 
 
 173 
 
 Roving machines, principles of reducing bobbin 
 
 
 
 speed 
 
 239 
 
 157 
 
 Roving machines, principlesof reducing flyer speed 
 
 240 
 
 157 
 
 Roving machines, twisting 
 
 234 
 
 154 
 
 Roving machines, winding 
 
 236 
 
 155 
 
320 
 
 GENERAL INDEX. 
 
 Par. 
 
 Roving machine, Pugh's underclearer for 226 
 
 Roving machine, pressers attachment of 228 
 
 Roving machine, reasons for bobbin lead 237 
 
 Roving machine, releasing motion 256 
 
 Roving machine, relation of strap and diminishing 
 
 rod 258 
 
 Roving machine, relative velocity of plate wheel.. 246 
 
 Roving machine, reversal of lift 254 
 
 Roving machine, setting of spindles 227 
 
 Roving machine, shape of speed cones 249 
 
 Roving machine, shortening of lift in 235 
 
 Roving machine, size of rollers 226 
 
 Roving machine, spindle speeds 234 
 
 Roving machine, table of production 
 
 Roving machine, theory of action of differential 
 
 motion 244 
 
 Roving machine, Tweedale's differential motion... 248 
 
 Roving machine, velocity of wheels 246 
 
 Roving machine, weighting of rollers 226 
 
 s 
 
 Scutching machine, Asa Lees' pedal motion ... 91 
 
 Scutching machine, Asa Lees' rope driving 92 
 
 Scutching machine, character of beater blow ... 69 
 
 Scutching machine, combinations of 93 
 
 Scutching machine combined with mixing 93 
 
 Scutching machine, conditions of successful working 94 
 
 Scutching machine, construction of air passages. .. 79 
 
 Scutching machine, construction of beaters ... 68 
 Scutching machine, construction of feed rollers 
 
 and pedals 85 
 
 Scutching machine, (Brighton's cages 76 
 
 Scutching machine, (Brighton's leaf extractor ... 77 
 Scutching machine, distance of dead plate from 
 
 beater sheet 77 
 
 Scutching machine, Dobson and Barlow's pedal 
 
 motion 90 
 
 Page. I Par. Page. 
 
 148 
 
 Scutching machine, doubling of laps in feeding... 
 
 97 
 
 52 
 
 148 
 
 Scutching machine, draught of 
 
 98 
 
 52 
 
 156 
 
 Scutching machine, drawing action of rollers . . . 
 
 85 
 
 44 
 
 171 
 
 Scutching machine, effect of dead plate on air 
 
 
 
 
 current 
 
 80 
 
 41 
 
 172 
 
 Scutching machine, Howard and Bullough's air 
 
 
 
 164 
 
 bars 
 
 74 
 
 38 
 
 171 
 
 Scutching machine, Howard and Bullough's pedal 
 
 
 
 148 
 
 bowls 
 
 86 
 
 44 
 
 166 
 
 Scutching machine, importance of balancing 
 
 
 
 
 beaters 
 
 68 
 
 36 
 
 155 
 
 
 
 148 
 
 Scutching machine, lap attachment 
 
 67 
 
 35 
 
 155 
 
 Scutching machine, lap feeding of 
 
 95 
 
 51 
 
 175 
 
 Scutching machine, lap even selvedge of 
 
 99 
 
 52 
 
 Scutching machine, lap weight and hank of 
 
 100 
 
 52 
 
 162 
 
 Scutching machine, Lord's 
 
 68 
 
 35 
 
 165 
 
 Scutching machine, Lord's piano feed 
 
 82 
 
 42 
 
 164 
 
 Scutching machine, number of workpeople re- 
 
 
 
 quired for 
 
 102 
 
 52 
 
 148 
 
 Scutching machine, object of 
 
 66 
 
 35 
 
 
 Scutching machine, operation of piano feed 
 
 84 
 
 43 
 
 
 Scutching machine, Piatt's dead plate 
 
 81 
 
 41 
 
 
 Scutching machine, Piatt's pedal motion 
 
 88 
 
 46 
 
 
 Scutching machine, Piatt's rope driving 
 
 87 
 
 45 
 
 
 Scutching machine, position of grids 
 
 72 
 
 37 
 
 47 
 
 Scutching machine, position of dead plate 
 
 75 
 
 39 
 
 48 
 40 
 
 Scutching machine, pulsations of beater 
 
 70 
 
 37 
 
 <*7 
 
 Scutching machine, setting of grid bars 
 
 73 
 
 38 
 
 48 
 40 
 
 Scutching machine, two or three winged beaters 
 
 
 00 
 
 t)\j 
 
 Scutching machine, velocity of air current 
 
 / 0 
 
 A ft 
 4U 
 
 UJ. 
 
 Scutching machine, velocity of beaters 
 
 09 
 
 OO 
 
 A 1 
 
 41 
 
 Scutching machine, velocity of cones 
 
 83 
 
 42 
 
 36 
 
 Sea Island cotton 
 
 18 
 
 13 
 
 
 Selvedges in carding 
 
 120 
 
 66 
 
 44 
 
 Selvedge, opener 
 
 52 
 
 28 
 
 39 
 
 Selvedge, scutcher 
 
 99 
 
 52 
 
 40 
 
 Setting brackets for rollers 
 
 113 
 
 60 
 
 
 Setting card covers 
 
 145 
 
 82 
 
 39 
 
 Setting card cylinders 
 
 129 
 
 74 
 
 
 Setting card pedestals 
 
 148 
 
 85 
 
 47 
 
 Setting, character of card 
 
 133 
 
 78 
 
GENERAL INDEX. 
 
 
 Par. 
 
 Page. 1 
 
 
 Par. 
 
 Page. 
 
 Setting, effect of Wellman flats 
 
 . ... 141 
 
 81 1 
 
 Spindles, setting of 
 
 ... 227 
 
 148 
 
 Setting flats 
 
 . ... 132 
 
 77 
 
 Spooling machine 
 
 ... 403 
 
 278 
 
 Setting flats, theory of 
 
 . ... 118 
 
 64 
 
 Spooling, production of 
 
 ... 403 
 
 281 
 
 Setting flats, Wellman 
 
 . ... 140 
 
 81 
 
 Standard Spinning Co's Mill 
 
 
 298 
 
 Setting flexible bend 
 
 . ... 119 
 
 65 
 
 Staple, definition of 
 
 . ... 17 
 
 12 
 
 Setting licker-in and doffer 
 
 . ... 136 
 
 79 
 
 Staple, effect in drawing 
 
 ... 210 
 
 141 
 
 Setting mote knives 
 
 . ... Hi 
 
 82 
 
 Starch pump 
 
 ... 415 
 
 295 
 
 Setting, Piatt's inspection of 
 
 . ... 137 
 
 79 
 
 Steam engines, types of 
 
 . ... 11 
 
 8 
 
 1 A A 
 
 144 
 
 Setting teeth in clothing 
 
 . ... 156 
 
 92 
 
 Stop motion drawing frame ... 
 
 219 
 
 Setting under casings 
 
 , ... 144 
 
 82 
 
 Stop motion winding frame 
 
 398 
 
 271 
 
 Seven lea motion 
 
 . ... 392 
 
 265 
 
 Stripping, method of 
 
 1 QO 
 
 
 Shape of card teeth 
 
 . ... 159 
 
 94 
 
 
 
 
 Shortening lift in roving machines ... . 
 
 . ... 235 
 
 155 
 
 T 
 
 
 
 Side grinding of card teeth 
 
 . ... 159 
 
 94 
 
 1 
 
 
 
 Side grinding, defects of 
 
 160 
 
 94 
 
 
 
 
 Side grinding, improved 
 
 162 
 
 95 
 
 Table of production of roving frame ... 
 
 
 175 
 
 Side grinding, striation of teeth by ... . 
 
 . ... 161 
 
 94 
 
 Table of production of mule 
 
 
 233 
 
 Size of driving rollers 
 
 224 
 
 146 
 
 Table of production of ring frame 
 
 
 259 
 
 Size of driving ropes 
 
 . ... 14 
 
 10 
 
 Tables of power for ring frame 
 
 
 260 
 
 Size of roving rollers 
 
 226 
 
 148 
 
 Taylor Lang's opening machine 
 
 . ... 46 
 
 24 
 
 Skeining motion 
 
 395 
 
 266 
 
 Teeth, carding, setting of 
 
 . ... 156 
 
 92 
 
 Slivers, definition of 
 
 108 
 
 55 
 
 Teeth, carding, licker in 
 
 .. ... 157 
 
 93 
 
 Slivers, doubling of 
 
 193 
 
 121 
 
 Teeth, carding, principles of setting 
 
 158 
 
 93 
 
 Slivers, doubling of 
 
 215 
 
 143 
 
 Teeth, carding, side grinding 
 
 160 
 
 94 
 
 Slivers, cans for 
 
 405 
 
 282 
 
 Testing flexible bend 
 
 119 
 
 65 
 
 Sliver lap machine 
 
 193 
 
 121 
 
 TVafincr VippI in flats 
 
 J. cftliug nccx xxx xxauo. •■ ... ... ... ... . 
 
 117 
 
 62 
 
 Slow motion, Sykes' 
 
 171 
 
 105 
 
 Theisen's condenser 
 
 11 
 
 9 
 
 Slow motion, Hetherington's 
 
 172 
 
 106 
 
 Theory of differential motion 
 
 244 
 
 162 
 
 Slow motion, Brooks' 
 
 174 
 
 107 
 
 Theory of mule winding 
 
 325 
 
 208 
 
 Slow motion, Knowles' 
 
 175 
 
 108 
 
 TVanamiQQifiTi fif nftWPT 1 bv bpltS 
 
 J. 1 cl-XIDLXXICSESXUXl Ul LIVJ w GX KJV u^ll-o . .. ... 
 
 12 
 
 9 
 
 Slubbing machine 
 
 225 
 
 147 
 
 Transmission, loss in 
 
 13 
 
 10 
 
 Slubs, production of 
 
 212 
 
 142 
 
 Twist in yarn, rule 
 
 387 
 
 258 
 
 Speed cones, construction of 
 
 249 
 
 166 
 
 Twist wheel in roving frames 
 
 241 
 
 158 
 
 Speed cones, shape of 
 
 249 
 
 166 
 
 
 
 
 Speed of combing machine 
 
 200 
 
 129 
 
 
 
 
 Speed of belts and ropes 
 
 13 
 
 10 
 
 u 
 
 
 
 Speed of roving spindles 
 
 234 
 
 155 
 
 
 
 
 Spindles, comparative speed of 
 
 9 
 
 8 
 
 
 
 
 Spindles, construction of roving 
 
 227 
 
 148 
 
 Under casings for carding machine 
 
 144 
 
 82 
 
 Spindles, number at work 
 
 3 
 
 5 
 
 Under clearer for roving machine 
 
 226 
 
 148 
 
 Hi 
 
 ■ 
 
 m 
 
 m 
 
322 
 
 GENEKAL INDEX. 
 
 
 Par. 
 
 Page. 
 
 Velocity of beater in opener 
 
 55 
 
 30 
 
 Velocity of beater in scutcher ... 
 
 69 
 
 36 
 
 Velocity ot carding cylinders 
 
 . 107 
 
 54 
 
 Velocity of carding cylinders during grinding . 
 
 . 170 
 
 105 
 
 Velocity of doner 
 
 108 
 
 54 
 
 Velocity of doffer comb 
 
 . 108 
 
 54 
 
 Velocity of main driving belts 
 
 13 
 
 10 
 
 Velocity of main driving ropes 
 
 13 
 
 10 
 
 Velocity of porcupine cylinders ... . 
 
 49 
 
 27 
 
 Velocity of rollers of drawing frame 
 
 . 209 
 
 138 
 
 Velocity of rollers of ring frame 
 
 
 259 
 
 Velocity of spindles in roving machines ... . 
 
 . 234 
 
 155 
 
 Velocity of spindles in mule 
 
 . 280 
 
 183 
 
 Velocity of spindles in ring frame 
 
 . 373 
 
 242 
 
 Velocity of wheels in differential 
 
 . 246 
 
 164 
 
 
 Par. 
 
 Page. 
 
 Waste from combing machine 
 
 ... 206 
 
 136 
 
 Wellman carding machine 
 
 ... 138 
 
 79 
 
 Width of lap for combing machine 
 
 194 
 
 121 
 
 Whiteley's clip 
 
 ... 166 
 
 101 
 
 Whiteley's fillet winding machine 
 
 ... 165 
 
 96 
 
 Whiteley's side-ground teeth 
 
 ... 162 
 
 95 
 
 Willow, The 
 
 45 
 
 24 
 
 Workpeople employed in machine making . . . 
 
 3 
 
 5 
 
 Wrap reel 
 
 .. 415 
 
 294 
 
 Y 
 
 
 
 Yarn, counts of 
 
 .. 387 
 
 257 
 
 Yarn testers 
 
 .. 416 
 
 292 
 
 John Heywood, Excelsior Printing and Bookbinding Works, Hulme Hall Road,. Manchester. 
 
ADVERTISEMENT. 
 
 JOSEPH STUBBS 
 
 MILL STREET WORKS, 
 Ancoats, MANCHESTER. 
 
 (PATENT STOP-MOTION DOUBLER-WINDER.) 
 
 SPECIAL MACHINERY 
 
 TTZSTIDEIR = 
 
 WINDING FRAMES, for winding from Mule Cops, Ring and Flyer Throstle or Doubler Bobbins. 
 HANK and PIRN WINDING FRAMES of all descriptions. 
 QUICK TRAYERSE WINDING FRAMES. 
 
 PATENT STOP-MOTION DOUBLER- WINDING FRAMES (same as above illustration). 
 
 Made from new patterns. Most simple stop-motion made. 
 
 GASSING FRAMES for Cotton, Worsted, and Silk Yarns, with latest improvements. 
 
 REELS for MULE COPS, RING and FLYER THROSTLE or DOUBLER BOBBINS. 
 
 All Reels are now made with new Patent " Bridge " Doffing Motion. This Motion consists of one piece only. 
 No soiling with oil in doffing. 
 
 YARN BUNDLING PRESSES of all descriptions. New Lifting Motion preventing breakdowns. 
 
 YARN PREPARING MACHINES, WARPING MILLS, WARPING HECKS, 
 
 YARN CLEARERS, &c. 
 
 The above Improved Machines may be seen in operation in the Show Boom at my Works, 
 
 and Inspection is specially invited' 
 
 Maker of ANNEALED and MALLEABLE IRON CASTINGS of superior quality. 
 
 Telegrams—" Winding, Manchester." Telephone No. 440. 
 
 Manchester Exchange, No. 12 Pillar, Tuesdays and Fridays, 1-30 to 3 p.m. 
 
ADVERTISEMENT. 
 
 ESTABLISHED 1791. 
 
 JOHN WHITELEY & SONS, 
 
 Brunswick Mills, HALIFAX, England. 
 
 MANUFACTURERS • CARD CLOTHING 
 
 In Mild, and Patent Hardened and Tempered Steel Wire, for Cotton, 
 
 Wool, Worsted, and Silk. 
 
 WITH ROUND, FLAT, FLAT-TO-BEND, ANGULAR & CONVEX WIRE, 
 
 PLATED "WIRE <& MUSIC WIEE, 
 
 Patent Needle Pointed Card Clothing, 
 
 ALSO 
 
 SPECIAL PLOUGH GROUND CARD CLOTHING 
 
 IMPROVED TAKERS-IN AND DIRT ROLLERS. 
 
 CARD TACKS. GAUGES for Setting Cylinders, Doffers, and Flats, &e., &e. 
 
 WHITELEY' S IMPROVED TENSION MACHINE for MOUNTING FILLETS 
 
 Flats Re-Cut and Clothed with Whiteley's Patent Clasp, Ashworth's Sewing, 
 or Lead Rivets, and Trued, Tested, and Ground ready for use. 
 
 NEEDLE POINTED STRIPPING ROLLERS. 
 
 Burnishing Brushes. Spiral Flat Stripping Brushes. 
 
 CARDING ENGINES CLOTHED, GROUND AND STARTED DY EXPERIENCED MEN. 
 
 Samples and Estimates on Application. 
 
ADVERTISEMENT. 
 
 Four Minutes from Wardleworth Station, L. & Y. Railway. 
 Fifteen Minutes from Rochdale Station, L. &* Y. Railway. 
 
 Telegrams:—" STOTT, MACHINIST, ROCHDALE." 
 
 WARDLEWORTH IRON WORKS, 
 
 WHITWORTH ROAD, 
 
 J. H. STOTT, 
 
 2Hacfyintst anb 3ronfoun5er / 
 
 MAKER OF 
 
 WARPING, WINDING, & REELING MACHINERY, k. 
 
 SPECIALITIES : 
 
 Patent Section Warping Machines. 
 Patent Curved Hecks. 
 Patent Balling Machines. 
 
 Patent Reels for Reeling Ring Frame 
 Bobbins. 
 
 Patent Dressing Frames, &c, &c. 
 
 WINDING FRAMES, FOR WINDING FROM HANKS, COPS, AND RING BOBBINS. 
 
 BEAMI1TG IIVL^OIHIinsrES- 
 COP AND OTHER REELS. BUNDLING PRESSES. PIRN WINDING FRAMES. 
 
 CABLE LAYING MACHINERY, &c, &c 
 
 w 
 
ADVERTISEMENT. 
 
 FELBER, JUCKER k CO., 
 
 MANCHESTER; 
 
 ALSO AX GLASGOW AND BOMBAY. 
 
 EXPORTERS OF ALL CLASSES OF 
 
 MACHINERY and UTENSILS for theTEXTILE TRADES 
 
 ]£8tl11iatC$ given and Plans made for complete Spinning and 
 Weaving Mills for Cotton, Wool, Flax, Jute, Silk, &c. 
 ALSO FOR BLEACHING, FINISHING, DYEING AND PRINTING INSTALLATIONS. 
 
 MILL FURNISHINGS AND STORES 
 
 Supplied of approved high-class qualities. 
 
 F. J. & Co. hold Letters Patent for numerous 
 Novelties and Improvements in connection with 
 Textile Machinery, amongst others: 
 
 JUCKERS PATENT INDICATOR FOR DRAFT TWIST AND HANKS. 
 
 TESTING MACHINES FOR TOP ROLLERS. 
 
 FAST REED MOTION. 
 
 LOOSE REED MOTION. 
 
 ADJUSTABLE SHUTTLE BOX END, &c. 
 
ADVERTISEMENT. 
 
 .-*>■ 3BSTA38L,IS3BE3EI> 1822. 
 
 ■5 
 
 TINKER, SHENTON & C° 
 
 HYI>E, near MANCHESTER. 
 
 Telegraphic Address— 
 
 "Duplex, Hyde." (JAMES SHENTON, Proprietor. Telephone No, 21. 
 
 Makers of High-Class Lancashire, Cornish, Vertical, Hyde Duplex, 
 
 AND ALL OTHER TYPES OF STEEL 
 
 9 
 
 Up to 2001bs. Working Pressure. Tested by Hydraulic Pressure to 3501bs. 
 
 Adapted and Constructed to Burn Coal, Wood, Vegetable Matter and Refuse as Fuel. 
 
 DRILLING, WELDING, FLANGING, PLANING, RIVETING, &c, by Special Machinery of 
 
 the most modern construction. 
 
 —CORNISH, DUPLEX, & VERTICAL BOILERS— 
 
 ALWAYS IN STOCK OR IN PROGRESS. 
 Please Address s*ll Enquiries as above. 
 
 Prices or Circulars on Application. Inquiries Solicited. 
 
 JAMES SHENTON has had upwards of 36 years' Practical Experience in the 
 manufacturing of High-class Steel Boilers. 
 
ADVERTISEMENT. 
 
 ESTABLISHED 1815. 
 
 T. COULTHARD & CO., 
 
 Cooper Road, PRESTON. 
 
 Specialities for Ring Spinning & Doubling 
 
 COTTON, WORSTED AND SILK. 
 
 Rabbeth, Elastic or Gravity, Booth-Sawyer & other Patent Spindles, 
 
 WITH 
 
 The Simplest and most Durable Automatic Spindle Holder. 
 
 itiiiiiiiiiHiiiiiiiiiiiitntiiiiiiniiiiiiiiiiiiiiiiiiiiiiiiiiiii^ 
 
 Patent Spinning & Doubling Rings, worth two of any other description. 
 
 iinii;i'.riiiBiiii!ii,iiiti;itiii:ini^iii ■i<«iiii!iMai'ii'intiii,ii;<i J iiii|iiinii'(iiiMii!ii:aiiiiiii'HL (ram iiha;i|]iii:ii'>MB>iiiii:i;:ii:ii ti u 
 
 FOX'S * PATENT * IMPROVEMENTS 
 
 For Worsted Spinning and Twisting. 
 
 E. JENCKES & CO.'S 
 
 (RICK'S ST AMD ARB) (Established 1854) 
 
 RING TR AVELLERS for SPINNING & DO UBLING 
 
 Throstle Frames altered to Ring Frames 
 
ADVERTISEMENT. 
 
 ESTABLISHED 1852. 
 
 Telegraphic Address: " WILSON, BARNSLEY." 
 
 Wilson & Co. 
 
 15, MARKET STREET, MANCHESTER (Opposite Royal Exchange). 
 
 BOBBINS 
 
 OF EVERY DESCRIPTION, 
 
 Made from 
 
 , a large 
 
 stock of which is always in season. 
 
 SPECIALITIES : 
 LONG & SHORT COLLAR TUBES, 
 
 Fitted at one or both ends with 
 
 "Improved Patent Steel Shields." 
 
 RABBETH BOBBINS AND WEFT PIRNS 
 
 effectually strengthened at small extra cost by Patent 
 
 STEEL OR BRASS "RING." 
 
 Every bobbin tested, and accuracy of fit and balance on Spindle guaranteed 
 MILLIONS IN USE. 
 
 WEFT PIRNS PATENT "RINGS'' & " TIPS" 
 
 are practically unbreakable. 
 
 RING DOUBLING & TWISTING BOBBINS 
 
 FITTED WITH 
 
 Patent Steel or Brass " Protectors," 
 
 Are completely protected from wearing action of Driving Studs or Pegs. 
 THOUSANDS OF GROSS AT WORK. 
 
 STEEL or BRASS "CAPS" 
 
 for above ensure a- smooth edge and prevent breakage of thread. 
 
 FLYER SPINNING & DOUBLING BOBBINS 
 
 FITTED WITH 
 IMPROVED METAL BUSHES, 
 
 ensuring accurate fit on Spindles, steady running, and uniform drag. 
 
 WARPING and WINDING BOBBINS, of superior construction, with BRASS or STEEL * RIMS," 
 
 to prevent breakage or opening of flanges. 
 
 TOP CLEARERS, Grooved or Parallel, &c, &c. 
 
 KVEEY DESCEIPTIOISr Olff" 
 
 SPINDLE PLUGS, SPLIT WINDING TUBES, CONICAL OR PARALLEL TUBES FOR CROSS-WINDING MACHINES. 
 
 Estimates for Home or Export on application to the Works : BARNSLEY. 
 
ADVERTISEMENT. 
 
 DRONSFIELD BROS., 
 
 Atlas Works, OLDHAM. 
 
 INVENTORS, 
 PATENTEES 
 
 PATENTEES 
 
 AND 
 
 MAKERS 
 
 OF ALL KINDS OF 
 
 MACHINES 
 
 AND 
 
 APPARATUS 
 
 FOR 
 
 GRINDING 
 CARDS. 
 
 AND 
 
 SOLE MAKERS 
 
 OF 
 
 MACHINES 
 
 FOR 
 
 COVERING 
 ROLLERS 
 
 WITH 
 
 CLOTH AND 
 LEATHER. 
 
 PATENT CARD MOUNTING MACHINES, &C , &C. 
 
ADVERTISEMENT. 
 
 Established 1832. 
 
 WILLIAM RYDER, 
 
 Bee Hive Works, BOLTON. 
 
 Manufacturer of all hinds of 
 
 FLUTED ROLLERS 
 
 Iron, Steel, and Case-hardened. 
 
 PLAIN & LOOSE BOSS TOP ROLLERS. 
 
 ill 
 
 SPINDLES & FLYERS 
 
 (Flyers of Steel) of every description, .for Cotton, Silk, 
 Woollen, and Flax Spinning. 
 
 Seed & Ryder's Presser attached by Patent Bottom Clip. 
 
 MULE SPINDLES. 
 
 LICENSED MAKER OF THE 
 
 FERGUSLIE PATENT RING SPINDLE 
 
 For Spinning or Doubling. 
 
 SOLE LICENSED MAKER OF THE 
 
 WHITIN PATENT GRAVITY SPINDLE 
 
 for sFiisrisriisrG- or rjoTTBLiisra-. 
 
 RING SWINDLES 
 
 On the Flexible, Rabbeth, and other principles. 
 
 INVENTOR, PATENTEE, AND MAKER OF 
 
 RYDER'S FORGING MACHINES. 
 
 ALSO MAKER OP 
 
 The FERGUSLIE WH|T|N 
 Patent doubling Spindle. Sawing Machines tor not iron, Gravity Spindle. 
 
 _A-1S3"I3 OTHER TOOLS. HALF SIZE. 
 
 Unlimited Speed without 
 vibration. 
 
 WILLIAM RYDER, Bee Hive Works, BOLTON. 
 
ADVERTISEMENT. 
 
 HENRY LIVESEY Ltd., BLACKBURN. 
 
 MACHINISTS AND MAKERS OF 
 
 ^LOOMS^ 
 
 FOR 
 
 Weaving Printers, Shirtings, T. Cloths, Domestics, Dhooties, &e. Blackburn and Keighley Double-Lift Dobbies 
 up to 40 Shafts. Drop Box Looms for Ginghams, Handkerchiefs, &e. 
 
 ESTIMATES FOR 
 
 EVERY DESCRIPTION OP 
 
 WEAVING MACHINERY 
 
 Illustrated Catalogues on application. 
 
 Attend 
 Exchange, 
 Manchester, 
 
 every 
 Tuesday and 
 
 Friday, 
 10 Pillar, 
 
 1-30 to 2-30. 11 
 
 Established 
 1863. 
 
 LIVESEY'S DROP BOX LOOM for Checks, Ginghams, Oxfords, Harvards (up to 5 Shuttles). 
 MAKERS OF THE 
 
 HYDRAULIC CLOTH PRESSES, &c. 
 
 PLAITING MACHINES. 
 
 Looming & Drawing-in Frames, &c. 
 
 MAKERS ALSO OF 
 
 BOBBINS, TUBES, SHUTTLES, k 
 
 Loom Sides Planed and Cross Rails cut to exact length with Special Tools. Bushes and Seatings on 
 
 Loom Sides Planed by Special Machinery. 
 
 s ^ XT T T I* E BOXES PLANED. 
 
 Improved Cast-Iron Taking-up Beam, 
 
 COVERED WITH FILLETING. 
 
 'Slasher' Sizing & Warping Machines. 
 
 COP & THROSTLE WINDING MACHINES. 
 
 DRUM WINDING & SPOOLING MACHINES 
 
 For Linen and Coloured Yarns. 
 
ADVERTISEMENT. 
 
 THE 
 
 STEAM CYLINDER LUBRICATOR. 
 
 SPECIAL FEATURES. 
 
 Automatic in Action. 
 Easily Fixed- 
 Reliable and Positive, 
 
 Efficient and Easily 
 Regulated. 
 
 No Dirty Glasses. 
 Economical. 
 
 Few Parts in Small 
 
 Space. 
 Perfect Sight-Feed. 
 
 PRICES AND 
 
 REFERENCES 
 ON 
 
 APPLICATION. 
 
 DESCRIPTION.— A is the oil chamber in which works a piston B, haying screwed into its top side a hollow piston rod K, which 
 works through a stuffing box. This piston rod also serves as an indicator showing the level of the oil. At the top end of the rod is a 
 filling-plug J, through which the oil is delivered into the chamber A, the oil passing through the small holes at the bottom of the 
 tube ; D is the steam inlet, H the oil outlet, G the sight-feed, L an air valve, M a plug which can be unscrewed and the sight-feed G 
 inserted at the other side or a second applied, E is a run-off valve, and C is the base to which the Lubricator is fixed. 
 
 THE STEAM CYLINDER LUBRICATOR CO. LIMITED, 
 
 65, KING STREET, MANCHESTER. 
 
 Telegraphic Address: 
 "SEAFIELD, MANCHESTER." 
 
ADVERTISEMENT. 
 
 THE MONTHLY JOURNAL 
 
 OF THE 
 
 Ccyttk 3tt5iistrtes 
 
 Published on the 15th day of each month 
 
 PRICE SIXPENCE. 
 
 Post-free, 9s. per annum. 
 
 Is recognised at 
 HOME and ABROAD 
 
 as the most 
 
 'USEFUL and PRACTICAL 
 
 YgXCILG IUaGAZIHG. 
 
 NOTE. — It is indisputable that the articles in "The Textile Recorder" 
 are quoted in Continental, Colonial, and American Trade Magazines, 
 to a greater extent than those of any other Textile Journal. 
 
 70HN HEYW00D, 1, Paternoster Buildings, London; and Ridgefield, Manchester 
 
ADVERTISEMENT. 
 
 THEISEN'S PATENT CONDENSERS. 
 
 FOR STEAM ENGINES AND VACUUM PANS. 
 
 PARTICULAR MERITS. 
 
 I. No water is wasted or consumed, as the condensed 
 water can be used for feeding the boiler, and 
 the same quantity ordinarily employed for boiler 
 feeding suffices for effecting condensation. 
 
 II. Hot distilled water is obtained, affording an absolute 
 preventative against boiler incrustation. 
 
 III. Very active condensation is obtained with a com- 
 paratively small surface, this effect being 
 brought about by the rapid absorption of the 
 heat through evaporation. 
 
 IV. A high degree of vacuum is secured, resulting 
 in a great saving of fuel. 
 
 V. Hot and impure water can be used for cooling. 
 
 VI. The apparatus can be executed to suit the most 
 exacting requirements. 
 
 VII. The cooling surfaces are automatically kept clean 
 
 VIII. The condensing passages are easily accessible. 
 
 IX. The apparatus is simple in construction and 
 easily manipulated. 
 
 SOLE LICENSEES FOR THE UNITED KINGDOM AND COLONIES: 
 
 THE UNION ENGINEERING CO., 
 
 1, Clarence Street, 
 
ADVERTISEMENT. 
 
 GEO. THOMAS & CO., 
 
 28. ZDZE^nsrS&.A.TIE], 
 
 Cable and Telegraphic Address 
 "SAMOHT, MANCHESTER." 
 
 MANCHESTER. 
 
 ENGINEERS, CONTRACTORS, and EXPORTERS of all Classes 
 of MACHINERY, and ACCESSORIES, &c. 
 
 N.B. Representatives in all the Industrial Centres of the "World. 
 
 MACHINERY for SPINNING and WEAVING Cotton, 
 Wool, Worsted, Flax, Hemp, Jute, Silk, &c. 
 BLEACHING, DYEING, PRINTING, FINISHING 
 
 Textile Fabrics. 
 
 Steam Boilers, Steam Engines, Economises, Turbines, Mill Gearing, Electric Lighting and 
 
 Gas Plant; Hoists, &c. 
 Ironwork for Mills from A to Z— Fireproof, &a, Roofing and Patent Glazing; Heating and 
 
 Ventilating Apparatus. 
 Paper, Rice, Sugar, Ice, Flour, Oil, Chemical, Distillery, Iron and Steel Plants. 
 Portable and Permanent Railway Plant, Rolling Stock, Locomotives, Steam Ships, Steam 
 
 Launches, Dredgers, &c. Hydraulic Machinery and Tools. 
 
 SOLE OMCitlCEBEiS ATSTDO 3P3R03P3RIEX03RS OF THE 
 
 PATENT UNIVERSAL YARN ASSORTING BALANCES. 
 
 British Patent, No. 6,703, 1886. U.S.A. Patent, No. 380,826, 1888. New Patents, No. 15,454, 1889, and No. 9,264, 1890. 
 
 N.B. — These Balances or Yarn Testers (indispensable to Spinners, Manufacturers, and Merchants) indicate the Counts of Yarn in small 
 lengths, or from bits of cloth, in either Cotton, Woollen, Worsted, Linen, Jute, or other Fibre. 
 
 "S" Balance. "Simplex" Balance. 
 
 
 MMfffffffliTJ M « 1 J 
 
 
 
 Price 
 
 
 65/- 
 
 
 SCALE One-filth of fall size. 
 
 EDITORIAL. AND PUBLISHING DEPARTMENT : 
 
 INDUSTRIAL PROGRESS ABROAD (Brochure) by Geo. Thomas, 1876 Price 1/- 
 
 TEXTILE READY RECKONER (Universal Tables for Calculating the Structures of Cotton, Woollen, Worsted, Linen, Silk, 
 
 and Mixed Fabrics). (Translation from Staub)-1888. Price 6/6 ... 
 STOCKHOLM'S MARIA ELEVATOR (Hydro- Pneumatic Passenger Lift), by Geo. Thomas, with 5 plates, 1888. Price 2/6 
 ELEMENTARY TREATISE ON THE FINISHING of White, Dyed, and Printed COTTON Goods (Translation from Depierre), 
 1889, Price 30/- . 
 
 geo. t: 
 
 So GO. 
 
ADVERTISEMENT. 
 
 CHARLES H. PUGH 
 
 Whitworth Works, 
 
 BIRMINGHAM, England. 
 
 MACHINIST & MANU FACTURER. 
 
 SPECIALITIES = 
 
 SCREWS. WIRE GUIDES of all descriptions. 
 
 STAMPINGS in all Metals. Small Parts of Machinery. 
 BOLTS, NUTS, and WASHERS. BRIGHT TURNED STUDS. 
 
 Flat and Coiled SPRINGS. 
 
 PATENT UNDER CLEARER SPRING 
 
 FOR 
 
 ZRO^rmSTG- FEAMES. 
 
 METAL WORKER, &c 
 
 SUNDRIES FOR TEXTILE MACHINISTS. 
 
 Inventions worked out by a Trained Staff of Toolmakers, 
 
 CORRESPONDENCE INVITED. 
 
ADVERTISEMENT. 
 
 ROBERT HALL £ SONS 
 
 Attendance at 
 Manchester Royal Exchange, 
 
 No. 8 Pillar, 
 Every Tuesday and Friday only. 
 
 — o — 
 
 Telegraphic Address: Hall, Bury 
 
 Office: 
 
 9 
 
 Near MANCHESTER. 
 
 Office: 
 3, HOPWOOD AVENUE, 
 MANCHESTER, 
 Every Tuesday and Friday only. 
 
 — o — 
 
 Telegraphic Address : Hall, Bury. 
 
 POWER LOOMS 0F Description. 
 
 ALL KINDS OF PREPARING & FINISHING MACHINERY 
 
 FOR WEAVING PURPOSES. 
 
 SPECIALITIES — ESTABLISHED 1844. 
 
 Tapestry and Brussels Carpet Looms. 
 Hosepipe and Belting Looms and Machinery. 
 Turkish Towel and Sailcloth Looms. 
 Drop-Box Looms. 
 
 Pirn and Drum Winding Machinery. 
 
 Shearing and Raising Machines. 
 
 Sectional Warping and Balling Machines. 
 
 Plush and Slipper Carpet Looms. 
 
 Fustian and Bed-Tick Looms and Machinery. 
 
 Jacquard and Dobby Looms. 
 
 Damask Looms. 
 
 Sponge Cloth Looms. 
 
 Winding and Warping Machinery of every description. 
 
 SPECIAL ATTENTION DIRECTED TO OUR WINDING & WARPING MACHINERY. 
 
 COMPLETE LISTS OF MACHINERY MADE ON APPLICATION. 
 
 LETTERS TO T3E ADDRESSED -- 
 
 HOPE FOUNDRY, BURY, LANCASHIRE. 
 
 French and German Correspondence. 
 
ADVERTISEMENT. 
 
 LAMBETH COTTON ROPES 
 
 T n ordering these Ropes the diameter should not be overstated. They contain more yarn in the given diameter than is 
 usual, and, not being liable to stretch, no provision need be made for loss in thickness. 
 
 Also DRUM, RIM, SCROLL, SPINDLE, RING SPINDLE, TAPE and TUBULAR BANDINGS to any description for Cotton Mills. 
 The Lambeth Cotton Ropes are of unique design and construction, superseding all other Ootton Ropes for MAIN DEIVINGr. 
 
 Tension and Friction accurately measured for and provided against, and the Ropes fitted exactly to the working part of the 
 
 grooves of the Pulley. 
 
 A LARGE STOCK OF ALL SIZES KEPT, TO MEET URGENT ORDERS, 
 
 Notb. — No Ropes are the genuine Lambeth unless supplied direct from my works, where they are alone made, or bearing my 
 
 Registered Trade Mark. 
 
 JStlllnillltlllllllllllllllllllllllllllll 
 
 ESTABLISHED 
 1789. 
 
 BLACKBURN. 
 
 ESTABLISHED 
 1789. 
 
 Telephone no, 10. 
 
 Telegraphic Address: "HART, BLACKBURN." 
 
ADVERTISEMENT. 
 
 CHARLES LANCASTER, 
 
 Consulting Engineer to Spinners, Manufacturers anil Shippers, 
 
 35, MARKET STREET, MANCHESTER. 
 
 TECHNICAL information on Carding, Spinning, Sizing and Weaving. 
 OLD MILLS (home or foreign) re-organized to improve quality and quantity 
 of Production. PATENTS bought from or introduced for Inventors. 
 
 RECIPES FOR SIZING WARPS AND "FILLING " CLOTH. 
 
 LANCASTER & CO., 
 
 Mill Engineers and Praetieal BUYING AGENTS for Mills Abroad of 
 
 SPINNING & WEAVING MACHINERY, 
 
 and of Mill Stoves, from ALL Makers at Clients' option. 
 
 Plans and Estimates of complete New Mills. Practical Mill Managers, 
 Carders and Tacklers engaged for Clients abroad. 
 
 Before ordering Machinery and Mill Stores elsewhere, 
 
 write LANCASTER & CO., who know the Cheapest Markets, and deal with all the 
 leading Makers. 
 
 L. & CO. will supply you with Machinery and Sundries from your 
 usual Maker at his lowest prices. 
 
 Offices opposite Royal Exchange, MftflfiHESTERi 
 
A D VER TlSEMENTS. 
 
 ROLLER SKINS 
 
 Suitable for all elasses of SPINNING. 
 
 ALL I£IKrX>S OE* 
 
 LEATHERS FOR MANUFACTURERS, 
 
 Brown & Green Bands, Butts, Laces, 
 
 SAMPLES AND PRICES ON APPLICATION. 
 
 JOHN CURTIS & CO., Leather Dressers, 
 
 ROBERT STREET, CHEETHAM, MANCHESTER. 
 
 A. MOORHOUSE, 
 
 Engineer & Machinery Merchant, 
 
 7, MARKET STREET, MANCHESTER. 
 
 SPECIALITIES, 
 
 STEAM OVENS and KETTLES, for Mills and Works, heated by a Small Jet of Steam. 
 PASTE MIXING MACHINES, for Mixing Paste and Pumping it into Mule Rooms 
 WROUGHT-IRON SPLIT PULLEYS, SHAFTING, &c. 
 
 HEATING, LIGHTING, and VENTILATING MILLS, WORKS, and WAREHOUSES. 
 
 RING SPINDLES. 
 RINGS. 
 RING TRAVELLERS. 
 
 LOOSE BOSS TOP ROLLERS. 
 LONG and SHORT COLLARS. 
 BOBBIN WHEELS, &e. 
 
 NEEDLE LUBRICATORS and MACHINERY GLASS of every kind 
 
 used in Doubling. 
 
 TO COTTON SPINNERS AND OTH ERS -Machinery a nd Tools sold on Commission. 
 
 Aduice giuen regarding Colours and Materials used in Dyeing, by a practical Dyer and Chemist. 
 
ADVERTISEMENT. 
 
 CO 
 
 li 
 
 O -J 
 
 < 5 « 
 ° z 
 
 BC — 
 HI C3 GQ 
 
 EEs 
 £52 
 
 x ee ui 
 I- < S 
 
 2h 
 
 H Z 
 
 < £ 
 
 "5S 
 
 e „ 
 
 Si v. 
 
 >3 CO 
 CO ^co 
 
 a o 
 
 CD CO 
 CO 
 
 o 
 
 -O 
 
 co Q. 
 
 ! 2 
 
 3 CO 
 
 °- s 
 2~<8 
 
 :§ § 
 
 ^ o 
 
 |*. 
 
 CO CO 
 
 If 
 
 •5 S 
 
 :=> oa 
 
 o ^ 
 a © 
 
 * .1 
 
 +3 J*) 
 
 u_ CO 
 
 © CO 
 
 c ° 
 5 
 
 •C = 
 
 « .2 
 
 O So 
 
 ^ « 
 
 CO 5 
 
 co .£ 
 
 § s 
 
 CO CD 
 O 
 
 C CD 
 
 B "C 
 
 CO 
 
 cj a. 
 
 •J- 1 CO 
 
 J s 
 
 CJ .E 
 
 CO o 
 
 ? I 
 
 s « 
 
 QQ 
 
 83 eg 
 
 .3 «2 
 
 «J o 
 
 CO 
 
 a? 
 
 5=1 
 
 s 0 
 
 IS 
 
 _ O 
 
 o3 
 
 0 
 
 i 
 
 a 
 
 GO 
 
 | 
 
 o 
 1 
 
 0) 
 C4 
 in 
 
 a 
 
 | 
 
 c$ . 
 ft 0) 
 
 ft « 
 % c 
 
 W -IH 
 
 +» 
 
 o 
 
 0 
 0 
 
 H 
 
 0 =. 
 
 1 5 
 
 O w 
 
 C to 
 
 B O 
 
 < S 
 
 pcf 
 O 
 H 
 < 
 
 IH 
 
 H 
 
 k 
 w 
 
 !> 
 
ADVERTISEMENT. 
 
 JOSEPH NASMITH,A.I.Mech.E., 
 
 Consulting (Engineer, 
 
 4, ARCADE CHAMBERS, ST. MARY'S GATE, 
 
 MANCHESTER. 
 
 ADVICE GIVEN ON TEXTILE MECHANICS. 
 
 • 
 
 Machinery Bought on Commission or Inspected for 
 
 Foreign Clients. 
 
 General Expert Work Carried Out. 
 
 CORRESPONDENCE INVITED. 
 
4 
 
 DEC 15 1890 
 
 3S(S 
 
 ADVERTISEMENT. 
 
 PATENT 
 
 E BURNER 
 
 Date Due 
 
 N THE MARKET. 
 
 TO STEAM : 
 
 SMOKE PROBLEM I 
 SIMPLIt 
 
 This apparatus ful / 
 for TESTING SMOK1— 
 work in Fleet Stree' 
 
 ZZZBS' PATENTS. 
 ;edom from smoke. 
 
 ORE SEEN. 
 
 >n by the COMMITTEE 
 >aratus can also be seen at 
 
 >EKS. 
 
 For References and Details apply to the STEAM USERS' DEPOT, 6a, FOUNTAIN 
 STREET, MANCHESTER. 
 
 Two large boilers, 30ft. by 7ft. t kept for exhibition trials only at Egret Mills, Old Street, Ashton-under-Lyne, 
 can be tested by engineers or steam users on three days every week. The water measured and coal weighed 
 per hour. ______________ 
 
 W. McG. GREAVES, 
 
 Egret Mills, Old Street, Ashton-under-Lyne. 
 
ADVERTISEMENT. 
 
 LANG BRIDGE, Paradise Works, 
 
 ACCRINCTON, ENGLAND. 
 
 IR SPECIALITIES. 
 
 OP Sliver Can, double the strength and durability of others at same weight. 
 • the highest satisfaction. 
 
 sh supply of Boiled Starch or Size to any part of mill. 
 
 rrpose. 
 
 Is, Spinning, Warping, or Store Rooms. Can be seen at work, 
 rnishings, &c, &c. 
 
 GETTY CENTER LIBRARY