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Art of Coppersmithing. 
 
 A PRACTICAL TREATISE ON WORKING SHEET 
 COPPER INTO ALL FORMS. 
 
 THIRD EDITION, REVISED. 
 
 By 
 
 JOHN FULLER, Sr. 
 
 PUBLISHED BY 
 
 DAVID WILLIAMS COMPANY, 
 
 232-238 William St., New York. 
 
 1904 
 
iY of OONGRESS 
 
 fwo -Oepies ristsiveii 
 
 JUN 1 5^5 
 Cooyngni entry 
 
 OLASS^CC XXc. No; 
 
 COPY 8. 
 
 » f 
 
 «M 
 
 Copyrighted, 1893, by John FuiXER, Sr. 
 Copyrighted, 1904, by John Fuller, Sr. 
 
DEDICATED 
 
 O THE MEMORY of my Father, to 
 whose early instruction much of the 
 following work is dtie : and to the Boys 
 of the Copper Trade, in the hope that 
 it may assist them to acquire pro- 
 ficiency in the art of Copper Work- 
 ing. 
 
TO THE READER. 
 
 When a boy between the age of nine and fifteen years, struggling 
 along with my father, trying to be what was then called a Tinman 
 and Brazier, I was compelled by circumstances to encounter many stum- 
 bling blocks and overcome many obstacles in the way of education. It 
 will be noticed in the opening pages of this work that the writer 
 was but a mere child when, like thousands of other children, he 
 commenced to handle tools, not toys. As my childish mind began to 
 develop and inquire into the whys and wherefores of things about me, 
 I also began to look for a source of information, beyond the shop, to 
 assist me to fill the position it seemed I was destined to occupy with 
 a hope of some degree of distinction (for most children have aspira- 
 tions). My search was incessant, and not altogether in vain, because 
 among the vast amount of chaff searched I found occasionally a golden 
 grain, which was laid up in the storehouse of my mind. 
 
 I jotted down instinctively in my memory each practical lesson 
 learned in the shop, which was my only record. After using every 
 means at my command to obtain the education necessary, wrestling 
 in the little spare time allotted to me in the evening with such books 
 as came in my way, storing my mind indefinitely for several years 
 with whatever seemed likely to be useful, I went to London. Here 
 I ransacked every old book stall I could find, hoping to find some 
 guide to the copper trade ; but all in vain. I never discovered a line to 
 
help me. I then resolved to exert every effort to acquire the neces- 
 sary ability, so that when a favorable opportunity should offer I could 
 give my experience for the benefit of boys placed in the same unfortunate 
 position as myself. 
 
 And while the aspirations of my youth died away amid the busy 
 turmoil of mechanical life, and smoldered for years (with an occasional 
 burst of warmth), the thoughts were still cherished, and I began without 
 any preparation, save my memory, to give the helpless boys of the 
 trade reliable instruction in things they should know in starting out to 
 acquire the " Art of Coppersmithing." I did my best to tell from my 
 own experience, in the most lucid manner, that which is being called for 
 in everyday life, in three separate branches of the copper trade, sup- 
 posing with each lesson there was a good boy at my side. I am pleased 
 with the result of my first effort, which was in a measure impromptu. 
 It will not, however, make Coppersmiths of any one without effort and 
 application, but I trust it will be a help to all who have need of assistance, 
 and be an incentive to boys to exercise whatever talents they may 
 possess for their own benefit and that of others less fortunate. 
 
 Before closing my few introductory remarks I desire to tender 
 thanks to The Metal Worker for the opportunity afforded me for the 
 consummation of my work. 
 
 John Fuller, Sr. 
 Seneca, Kansas. 
 
TABLE OF CONTENTS. 
 
 Page. 
 Historical Sketch of Copper I 
 
 Braziers' Art, or Light Coppersmithing 6 
 
 First Year's Experience 14 
 
 Repairing and Tinning 17 
 
 The Boa's Second Year 22 
 
 Making Washing Coppers 26 
 
 Making Small Brewing Coppers 31 
 
 Table of Dimensions and Capacity 33 
 
 Making Hand Bowls 35 
 
 Making Frying Pans 42 
 
 Making Closet Pans 47 
 
 Making Water Balls ' 47 
 
 Mounting for Copper Goods 5° 
 
 Glue Pots and Tea-Kettles 61 
 
 Oval Tea-Kettles 68 
 
 Beer Mullers 71 
 
 Funnels 80 
 
 Coffee Pots 83 
 
 Saucepans and Pudding Pots 87 
 
 Stewpans 93 
 
 Stock Pots 99 
 
 Fish Kettles 102 
 
 Brazing Pans 104 
 
VI CONTENTS. 
 
 Page. 
 
 Tea Boilers 107 
 
 Warming Pans 112 
 
 Preserving Pans 117 
 
 Dripping Pans 1 18 
 
 Coal Scoops and Coal Hods 122 
 
 Making Coal Scoops 128 
 
 Planishing and Smoothing 148 
 
 Cranes or Syphons 151 
 
 Pumps 1 54 
 
 Appliances of Railway and Marine Coppersmiths 162 
 
 Making Copper Pipe . . 171 
 
 Piecing and Joining Pipes 173 
 
 The Fire Pots 176 
 
 Fire Pot Set for Brazing Joint 178 
 
 Soft Soldering Large Joints 180 
 
 Taking Templates. . . . : 183 
 
 Filling and Bending 183 
 
 Making Bends 186 
 
 Template Boards 191 
 
 Patching Pipes 196 
 
 Outlets 199 
 
 Expansion Joints 204 
 
 Tee Pieces 209 
 
 Three-Way Pieces 211 
 
 Cross or Four- Way Pieces 213 
 
 Saddle Fire 217 
 
 Marine Work 219 
 
 View of Maudsley, Sons & Field's Shop 221, 222 
 
 Making Large Bends 224 
 
CONTENTS. VII 
 
 Page. 
 
 Making Double Bends 227 
 
 Brazing- on Flanges 230 
 
 Short Bends 232 
 
 Air Pipes for Ships 234 
 
 Making Hollow Spheres 241 
 
 Brazing Sheet Brass 248 
 
 Locomotive Brass Work 252 
 
 Brazing the Joint of Valve Chimneys 258 
 
 Brass Dome Covers 262 
 
 Heavy Pipes for Breweries 269 
 
 Brewing Coppers or Kettles 281 
 
 Dome Coppers 293 
 
 Dome and Pan Coppers 299 
 
 Tallow Coppers ' 301 
 
 Dyers' Coppers 307 
 
 Sugar Tieches 311 
 
 Stills 312 
 
 Index 318 
 
HISTORICAL SKETCH OF COPPER. 
 
 Copper is one of the most important of the seven metals mentioned 
 by ancient historians. It was known probably before the time of 
 Tubal Cain, who was well acquainted with its uses and an educator of 
 workers in brass and iron. Grecian historians say that Cadmus dis- 
 covered copper and taught its application to the wants of his country- 
 men. It was brought to notice on the island of Eubcea, near the city 
 of Chalkis, and thus we may suppose the Grecians gave it the name of 
 chalcos, by which name the metal was known to Homer and other ancient 
 authors. The old Romans knew copper as aes cyprum, and later as cyprum, 
 names apparently derived from that of the island of Cyprus,where Pliny 
 says the art of working it was first discovered. It is certain that 
 upon this island the Phenicians had opened copper mines at a very 
 early period. Hence, in the mystic nomenclature of the old alchemists, 
 copper received the name of Venus, the goddess to whom Cyprus 
 was sacred, and among their signs it was known by the astronomi- 
 cal sign of that planet, ? . The English word copper, the German 
 kupper, the Spanish cobre and the French cuivre were probably intro- 
 duced into those languages during the middle ages and seem but 
 slight modifications of the Latin name. Copper is mentioned in the 
 oldest records and appears to have been one of the first metals brought 
 into use by mankind. We are led to this conclusion by the con- 
 sideration of its nature and the probable manner of its occurrence. 
 Masses of native metal, separated bv water from the original beds 
 and deposited by floods in spots where warlike people sought mate- 
 rials from which to make their rude weapons would, by their weight, 
 color, luster and malleability, quickly attract attention. These 
 qualities, in connection with the fact that pure native copper is 
 often detached in masses of considerable size, make it more than 
 probable that this metal was the first upon which the unskilled 
 attempts of the primitive smiths and smelters were made. It is 
 generally assumed, without any authentic evidence to support the 
 assumption, that the ancient workers in copper had some particular 
 alloy of tin and copper which they made so hard that they were 
 
2 ART OF COPPERSMITHING. 
 
 able to cut the hardest rocks, and the remains of large temples, 
 whose columns were of porphyry and syenite, seem almost incapable 
 of any explanation except by this supposition. Another fact in con- 
 nection therewith challenging examination is that the Incas in Peru, 
 although unable to make any use of the iron ores which lay pro- 
 fusely about them, were familiar with the special properties of this 
 particular hard alloy of copper and tin and made it in proportions 
 almost the same as those which the ancients adopted in the Old 
 World, using it to construct the tools necessary for cutting the stones 
 required in the building of their immense aqueducts and temples. 
 Whether the Phenicians, who carried tin from Britain, acquired the 
 knowledge of making bronze there is not certain ; but it may prob- 
 ably be assumed that the weapons and tools of bronze found in the 
 graves of some ancient race in various European lands, and which 
 are known to be Celtic remains, were taken by wandering tribes from 
 that region of Britain where at the present day the descendants of 
 the same Celts have been and are possibly to-day among the largest 
 copper refiners on the globe; and there the richest, and until 
 recently the only known, tin region within thousands of miles occurs. 
 
 Uses of Copper. 
 
 In the construction as well as the beautifying of public buildings 
 copper, bronze and brass have all played an important part, the 
 roof being covered with copper, the monuments dedicated to the hon- 
 ored dead being of bronze and the decoration of their walls artistic- 
 ally executed in brass. The invention of gunpowder and the intro- 
 duction of bronze cannon, which were used in the fourteenth and fif- 
 teenth centuries, added greatly to the increasing value and stimulated 
 the production of copper, and as civilization advanced the desire for a 
 metal similar in its properties and beauty to gold and silver rapidly 
 increased until there is scarcely a branch of human industry where 
 copper is not an important factor in the means of arriving at or secur- 
 ing greater perfection. It is employed in nearly all kinds of machin- 
 ery, either pure or as a compound. We see it in the hands of. the mu- 
 sician, in the construction of mathematical instruments and instru- 
 ments for the astronomer, adding to the security of sailing-ships and 
 contributing its share in the internal construction of ocean steamers 
 that ply between the Old and the New World, besides furnishing a path 
 for the electric current in its journey from continent to continent in 
 
ART OF COPPERSMITHING. 3 
 
 the service and extension of civilization. It supplies a reagent for the 
 chemist and gives the physician a remedy against disease. The elec- 
 tro-metallurgist uses it to catch and make prominent the evanescent 
 forms of nature and art. The dyer, the cook, the brewer and distiller, 
 use it, and in many other important industries it is in constant consump- 
 tion, while almost every advance in science adds to the number of its 
 applications. 
 
 Copper Mines. 
 
 At Newlands, near Reswick, in Cumberland, England, some rich 
 mines of copper were worked as early as 1250, and it seems that in 
 1470 this place was still famous for the amount of metal it produced. 
 Ecton Hill, in Staffordshire, was another place where copper was ob- 
 tained in abundance before the era of copper-mining in Cornwall. It 
 is somewhat interesting and amusing, in the light of passing events 
 when searching into the history and development of the mineral re- 
 sources of England, to meet with acts of Parliament passed in the 
 reigns of Henry VIII and Edward VI for the purpose of preventing 
 the export of copper and brass, '"lest there should not be metal enough 
 in the kingdom fit for making guns and other engines of war and for 
 household utensils ; " and then down to so late a date as 1708 we find a 
 memorial presented to the House of Commons by the workers in brass, 
 stating that " England by reason of the inexhaustible plenty of cala- 
 mine might become the staple of brass manufacture for itself and for- 
 eign parts, and that the continuing the brass works of England would 
 occasion plenty of rough copper to be brought in." 
 
 At this time nearly all the copper used in England came from the 
 Continent, principally from Hungary, and not till 17 17 do we read of 
 English pennies being made from English copper. About the close of 
 the seventeenth century the attention of Cornish tin-miners was drawn 
 to the more valuable cupreous deposits around them; previous to that 
 time copper ore had been of little value, and was sold under the name 
 of poder, but this was produced from mines originally opened and 
 worked for tin. The yellow pyrites of copper was the first ore recog- 
 nized as valuable by the miner; the richer black oxide of copper was 
 considered as worthless, and tons of it were thrown into the sea or 
 left in the lodes to reward the later and wiser explorers. Deposits be- 
 gan gradually to be opened for the copper they contained about the 
 beginning of the last century, and from that time to the present the 
 
4 ■ ART OF COPPERSMITHING. 
 
 produce of the ore has steadily increased, as well as the consumption 
 of the metal taken from it. The discovery of the rich mines in Angle- 
 sea in 1768 was followed by the addition of Devonshire and Ireland to 
 the number of copper-producing regions, and later on immense quan- 
 tities of ore were imported from Cuba, Chili and the Pacific islands. 
 
 The Smelting of Copper. 
 
 The advantage of sending ores to be smelted in the rich coal dis- 
 tricts of Wales was very early perceived, and even in 1586, according 
 to Carew, copper ore was shipped there from Cornwall. In 1765 
 several furnaces were in existence near Bristol — still famous for its 
 brass — and several others along the coast westward. The various proc- 
 esses then in use appear to have been almost the same as that prac- 
 ticed as late as 1865 and known as the English method of smelting 
 copper; and considering the complex natuie of the many operations 
 which it includes and the remarkable difference that exists between 
 those practiced at that time in all other refining countries, we cannot 
 help admiring the ingenuity and judgment of those old metallurgists 
 who, aided only by their own observation, worked a system which, 
 while so well adapted to all the circumstances of the locality, can be 
 used in the treatment of every known variety of ore and has withstood, 
 with scarce a change, the keenest research of modern science. 
 
 American Copper Mines. 
 
 In America copper in paying quantities has been found in nearly 
 every State through which run the Appalachian chain of mountains. 
 The oldest incorporated mining company appears to have been one 
 for the purpose of reducing ores in Connecticut, the date of whose 
 charter is 1709. But all other deposits sufficiently developed to assure 
 a definite knowledge of their value are exceeded by those which within 
 the last 25 years have been opened in California, Arizona, New Mexico 
 and in particular in Montana and upon the shores of Lake Superior. 
 That this wonderful lake region was occupied by a race which existed 
 at a time prior to the earliest authentic aboriginal history is evident 
 from the remains which still exist of gangways, tools, and other proofs 
 of skill which the races occupying the country at the time of its dis- 
 covery nowhere make manifest. The Indians met by the first trav- 
 elers were quite ignorant of the methods of working that had been 
 practiced by the former race ; they could give no accounts to explain 
 
ART OF COPPERSMITHING. 5 
 
 the numerous excavations, and what copper they possessed was gath- 
 ered from the surface stones. The first record of the deposits is 
 found in the missionary report of the Society of Jesus for 1659-60. 
 The natives had then rude utensils made from this metal, and large 
 blocks of it were erected and worshiped among their gods. In 1768 
 an Englishman named Henry, a practical man, carefully examined 
 the old works at great risk, on account of the native hostility, and in 
 1 77 1 established works which were operated a short time only and 
 then abandoned. The later and more successful mining era begins 
 about the year 1844. The careful inspection of competent scientific 
 men made those regions gradually known to the world, and practical 
 miners who were drawn thither by the reports of mineral wealth 
 soon discovered large blocks of copper permeated with silver. A great 
 excitement was caused among adventurers and capitalists, who formed 
 companies in various parts of the world to work in localities of which 
 not even a survey had been made. In 1847, however, the crisis came, 
 and of the then hundreds of nominally existing companies only six 
 were found actually engaged in mining. The results of these early 
 disasters have gradually disappeared. Since then the progress of this 
 region has been healthy and profitable. 
 
ART OF COPPERSM1THING. 
 
 THE BRAZIER'S ART, OR LIGHT COPPERSMITHING. 
 
 The brazier's art, or the working of light sheet-copper into vessels 
 for cooking and articles for ornamental purposes, must have engaged 
 the attention of man from the earliest periods of his civilization, for 
 among the ancient art treasures in the British Museum in London 
 may be seen many very fine and interesting specimens of Oriental 
 work, illustrating vividly to a practical eye the skill and ingenuity 
 which had been exercised by the primitive craftsmen in the produc- 
 tion of armor, cooking utensils, lamps, vases and a great variety of 
 articles for personal adornment taken from the tombs of ancient Egypt, 
 Babylon and various parts of India and other places. Judging from 
 their preservation and the beautiful work displayed on them they 
 must have played an important part in illustrating the exalted posi- 
 tions held by their prehistoric owners, as well as the social standing of 
 the artist. It would seem that for thousands of years this ancient 
 handicraft has been handed down from father to son, and even to-day 
 many of the arts connected with special branches of brazing are as 
 jealously guarded and kept secret with the craft as they were at the 
 very dawn of its development. One of the most imperative injunc- 
 tions received by the writer from his father was to taithfully guard 
 his patrimony from the scrutiny of prying eyes, it having descended 
 to him through a long line of ancestors for many generations, who had 
 plied their craft with various degrees of proficiency, thus maintaining 
 their respectability and independence to an honorable old age, in evi- 
 dence of which in Canterbury, England, four years ago one of his kins- 
 folk could yet be seen working at the brazier's bench at the advanced 
 age of 87 years. But having been imbued with more liberal 
 ideas by coming in contact with and feeling my indebtedness to many 
 other men from whom we are compelled to borrow more or less, I have 
 concluded to waive the injunction received in childhood for the ben- 
 efit of those who are most interested. I will now try to describe a 
 brazier's shop in an old country town, together with the tools used 
 therein, and give such lessons in the art of braziery as I can recall to 
 memory to assist as far as practicable the learner to become profi- 
 cient. 
 
art of coppersmithing. 7 
 
 An Old-Fashioned Shop. 
 
 In the beautiful little town of Dorking-, in the county of Surrey, 
 England, could be seen an old-fashioned iron-monger's shop, with the 
 usual stock of copper goods, comprising stew-pans, saucepans, pre- 
 serving-pans, frying-pans, omelet-pans, cutlet-pans, dripping-pans, 
 warming-pans, tea-kettles, fish-kettles, turbot-kettles, coffee-pots, pud- 
 ding-pots, stock-pots, tea-boilers, tankards, spirit-measures, coal-scoops, 
 coal-hods, beer-mullers, washing-coppers, hand-bowls and a variety of 
 goods displayed • in a tasteful manner in a spacious show-room win- 
 dow. In the rear of this iron-monger's shop (hardware store) was once 
 a busy hive of some 25 or 30 men and boys engaged as blacksmiths, 
 whitesmiths, tinsmiths, gunsmiths, coppersmiths and braziers, each 
 department separate and distinct in itself. We will now visit this old 
 brazier's shop, with which we have the more special interest, look 
 about it, and endeavor to describe the interior as it was some 40 years 
 ago and as it probably is to-day, or at least as it was in 1884, hoping it 
 may benefit and interest the younger members of the craft. As shown 
 in the plan view, Fig. 1, the door is facing east, and the room is some 
 25 feet square, with an east-window light; on the north side is a brick 
 forge, Fig. 2, about 4 feet 6 inches square, the chimney of which is 
 built in the shape of a square pyramid and covers the whole hearth; 
 the fire-place or fire-hole is about 12 inches square and some 6 inches 
 deep, and set about 2 feet from the front of the hearth and the same 
 distance from the wall that carries the west side of the cone of the 
 chimney; on the west side of this wall the bellows are hung, and at 
 the back of the bellows are placed three covered pickle-tubs containing 
 severally sulphuric acid, muriatic acid and salt pickles. Along the 
 south wall and under the east window are the benches, Fig. 3, with 
 vises attached; on the east side of the forge is the scouring-sink, which 
 is some 3 feet long, and placed there so the fumes of the various acids 
 in daily use may be carried off by the draft of the chimney; there 
 should be a good supply of water at hand for rinsing purposes, 
 which is carried off by the drain-pipe running to the sewers. At the 
 back of the sink are a few shelves to hold spelter-boxes, mcrtar and 
 pestle, and a few covered jars containing sal ammoniac and borax. In 
 the chimney-wall are driven a number of square hoops upon which are 
 hung ladles, sal ammoniac wads of various sizes and the different kinds 
 and sizes of tongs. The rocking-shaft of the bellows is supplied with 
 
ART OF COPPERSMITHING. 
 
 PICKLE TUBS 
 
 ( BELLOWS^J 
 
 4 6x46 
 
 □ 
 FORGE 
 
 PATTERN 
 BOX 
 
 SAWDUST 
 BOX 
 
 COKE 
 BIN 
 
 TOOL BLOCK 
 
 TOOLS ON FLOOR 
 
 WORK 
 BENCH 
 
 WORK BENCH 
 
 Fig. i. — Ground Plan of Old Shop. 
 
ART OK COPPERSMITH ING. 
 
 
 
 •& 
 
 ^ 
 
IO 
 
 ART OF COPPERSMITHING. 
 
ART OF COPPERSMITHING. 
 
 II 
 
12 ART OF COPPERSMITHING. 
 
 a chain and stirrup so that the workman may easily work the bellows, 
 with his left foot, leaving his hands free for his work at the fire. On 
 the east side of the shop is the main work -bench, upon which is fast- 
 ened an old contrivance for turning stove and other pipe which I 
 think may claim to be the parent of the rollers now in use in the modern 
 tin-shop. This primitive contrivance is a round bar having the ends 
 turned square about 5 inches, flattened and then bolted to the bench, 
 leaving a space between it and the edge of the bench wide enough to 
 get the sheet iron or copper between, the workman forming the pipe 
 by bending the sheet over the bar with the leverage of the metal. On the 
 south end of this bench and on the south wall is a cupboard with sev- 
 eral shelves, in which is kept the bright-heads, dry spelter, borax, rosin, 
 flax and hemp tow, block and grain tin, solder and other little necessities, 
 so that they may always be in store and be kept clean and always 
 ready for use. The east bench is continued along the south wail about 
 half way and the remaining part taken up by the heavy tools, such as 
 beak-horns, shanks and side-stakes, along the wall. Over this part of 
 the bench is a file-rack and further on is along hammer-rack, the other 
 space being variously taken up by hanging patterns on hooks in the 
 wall. On the west side Fig. 4 is the coke-bin, and a large box, about 
 two-thirds full of sawdust, used to wipe off or dry work in after it has 
 been scoured clean. The next is a large box containing a full and 
 complete stock of patterns, kept together on rings in the same man- 
 ner as they are in the shops of the present day. In the middle 
 of the floor is the heavy tool-block which is about 16 inches, 
 wide by 6 or 8 inches thick and some 6 or 8 feet long, usually 
 of beech wood, and having pieces of wood nailed to it to an- 
 swer as feet to keep the block off the floor and the holes which re- 
 ceive the tools free from dirt and chips, so that no impediment be in 
 the way of tools placed therein. This stock of tools is comprised in 
 and named as follows : Large and small round bottom-stakes, tea- 
 kettle-bottom stake, tea-kettle shank with heads, sauce-pan-belly stake 
 with single and double end, bent and upright bullet-stakes, side-stakes, 
 large and small ; funnel-stake, hatchet-stake, beak-irons, crease-irons*, 
 anvil and heavy and light stock-shears. These are all of the heavy and 
 most costly tools ; the bottom stakes and the various kinds of heads 
 have bright faces and must be kept greased. The bottom-stakes have 
 lead covers to protect them from the action of the acids constantly in 
 use. The various kinds of hammers used can better be described as 
 
ART OF COPPERSMITHING. [3 
 
 we proceed and come to the work for which they are adapted and 
 used by the workman. In the most convenient corner of the bench 
 are kept with the shears several round and square manclrels, from 4 
 to 5 feet long, of suitable sizes, having their ends turned down square 
 and made to fit the holes in the bench, the same as the other tools. 
 The small tools on the shelf over the south bench consist of hollow 
 punches, chisels, fiat punches, rivet-sets, groovers, &c. The other small 
 tools are plyers, nippers, hand-shears, snips, compasses, squares and 
 straight-edges, a good assortment of rough and smooth files and two 
 burnishers. Having now described as vividly as possible the interior 
 of this old brazier's shop, together with all its appurtenances, we will 
 next follow an apprentice through his seven years of service, from his 
 first two years of drudgery on and up until he shall have gained suf- 
 ficient proficiency to take his place as a journeyman. 
 
14 ART OF COPPERSMITHING. 
 
 FIRST YEAR'S EXPERIENCE. 
 
 On Monday, February 7, 1842, in the town of Dorking, at 6 o'clock 
 in the morning, could have been seen a little boy, fairly intelligent and 
 rather larger in stature than his tender years would seem to indicate, who 
 lacked just 46 days to complete his ninth year. This little fellow was 
 trudging along by the side of his father toward an old brazier's shop 
 to take his initial step amid life's busy turmoil. Having arrived there 
 in due time and admission gained, a light was the first thing in order, 
 which was obtained from an old tinder-box with a brimstone match, the 
 light being transferred to an old-fashioned whale-oil lamp (Fig. 5), 
 which burned after being lit with a reddish-yellow flame. On looking 
 around the boy saw that about everything seemed black and forbidding, 
 cold and cheerless ; the soot of half a century previous was still clinging 
 to those dreary-looking walls. The next anxiety was to get a fire, which 
 was made from a pile of cinders at hand in the corner of the forge. 
 This fire seemed to offer a ray of hope to the little fellow, who clung 
 to the chain of the bellows and kept the cinders bright enough to be able 
 to see just where he was. After two and one-half long, weary hours 
 the bell rang and the boy trudged home to get his breakfast; and what 
 a release it seemed to get away, if but for 30 minutes, from this gloomy- 
 looking place and revel in the sunshine while walking home and back ! 
 As the hour of 9 approached he was wending his way thither again, 
 and from 9 until 1 o'clock blew the fire, ran errands and helped his 
 father, when the joyful bell rang for dinner, for which an hour was 
 allowed, returning at 2 o'clock and working until 5, then going to tea 
 for half an hour and back to work again until 7 o'clock, at which time 
 the most welcome sound of the whole day said, " Leave until 6 the 
 next morning." Never did child go to bed more cheerfully or sleep 
 more soundly than did that little hero of nine summers, and never did 
 the time seem to fly more swiftly as the gentle word summoned him to 
 his duties each succeeding morning. 
 
 The first week was at length finished, and on Saturday we left off 
 work an hour earlier ; but the last employed were the last paid, and 
 
ART OF COPPERSMITHING. 
 
 15 
 
 thus the boy was the last to be paid, which was done with as much 
 ceremony as if he were the most important man. After paying him 
 his 3 shillings wages the good man seemed moved by pity, for he spoke 
 the only kind word that had seemed to greet the boy's ear (excepting 
 from his father) during the week, and so the first week of the infant's 
 toil closed. Peter L. Saubergue a 1 ways proved a good and kind 
 master, and our boy learned to love him as time went on. Here let 
 us pause a moment to consider if it ought to have been then or is now 
 necessary for the welfare of the race that little children of such ten- 
 der years should be made captive and brought to labor while thou- 
 sands of able-bodied men are idle around them waiting for work. 
 
 At the end of six months this boy had got to be quite handy and 
 was kept busily engaged breaking coke, sal ammoniac and borax, 
 charging joints and drying them ready for the fire, thinning edges 
 and other little jobs. Then as each batch of cooking utensils was 
 brought to be repaired and retinned he was taught to burn off the 
 
 Fi?- 5-— Old-Fashioned Whale Oil Lamp. 
 
1 6 ART OF COPPERSMITHING. 
 
 grease, apply the acids and scour them ready for the process of re- 
 tinning. Then, again, all the hammers were required to be kept clean 
 and bright, also all other polished tools, all of them being carefully 
 greased with raw goose-grease, which duty had to be performed every 
 day before leaving work, because if a hammer should get cloudy it 
 entailed much labor repolishing on the buff -board to restore it suit- 
 able for use. The boy labored along at this seeming drudgery, which 
 many boys are apt to shun and exert every effort to evade, to their 
 own detriment, for wrapped up in this so-called drudgery are some of 
 the most important features of every trade. 
 
ART OF COPPERSMITH] NG. I 7 
 
 REPAIRING AND TINNING. 
 
 At the close of each year, before the Christmas holidays commence 
 md the prominent families leave city resorts for country homes, all 
 the kitchen furniture has to be overhauled, tinned and repaired, and 
 all of these goods are sent to the brazier's shop for this purpose. We 
 will now take a batch and proceed to repair them and then go on and 
 describe the process of retinning as it would be done, giving the boy 
 his share in the job. There would be stew-pans, saucepans, frying- 
 pans, fish-kettles, stock-pots, ladles, spoons, gravy-strainers, fish-slices 
 and a host of other things required for a complete Kitchen ouifit. 
 Fig. 6 shows a copper saucepan with curved sides. The first thing 
 necessary is to burn off the grease which accumulates under the flap 
 of the handle and around the wire of saucepans and other vessels, and 
 this is to be done carefully, so that the articles are not softened. 
 They are made hot enough so the gases evolved by the heat will just 
 ignite and no more, each piece going through the fire in succes- 
 sion, when they are brushed off and examined. If any of the handles 
 are loose the old rivets are taken out and new ones put in, the rivet- 
 holes being cleaned and tinned and the handle then replaced with 
 new tinned copper rivets. It often happens that a hole is worn 
 through the lag of a saucepan or stew-pan by the constant rubbing 
 on the kitchen hot-plate or scullery-sink. The damage done by this 
 wear is repaired in three ways, according to the time available, the 
 ability or inclination of the workman, or the affluence and dignity of 
 the owner. 
 
 At one time it was the fashion to finish all utensils up with a sharp 
 lag (Fig. 7), and often careless workmen have half cut the lag through 
 before completing them when new. When they are in need of repair- 
 ing and it must be done in as short a time as possible, and the slit is 
 not too long, say over 2 inches in length, then at the extremities of 
 the slit punch two small holes and slightly open it; now take a thin 
 piece of sheet copper of sufficient length and double it, as in Fig. 8, 
 then slip the two leaves through the slit, as in Fig. 9 or 11, and lay 
 the leaves back each way, as in Fig. 10; then close the whole up close 
 
ART OF COPPERSMITHING. 
 
 Fig. 6. — Bellied Saucepan. 
 
 Fig- 7. — Stewpan. 
 
 Fig. 8. — Showing Piece Doubled. Fig. 9. — The Way Piece is Put In. 
 
 Fig. 10. — Piece Put Through Outside. Fig. 11. — The Piece Put Through Inside. 
 
ART OF COPPERSMITHING. 
 
 l 9 
 
 Showing Shell Piece. 
 
 Fig. 13. — Showing Piece Cramped and 
 Brazed In. 
 
 Pig. 12. — Showing Piece and Hotv 
 Put In. 
 
 Pig. 15. — Manner of Measuring to 
 Determine Price. 
 
 Fig. 14. — Sal Ammoniac Wad for 
 Tinning. 
 
20 ART OF COPPERSMITHING. 
 
 with a mallet, letting the double part, if inside, go one-half up the 
 side and the other half out into the bottom, as in Fig. 10; it may now 
 be soldered with spelter or soft solder. The article can be repaired by 
 making a shell piece and riveting it to its place, as m Fig. 12; this 
 kind of piece may be of any length, but the best job is to cut the 
 damaged part out and cramp and braze a new piece, as in Fig. 13, 
 which may be done by an expert hand in as short a time as the other 
 two methods, excepting, however, the cleaning off and replanishing. 
 New bottoms may be cramped and brazed in or double-seamed, as 
 may be considered expedient. 
 
 When all the repairing is complete and the bruises taken out and 
 the bottoms of the stew-pans and saucepans and the like are laid flat 
 or made level the preparation for retinning properly begins. We com- 
 mence with the application of a coat of pure commercial muriatic acid 
 to eat off or remove the dirt and the portions of the old or previous 
 tinning. When the vessels have stood a sufficient time they are thor- 
 oughly scoured inside with good sharp sand, with the addition of 
 some common salt, and then washed clean, care being taken that all 
 of the old tin is off when burnt and that nothing greasy gets inside. 
 Then while the vessel is yet damp a coat of finely-powdered sal am- 
 moniac is sprinkled over the inside and a coat of wet salt carefully put 
 on the outside to guard against the effects of the different gases from 
 the fire. 
 
 Now take a quantity of block or ingot tin and slowly melt it in a 
 ladle, being careful not to allow any part of it to become too hot or 
 get burnt. When the tin is melted and ready, then warm and dry 
 the vessel to be tinned and pour a sufficient quantity of tin into it. 
 Next take a sal ammoniac wad, Fig. 14, and with it rub and agitate the 
 liquid tin over the entire inside surface of the vessel until every part 
 is well covered, and then pour out the bulk of the liquid tin. After 
 heating the vessel to a uniform heat all over, take a wisp of clean, soft 
 flax-tow, the hand first being protected by means of a glove which has 
 had the tips of the fingers cut off as far as the first joint, and whisk it 
 in a pan of powdered sal ammoniac ; then with a light hand and a few 
 quick motions, first around the left side and then the right, and then 
 across the bottom, wipe out the residue of the tin, leaving only a clear 
 bright coat on the surface of the vessel. Only by constant practice 
 can this operation be accomplished or excellent results secured. Be- 
 ing a few months out of practice will seriously affect a man's efficiency 
 
ART OF COPPERSMITHING. 2I 
 
 in the sense of touch and cause him many unpleasant and annoying 
 failures. While the tinning process is going on the boy is busily scour- 
 ing and preparing other vessels and keeping his weather-eye open to 
 what is going on. The tinning process being over, the next in order 
 is to scour each article with clean white sand on the outside to re- 
 move the salt and inside any sal ammoniac that might be left. This 
 scouring must be carefully done, and it is best to have a separate place 
 for each operation, so that when the outside is cleaned off the inside 
 can be scoured without tear of contamination from the salt ; because 
 if the outside scouring wisp should by mistake get on the inside the 
 work would be spoiled and can scarcely ever be restored again, so it 
 is best to keep the wisps far enough apart to insure them from being 
 taken up and used by mistake. After the sal ammoniac has been 
 scoured off and the surface outside and inside is clean and bright, the 
 articles are rinsed in fresh, clean water and dried in clean pine sawdust 
 kept in a large box and then sfood around a large forge-fire to be 
 dried more thoroughly. Next brush off the sawdust and with a clean, 
 soft linen or cotton rag and clean whiting polish the inside ; then with 
 another rag and a little crocus polish the outside and the job is com- 
 plete. 
 
 Tinning has always been paid for extra in all country shops at the 
 rate of a shilling a day in excess of the ordinary pay on account of 
 the disagreeable nature of the work. The manner of measuring and 
 paying for the work is by the inch, as shown in Fig. 15. The rule is 
 laid obliquely from lag to brim, so that the longest measure may be 
 obtained, and the price varies from 1 to 2 pence an inch according to 
 the nature of the work. 
 
22 ART OF COPPERSMITHING, 
 
 THE BOY'S SECOND YEAR. 
 
 The first year of drudgery glides slowly away, and as the end of 
 the second year approaches the long, weary, damp and chilly nights 
 of October and November come with it ; the heating-stoves of those 
 who are compelled to use them are called into service, and with them 
 comes a demand for stove-pipe, both iron and copper. Now, at the 
 time of which we are writing there were no squaring-shears with 
 which to cut the sheets into suitable pieces, so all the work had to be 
 cut out with hand-shears or the stock-shears. Then there was no 
 folder with which to fold the edges for grooving ; the locks were all 
 folded over a hatchet stake and closed down on a straight edge. The 
 men usually cut out the pipe, and if it was not too large the bov was 
 put to work folding edges and then closing them down over a 
 straight-edge on a square mandrel laid across the bench (Fig. 16). 
 If copper stove-pipe is to be made it is usually browned and plan- 
 ished. Here, then, is one of the boy's first lessons in the manipulation 
 of a planishing-hammer. While he is engaged at this many a " half- 
 moon " intrudes itself on the surface of his work to enlighten him 
 that he must be careful and attend to his task. 
 
 Copper Stove-Pipe. 
 
 Let us now describe the making of two joints of copper stove-pipe. 
 We will suppose the pieces are cut the proper width and of sufficient 
 taper that the small end of one joint will when formed fit snugly into 
 the large end of the other. The pieces are first clipped at the end as 
 in Fig. 17, about 2 inches from the end and as far in on each side as 
 the locks will take up ; then, with a tow wisp, some dry Spanish 
 brown is rubbed all over one surface of each piece, and the sheets are 
 fastened together with four dogs, as shown in Fig. 18, or secured in 
 whatever way seems best. The browned surfaces being outside the 
 sheets are then taken to the large bottom-stake (Fig. 19), and with a 
 suitable hammer, called a bottom-hammer, which has one face a little 
 fuller in the center than the other, the pieces are planished — that is, 
 the grain of the copper is closed. There is only one way to do this 
 part of the work successfully and in a perfect manner, and there is a 
 
ART OF COPPEUSMITIIING. 
 
 23 
 
 Fig. 16. — Folding Edges on Bench. 
 
 ■Ill 1 ! 
 
 lip !!§f'''/j!i 
 
 I f ,11 
 
 A 
 
 
 
 ,-m 
 
 
 m 
 
 , 1 
 
 F'g- '7- — Pattern Clipped Ready for Fig. 18. — Two Pieces Dogged Together, 
 
 Folding. 
 
24 
 
 ART OF COPPERSMITHING. 
 
 Fig. 19. — Planishing at the Block. 
 
 Fig. 20.— Showing the Blows Arranged. 
 
ART OF COPPERSMITH1NG. 
 
 25 
 
 Fig 24. — Bench Hook for Holding Mandrel. 
 
 Fig. 21. — Folded for Turning. 
 
 Fig- 25. — Mandrel in Position. 
 
 Fig. 26. — Loose Bar and Pipe. 
 
 Fig. 22. — Old Fashioned Bending Bar. 
 
 Fig. 2 3- — Fipe Finished and Riveted at End. 
 
26 ART OF COPPERSMITHING. 
 
 Tittle knack in it which boys are a good while learning, particularly 
 if they are, unfortunately, counted as unwelcome intruders in the 
 shop. The secret of success is to keep the blows regular.' The best re- 
 sults are obtained by striking each succeeding blow m as near a 
 direct line with the previous one as possible, and then filling in be- 
 tween as each line is completed, as in Fig. 20. When the surface has 
 been planished all over the sheets are taken ar art and made to lay 
 level ; this done they are ready for folding and forming.' They are 
 then taken to the hatchet stake and folded, the edges being closed 
 down, as in Fig. 21, and next they are taken to the bending-bar (Fig. 
 22) and bent round by placing one edge between the bar and the 
 bench, and bending a little at a time until the locks will meet each 
 other, and after grooving, rounded up and smoothed with a mallet, 
 making finished pipe as in Fig. 23. 
 
 ^ That old bar (used in the shop we are writing of), judging from 
 the wear of the bench and itself, must have served as a former for 
 many a boy before, and perhaps is used yet, for it was still clinging 
 to its place in 1884. An improvement was introduced by my father in 
 bending-bars by making two hooks of i^-inch rod (Fig. 24) and plac- 
 ing them in the bench, so a mandrel or bar could lay in them close 
 to the bench (Fig. 25) and permit of one end being raised so that the 
 pipe could be slipped off readily (Fig. 26). One day there was some 
 pipe of different sizes to make, and after finishing the smallest, 
 while at work forming up the larger sizes one of the smaller pipes 
 was placed on the bar and the larger pipes formed over it. During 
 this simple operation it was noticed that the pipe was formed without 
 any ribs appearing, as had been the case when the naked bar was used. 
 By this method the pipe can be made smooth and much work saved in 
 rounding up. This method has been used to advantage when no roll- 
 ers were at hand, and as good work can be turned out by this means 
 as by the use of the rollers, though of course not so rapidly. 
 
 Making Washing-Coppers. 
 
 The next lesson in the use of the hammer would be " spotting " 
 coppers, or, more properly, making coppers complete. In the South of 
 England scarcely a house could be found without a washing-copper m 
 or near it; hence there was always plenty of this kind of work for a 
 boy in any brazier's shop. "The capacity of these coppers runs from 
 8 to 25 gallons or more, according to the size of the house, and they 
 
ART OF COPPERSMITHING. 27 
 
 are much more economical as regards fuel and would seem much 
 better adapted for washing purposes than a wash-boiler on a cook 
 stove. Some of these boilers are made to serve for both washing and 
 brewing. A copper to be used for brewing is made a little different 
 from a washing-copper, although the greater part of their construc- 
 tion is the same. Let us proceed with a washing-copper to hold about 
 20 gallons and a brewing-copper of a little larger capacity. Now, in 
 nearly all cases the sides are all cut out and furnished ready to be put 
 together, and the bottoms also, which are already raised up at the 
 edge some 3 or 4 inches, and therefore few boys or men trouble 
 themselves as to the dimensions they ought to be, their only care 
 being to put them together into shape as quickly as possible, which 
 they proceed to do in the following manner : The sides are first 
 examined and made true, if necessary. As shown in Fig. 27, one 
 piece is laid half-way on the other and a line drawn along the edge of 
 the top piece ; it is then turned over and the end of the same edge 
 placed at the end of the line drawn on the other piece. If the edge 
 coincide with the line drawn and the curved edges also coincide, it 
 will be considered true. If the end edges do not coincide, divide the 
 difference at one end and pare it until the edge and line coincide with 
 each other. Next, the holes are punched along the side and bottom 
 edge, as shown in Fig. 28, in such a way that the distance between the 
 center of the holes will be equal to the diameters of the head and 
 shank of rivet added together. Thus if the head be 1 inch and the shank 
 % inch, then the distance between the centers of the holes will be 1^ 
 inches. The rivets in the bottom must be at least one size larger, some- 
 times two sizes, according to the strength of the bottom, which is 
 always much stronger than the sides. 
 
 Now form the sides and put three rivets in each seam', as in Fig. 
 29, and knock them down half-way temporarily, and put a small 
 tack in the middle of the part which will form the brim at top ; then 
 with a racer (Fig. 30) or a pair of compasses mark off the width of the 
 brim as in Fig. 29. Now take the copper and put it on a suitable head, 
 which is placed in the square shank (Fig. 31) and run a course around 
 with a hammer on the bottom side of the line that marks the width 
 of the brim, to harden the metal, after which proceed to lay off the 
 brim with a mallet, being careful to get it down true. Next smooth 
 it down on an anvil, with a full-faced hammer, this being done 
 carefully so as to preserve the roundness. The sides are now stiff 
 
28 
 
 ART OF COPPERSMITHING. 
 
 Fig, 27 .—Making Sides True. 
 
 Fig. 28.— Sides Prepared and Punched. 
 
 Fig. 29. — Sides Formed. 
 
 Fig. 30. — A Racer. 
 
 Fig. 31. — Riveting and Planishing. 
 
ART OF COPPERSMITHING. 
 
 29 
 
 Fig. 32. — Planishing Hammer. 
 
 V ! 
 
 Fig. 35. — Scrubbing Hammer. 
 
 81 
 
 .::V ! 'iiiii 
 
 /TjV. 33. — Spoiling Copper. 
 
 Fig. 36. — Jf<y /<? Scrub Rivets. 
 
 Fig. 34. — Bottom Punched. 
 
3° ART OF COPPERSMITHING. 
 
 enough to handle, and we proceed to draw m the bottom ends to fit 
 the bottom, as in Fig. 29, making them small enough to go into the 
 raise of the bottom, and the bottom to lap up the side about % 
 inch more than the diameter of the rivet-head. When these 
 are fitted, shape up the sides true and smooth them with a 
 mallet on the head in the square shank (Fig. 31). Now take a wispful 
 of Spanish brown and rub it all over the outside surface, and with 
 another wisp rub a little dry black-lead over the inside. We are now 
 ready to commence the spotting, which is done as follows : Take the 
 bottom of the slides in the left hand, and with a double-faced planish- 
 ing-hammer (Fig. 32) begin by striking several blows in succession 
 around each other until the spot formed is from ^ to 1 inch in 
 diameter ; then repeat, making each spot regular and in line and 
 about % inch apart, or so that the spots are clearly defined, 
 and cover the whole surface as shown in Fig. 33. As this pro- 
 ceeds and each course comes to a rivet, scrub it enough to set the 
 sides down to the head to draw up the head of the rivet, or the whole 
 joint may be partly scrubbed before spotting begins. When the 
 spotting is complete finish the scrubbing and draw up the rivets with 
 the set. Clean the end of the rivet-shank with a file and knock down 
 the rivet, finishing it in a pyramid form, as near octagon as possible. 
 Now take the bottom (Fig. 34) to the head in an upright 
 shank as shown at the right in Fig. 31, and with the bottom 
 in both hands, hit it on the head enough to make the outside 
 convex ; then smooth it, brown it and planish it all over. This could 
 be done on the head (shown at the left in Fig. 31) if more convenient, 
 and only one is engaged on the work. Put the sides into the raise 
 of the bottom and mark four holes (being careful that the sides set 
 true before marking the holes) opposite each other and punch them 
 in the bottom ; then place the sides into the bottom again, and put in 
 four rivets and knock them halt-down temporarily, and punch the rest 
 of the holes through the bottom from the inside. Next put' in all the 
 rivets, knocking them half-down in the same way, and when they are 
 all in take a suitable cross-piened hammer (Fig. 35) and begin to scrub 
 up the bottom rivets, after which draw them up with the set and head 
 them up eight square to the form of a pyramid. If the scrubbing is 
 properly done there will be no need of any cement being used to se- 
 cure the joint against leaking ; all that is required is good workman- 
 ship. What is called scrubbing is to hammer the part all around the 
 
ART OF COPI'ERSMITHING. 3 1 
 
 rivet down close to the head, making the surface on the inside per- 
 fectly smooth, the rivet-head being, as it were, in a countersink when 
 the scrubbing is completed. To do this we first use the pane of the 
 hammer between the rivets ; then on each side ; then across the four 
 corners made by the previous blows, as shown in Fig. 36. 
 
 Making Brewing-Coppers. 
 
 We will now finish the brewing-copper (Fig. 37), the sides of which 
 have been made the same as those described for a washing-copper. We 
 next take the bottom (Fig. 34) in both hands and hit it on a head in 
 an upright shank (Fig. 31) enough to make it concave on the outside, 
 as shown in Fig. 37. Then brown and planish it from the inside, 
 after making the crown nearly level with the raise of the bottom. This 
 is done so that all liquor will run out clean through the pipe. The 
 rivets are now put in the bottom the same way as described for the 
 washing copper, except that enough rivet holes are left where the pipe 
 is to go. A pipe is seldom put in a brewing-copper by a boy until he 
 has been at the trade for a considerable time; but we will work it in, 
 and, in doing so, let us suppose the pipe is 3 inches in diameter at the 
 large end and 1% inches at the small, so as to fit the socket of the 
 cock. The pattern (Fig. 38) should be extra heavy copper, thick 
 enough to allow a flange to be worked on it from 2 to 3 inches wide, 
 which is commenced while the pattern is flat, using in the operation a 
 cross-piened hammer, and, as the flange is being laid off, the pattern or 
 pipe is made to curl with each blow as the work is being done (Fig. 
 40). The bottom of the pipe flange (Fig, 39), or that part which 
 spreads over the bottom, requires a little more work than the part of 
 the flange intended to go up the side, to make it fit to its place and 
 secure a good job. When the flange is laid off enough and the seam of 
 the pipe is soldered down, the hole for the pipe is cut in the side of the 
 copper, "close to the bottom, where the rivets have been left out for that 
 purpose, and in the middle of one of the sides or sections of the body, 
 the hole being cut small enough so that about a quarter inch can be 
 turned out to let the pipe and its flange go up to its place easily and 
 form a narrow collar around the pipe, the seam of the pipe being on 
 the bottom, as shown in Fig. 39. Now turn the copper on its side as in 
 Fig. 42 and with a suitable piece of rope, passed down through the 
 pipe, sling the head A, and pass a strong wooden bar through the 
 loop B, so that it will hang in the right position, and a boy can hold it 
 
32 
 
 ART OF COPPERSMITHING. 
 
 Fig. 37. — Brewing Copper, Showing Bottom. 
 
 Fig. 38. — Pipe Pattern. 
 
 Fig- 39-— The Way to Fit Pipe, Cock 
 and Boss. 
 
 Fig. 40. — Pipe Pattern Half Worked. 
 
 Pig. 41. — Showing Boss Ready. 
 
ART OF COPPERSMITHING. 
 
 33 
 
 steady while the rivets are worked in which hold the flange to the bot- 
 tom. When the rivets are all in scrub them and the edge of the flange 
 until both are smooth with the surface of the side and bottom, and 
 close down the narrow collar tight around the pipe (Fig. 37). 
 
 The cock is then made to fit tight on the pipe (Fig. 39), and a case 
 of light copper (Fig. 41) made to fit tight around the large end of the 
 pipe and outside of the socket of the cock, with a collar, as shown. 
 When it is fitted, a hole is cut in the case and a lip turned back, as 
 in Fig 41. The case is now put on the pipe and the end of the pipe 
 driven tight into the socket of the cock, and then the pipe rammed full 
 of damp sand from the inside of the copper and some clay rubbed in 
 around the collar of the case and a little rosin in the case. When all is 
 ready the case is filled with old, rough solder, burnt tin or any other 
 suitable metal which cannot be used with advantage for anything else. 
 When cool enough, the lip is closed down and a nail driven in to keep 
 it close while it is being soldered 
 
 Fig. 42.— Riveting Bottom of frlange. 
 
34 
 
 ART OF COPPERSMITHING. 
 
 The table below gives the dimensions of coppers, with their capac- 
 ity and approximate weight up to ioo gallons. Small country shops 
 seldom make anything larger, not having room or the conveniences 
 for building them. The work was paid for by the pound — that is, the 
 weight when finished— at a rate of from 3 to 5 cents per pound. 
 
 Inside 
 
 'Diameter of 
 
 Depth 
 of sides in 
 
 Diagonal 
 
 Contents 
 
 Approximate 
 
 diameter at 
 
 bottom 
 
 length from 
 
 in 
 
 weight, 
 
 top, in 
 inches. 
 
 at lag, 
 in inches. 
 
 inches. 
 
 lag to brim, 
 in inches. 
 
 gallons. 
 
 in 
 pounds. 
 
 13i 
 
 11* 
 
 11 
 
 16 
 
 6 
 
 8 
 
 15 J 
 
 13| 
 
 12 
 
 19! 
 
 8 
 
 10| 
 
 17 
 
 14* 
 
 13 
 
 21 
 
 10 
 
 13i 
 
 18J 
 
 15| 
 
 13* 
 
 22! 
 
 12 
 
 16 
 
 20 
 
 17 
 
 15 
 
 24! 
 
 16 
 
 21* 
 
 22 
 
 18* 
 
 16J ' 
 
 27 
 
 21* 
 
 28i 
 
 23£ 
 
 20 
 
 17! 
 
 28| 
 
 25! 
 
 34 
 
 25 
 
 21* 
 
 18! 
 
 30! 
 
 31 
 
 41! 
 
 26 
 
 22* 
 
 19 
 
 31! 
 
 35 
 
 46! 
 
 27 
 
 23 
 
 20 
 
 33 
 
 41! 
 
 55i 
 
 28 
 
 24 
 
 20! 
 
 34 
 
 44f 
 
 59! 
 
 29 
 
 25* 
 
 22 
 
 36 
 
 49! 
 
 66 
 
 30£ 
 
 27 
 
 22f 
 
 37! 
 
 55f 
 
 74 
 
 31! 
 
 27* 
 
 23! 
 
 38! 
 
 60 
 
 80 
 
 m 
 
 28£ 
 
 23£ 
 
 39! 
 
 66 
 
 88 
 
 34 
 
 29! 
 
 24! 
 
 42 
 
 75 
 
 107 
 
 34* 
 
 30! 
 
 25 
 
 43 
 
 83 
 
 121* 
 
 35 
 
 31 
 
 26 
 
 43! 
 
 87 
 
 128 
 
 37 
 
 32i 
 
 27 
 
 44! 
 
 93 
 
 137 
 
 38 
 
 33! 
 
 28 
 
 46 
 
 106 . 
 
 159 
 
 Table Showing Dimensions, Capacity and Weight of Coppers. 
 
ART OF COPPERSMITHING. 35. 
 
 MAKING HAND-BOWLS. 
 
 It a boy has made himself useful during his first two years he has 
 gained much valuable information for future application. He has 
 been kept busy, and thus secured efficient training for the eye and 
 hand by having many little jobs given him to try his skill upon, by 
 which he has assisted his tutor and partly repaid him for the care 
 and attention received while watching over him and directing his 
 initial work. If, on the other hand, he has been negligent and afraid 
 he would do too much, his progress is likely to have been a little slow, 
 for few men care to help a boy who shows a desire to shirk his duty. 
 After the writer was made to understand why he had been placed in 
 that old shop, he was usually the first to arrive and the last out, and 
 became much attached to the trade; particularly after having seen the 
 first half-dozen bright copper tea-kettles finished and cleaned ready 
 for the show-room, he looked forward to the time when he could imi- 
 tate them. 
 
 When the tinning season is past and no more stove-pipe is likely 
 to be wanted, and jobbing work is slack, the stock is reviewed, and 
 usually about the first things that are wanted are hand-bowls, which 
 supply the work for advancing the boy a step further. Copper hand- 
 bowls furnish an excellent initial lesson, because while the work to 
 be executed in making them may not necessarily call for the finest 
 finish, yet a boy who is interested in his work may display his best skill 
 here and make preparation for the better work which is to follow. 
 Then again, if the bowls are to be tinned inside an opportunity is 
 offered to try his hand at the tinning process, seeing that this also 
 does not have to be done as carefully as in the case of cooking utensils. 
 Copper hand-bowls were made in three sizes, and called small, middle 
 and large. The small size when finished was 8 inches in diameter, 
 the middle size 8% inches and the large 9 inches. The bodies were 
 cut the following dimensions : 
 
 Length. Width. Diameter of bottom 
 
 Small 24 2>% 5/4 
 
 Middle 26 3^ 6 
 
 Large 28 4 6 14 
 
36 
 
 ART OF COPPERSMITHING. 
 
 Mill *j 
 
 || 
 
 , : 1 1 i 1 >fc£22ZM%%^&! 
 
 ^^'• ni M\Wf_ ,&' 
 
 ^"'HiliiHfH 
 
 II 
 
 s 
 
 
 | fc 
 
 
 Z^. 44. — A'z'z/ 
 
 £& 
 
 ng Hammer. 
 
 Fig. 45. — Side Stake. 
 
 Fig. 46. — Sides of Hand Bowl. 
 
 Fig. 47. — Sides Brazed Together. 
 
 Fig. 48.— Sides Wrinkled for First Course. Fig. 49.— Razing Hammer. 
 
ART OF COPPERSMITHING. 37 
 
 The strength of the material may be governed by the price at 
 which it is desired to sell the finished articles, but the usual weight 
 was 8, 9 and 10 pound plate for the sides of each size respectively 
 and 10, n and 12 pound for the bottoms. This difference would seem 
 due to a desire to make the bottom stronger, but is really on account 
 of the thickness of the body, which is increased in the thickness 
 while razing it in to suit the size of bottom. 
 
 We will now proceed with the work and finish up a 9-inch bowl. 
 The side is cut, according to the above table, 28 inches long and 4 
 inches wide. Smooth the burrs off with a file and then thin the end 
 edges with a hammer (Fig. 44) on a side-stake (Fig 45) in the floor- 
 block. After thinning clean the edges if necessary with sand-paper ; 
 now cramp it with the snips at one end as far as the scarf made with 
 the hammer, which should be about 3-16 inch (Fig. 46). Form it round 
 as in Fig. 47, then close the cramps down and jar a little borax and 
 water through the joint and charge it with fine spelter, following the 
 zigzag line of the cramps. (It is well to wash and mix the solder 
 with borax and water a few days before.) Next dry it slowly over 
 the fire, after which, holding it with a suitable pair of tongs, make it 
 hot enough at the back to annul any spring and to assist to heat the 
 copper ; then turn the seam to the fire, and with a brisk blast from 
 the bellows run the solder down the joint. When cool, see that the 
 seam is full and perfect. Now file up and trim the joint on the out- 
 side and inside, taking off any sharp corners or knobs of spelter. 
 When smooth take it to a side-stake (Fig. 45) and knock down the 
 seam, making it the same thickness as the other part of the sheet, 
 and then anneal. Now take a racer and mark around the middle of 
 the body, and wrinkle it at one end as far as the middle (Fig. 48). 
 Then take it to the block, and on a long head in a tea-kettle shank or 
 on the point of the side-stake raze in a course with a mallet or light 
 razing hammer (Fig. 49) until the diameter of the body at the end is 
 reduced to within about five-eighths of the size of the bottom. Next 
 " stag" it in, as shown in Fig. 50, a shade smaller than the bottom. 
 Thin the edge of the part turned on a suitable bullet-stake (Fig. 51), 
 also the edge of the bottom and cramp it, as in Fig. 50, then lift each 
 alternate cramp and put the bottom in from the inside. Close down 
 the cramps on a bottom-stake with a hammer, and popple the bottom 
 (which is done by a few blows of a hammer on a bottom-stake in the 
 center to draw it a little), and then spring the bottom in and out to 
 
38 
 
 ART OF COPPERSMITHING. 
 
 Fig. 50. — Body and Bottom Prepared to 
 Put In. 
 
 Fig. 51. — Bullet Stake. 
 
 Fi%. 52. — Bowl Ready for Wiring;. 
 
 Fig. 54. — Way to Put the Flaps On. 
 
 Fig. 53. — Pattern for Handle. 
 
ART OF COPPERSMITH I NG 
 
 C .... Of Flap and Socket Ready to Go 
 Together. 
 
 Socket and Flap Fitted. 
 
 Fig. 55.— Making the Handle. 
 
 Mg. 56.— Buck-Bill Tongs. 
 
 Fig. 57. — Tongs Holding Socket. 
 
 Fig. 58. — The Bowl Finished 
 Complete. 
 
4° ART OF COPPERSMITHING. 
 
 loosen the -joint enough to receive the spelter freely into the seam 
 when being run at the fire. Jar some borax and water through the 
 joint and charge it with spelter, following the cramps in their zigzag 
 path around the bottom, then take it to the fire and dry slowly. Heat 
 the sides until the borax is all down, run the joint around, and when 
 cool clean off the joint outside and knock it down on a bullet-stake 
 and anneal. Next take it to a small bottom-stake and flatten the 
 bottom with a mallet, and with a pair of compasses mark the size the 
 bottom is to be when the bowl is in its finished shape, which will be 
 $y 2 inches. Break the bottom up the side from the outside of the 
 circle made by the compasses, which Will increase the depth a good 
 y 2 inch. After the bowl is shaped, turn the edge on the back of the 
 side stake for a No. 8 wire, as shown in Fig. 52. If the inside is to be 
 tinned it is now ready, and the work may be done in the manner 
 already described. 
 
 We will now make the handle, which is a socket-handle, about 1^ 
 inches inside at the wire and 1 inch in diameter at the flap and 5^ 
 inches long. The pattern of the socket would be 4^ inches at one 
 end and 3^ inches at the other. When cutting the pattern leave a 
 little V-piece in the middle of the flap-end and a point at the seam, as 
 shown in Fig. 53, to hold the flap on while it is being brazed. The 
 pattern being cut, thin the edges and turn it, then charge it and braze 
 it down, clean off the joint and knock it down on a beak-iron. Next 
 cut out the flap (Fig. 54, A B) and make the hole for the socket small 
 enough so that a collar may be worked out as shown in Fig. 55, to go 
 a little way up the socket. When the collar is fitted, put the socket 
 through the hole and turn back the V-pi ece an d also the little points 
 left on at the seam, which should hold the flap firmly in place. Charge 
 it with spelter and dry, and holding it with a pair of duck-bill tongs 
 (Fig. 56), warm first gently and then heat it until the borax is down, 
 or run, then turn the flap down to the fire as in Fig. 57 and run the 
 solder around the edge of the socket and flap, and when the joint 
 is cleaned off wire the end of socket. 
 
 If the bowl (Fig. 58) has been tinned and scoured clean, it may 
 now be planished so that it is bright or brown. To planish articles 
 of this kind with ease and comfort it is necessary to sit at the foot- 
 block, and in such a position that the operator's thigh may lie in a 
 horizontal line with the knee, and the shank and head at such a hight 
 that the fore-arm and hand may lie, when at rest, level with the ham- 
 
ART OF COPPERSMITHING. 41 
 
 mer-handle when the face of the hammer is at rest on the face of the 
 head, or as near to this as it is practicable to get, the knee acting as 
 a gauge, rest and guide during the operation. We may now proceed 
 with the planishing. If the article is to be brown it is rubbed on the 
 outside with some Spanish brown, care being taken that none gets on 
 the inside. Wipe the inside with a clean rag; next flatten the bottom, 
 smoothing it first with a mallet, and make a faint mark with the com- 
 pass showing the size of bottom. On a clean, bright bottom-stake 
 planish the bottom with a small bottom-hammer, after which, on a 
 clean, bright head, commence at the bottom and take each course 
 around the body until the wiring edge is reached, then with a con- 
 cave smoothing-hammer smooth as much as is needed. Now put in 
 the wire, and after planishing the flap of the handle and chamfering 
 the edge of it with a hammer, rivet on the handle and finish the article 
 by cleaning. 
 
42 ART OF COPPERSMITHING. 
 
 FRYING-PANS. 
 
 Frying-pans, closet-pans and water-balls afford means for the next 
 step and initiate the boy into the art of raising. It may be necessary 
 to explain here for the benefit of the beginner the difference between 
 the terms raising, hollowing and razing, which are often con- 
 founded one with another. Thus we say a closet-pan is raised up. 
 When we made the body of the hand-bowl smaller we razed the body 
 in or down to the required size. Hollowing is performed with a ham- 
 mer (Fig. 59) similar to a bullet-hammer, the difference being that the 
 hollowing-hammer face is half an oblate spheroid, while the face of a 
 bullet-hammer is half a sphere. A hammer used for raising up or 
 razing down has a rectangular face and is nearly flat, as already illus- 
 trated in Fig. 49. Hollowing is done by sinking the pattern into a 
 hollow in a hollowing-block, and the work that can be done in this 
 way is quite limited, while with a raising-hammer any desired hight 
 or depth may be obtained. 
 
 Frying-pans have their sides raised up from a fiat disk and are 
 usually made from 9 to i<$ inches in diameter at the rim and from 2 
 to 3 inches deep when finished. They are sometimes made larger, but 
 not often. We will now describe the making of a pan 12 inches in 
 diameter at the brim and to receive a T \-inch wire. Frying-pans 
 are made flaring in the ratio of about 2 to 1 — that is, if the side 
 be 2 inches deep, then the ■ flare on the side will be 1 inch, 
 or in other words, if such a pan be 12 inches at the 
 top the bottom will be 10 inches. Let our example be 12 
 inches at top ami 10 at bottom, the slant hight 2 inches and the wire T 5 g. 
 Now, to make this we require a disk of metal equal to the surface of the 
 pan, the strength of which may range from 14 to 18 pound plate. The 
 disk then would be equal to the bottom + sides 4- half the covering of 
 wire, which, allowing 1 inch for the circumference of the wire, would 
 make the sides before turning the edge for wire 2^ inches deep, and 
 the top diameter 12}^ inches. Then 
 
 |/ 103 4- ( 10+ 18 - 5 x 3.1416 x 2.5 h- .7854) = i/l00 4- 112.5 = 14.57 
 
 equals diameter of disk ; adding the thickness of the metal 
 
ART OF COPPERSMITH I NG. 
 
 43 
 
 Fig. 59. — Hollowing Hammer. 
 
 tig. 60. — Pattern of Frying Pan. 
 
 Fig. 61. — Disk Wrinkled. 
 
 Fig. 62. — Razing Pattern on Tea-Kettle Shank. 
 
44 
 
 ART OF COPPERSMITHING. 
 
 Fig. 63. — How Wrinkles are Razed Down. 
 
 Fig. 64. — Handle Riveted on Frying-Pan. 
 
 Fig. 65. — Ancient Frying- Pari. 
 
ART OF COPPERSMITHING. 45 
 
 to this we have about 14.6 the size of the disk required 
 for our pan. Now describe with the compasses the size of 
 the bottom on the pattern (Fig. 60), and wrinkle the edge regularly- 
 all around as shown in Fig. 61 ; then take it to the floor-block and on 
 a long head in a tea-kettle shank (Fig. 62), or on the point of a side- 
 stake (previously shown in Fig. 45), commence to raze down the 
 wrinkles, bringing the razing-hammer down first in front, then on 
 each side of every wrinkle in succession, as in Fig. 63, beating down 
 at each blow from }i to % inch. Follow up each course until the 
 brim is reached ; then anneal by making it a bright cherry-red in the 
 shade. Now wrinkle again as before, only with this difference, that the 
 wrinkle which was exposed to the hammer before shall be in the hollow 
 in the next course, thus making all of the sides to feel the hammer 
 equally. The third course should bring the sides up sufficiently, and 
 maybe done with a mallet. The last course should bring the sides up 
 enough so that when the pan is being planished the expansion caused 
 by hammering will just bring "it to its proper size. Finally, smooth 
 out the marks made by the razing-hammer with any smooth-faced 
 hammer up to where the wiring edge is to be turned, and partially turn 
 the edge over. It is now ready for tinning, after which it is scoured 
 clean and planished — first the bottom on a bottom-stake (Fig. 62), and 
 then the side on a bright head ; when this is done it is wired. The 
 handle, which is a socket-handle made of iron, as shown in Fig. 64, is 
 now riveted on and the whole cleaned ready for the store-room. 
 
 It was stated that frying-pans were sometimes made larger than 
 15 inches. It may interest the reader to learn that in the old farm- 
 houses of England, where the fire is made on dog-irons on the hearth 
 under an open chimney, the frying-pans used (Fig. 65) were seldom 
 less than 18 inches in diameter, with a wire ^4 inch thick and a 
 handle from 5 to 6 feet long, so that the cook should stand a good dis- 
 tance from the fire without scorching. It would seem they were very 
 unpleasant utensils to use, for this long handle was merely a piece of 
 t bar-iron, with sharp corners about ^ inch thick, tapering from 1^ 
 inches at the flap to 1 inch at the ring by which it was hung in the 
 chimney corner when not in use. 
 
4 6 
 
 ART OF COPPERSMITH ING. 
 
 Pig. 66. — Pan for Water-Closet. 
 
 Fig. 67. — Blanks Fastened Together for 
 Raising. 
 
ART OF COPPERSMITHING. 47 
 
 CLOSET-PANS. 
 
 Copper pans for water-closets are made in a similar way to frying- 
 pans, but are of lighter material, scarcely ever stronger than io-pound 
 plates, usually of 8, and are raised from flat disks three at a time. 
 Their dimensions are about 4 inches at the bottom, 9 at top and 4 
 deep and wired with a No. 9 wire. Let us make three pans similar to 
 the one shown in Fig. 66 and let their dimensions be 4 inches at the 
 bottom, 9 at top and the sides 4 inches high. Then proceeding by the 
 rule already given to find the size of a disk equal in surface to a given 
 pan and one-half of the circumference of the wire we have: 
 
 V 
 
 - — -^ x 3-1416 x 4-25 + .7 8 54 = J 16 + 113-05 = "-364, 
 
 the diameter of a disk required to make the pan. Now cut two disks 
 11.364 inches in diameter and one x / 2 inch larger, upon which turn up 
 an edge % inch deep (Fig. 67) and lay the other two in it and close 
 the edge down on them; they may now be worked up as one pan. 
 Wrinkle the side regularly with the edge that holds them together on 
 the inside and proceed to work on the point of a side-stake in the 
 block with a raising-hammer. At the completion of each course an- 
 neal and wrinkle again, making the outside wrinkle the inside one 
 m the next course. When the pan is up enough smooth down the 
 hammer marks with a smoothing-hammer and separate the blanks. 
 After turning the edges for the wire they are ready for tinning. 
 After tinning and scouring they are planished in the grain, made 
 bright on the inside and brown outside; when planished wire and 
 clean. 
 
 WATER-BALLS. 
 
 Water-balls are a kind of float used for the purpose of regulating 
 the water-supply in tanks and reservoirs, so that they may always be 
 kept full. These spherical floats have a long strig or lever made of 
 , copper soldered to them, having a square hole in it to fit on the square 
 of the plug of a cock, as shown in Fig. 68, so that as the cistern or 
 reservoir is emptied the float falling with the water opens the cock. 
 
48 ART OF COPPERSMITHING. 
 
 and as it gradually nils again tne float rises and shuts off the supply. 
 These balls are made in various sizes from 4 to 12 inches in diameter. 
 They are made of light material, from 6 to 8 pound plate, according 
 to size, and, like closet-pans, are raised up three at a time. Let us 
 raise up three pair of halves for three 8-inch balls. As the convex 
 surface of a sphere is equal to the curved surface of its circumscribed 
 
 cylinder, we have — ■*• * — _ IO o.53i2, the convex surface of 
 
 2 
 
 jne-half a sphere 8 inches in diameter. Converting this into a disk 
 
 we get |/£5^-53£f__ 1 1.3 13 the diameter of a disk equal to the con- 
 
 •7854 
 vex surface of one-half of an 8-inch ball. But we must have a %Mnch 
 
 lap on one-half for the joint ; therefore the convex surface of this, 
 larger half will be 
 
 8 x 3.1416 x 4.25 = 106.8144 and 4/ to6 ' 8t44 = ri 661 
 
 ■7854 
 the diameter of a disk equal to the larger half. Having the size of 
 each half, two are to be cut the size of each and one each enough 
 larger to allow turning an edge over to hold the other two, as pre- 
 viously described and shown in Fig. 67. To find the exact size of the 
 inner circle to wrinkle from draw the semicircle ABC (Fig. 69). 
 Space it with the radius, dividing the semicircle into three equal 
 parts and join C H, H I and I A. Divide the versed-sine B E into 
 two equal parts and draw the lines M F, F G and G R parallel to 
 C H, H I and I A, then taking G F as the diameter from which to start 
 mark the circle on the disk (Fig. 70). After having wrinkled the disk 
 the same as in Fig. 61, start to raze down by striking with the hammer 
 first in front and then on each side of the wrinkles, as shown in Fig. 
 63, until all are razed down to the brim. Next anneal and wrinkle 
 again, razing down the wrinkles until the proper size is obtained ; 
 then take it to a bullet-head in the straight end of a tea-kettle shank 
 and break the lag down by holding it in both hands and hitting the 
 bottom on the head in the center to swell it out, and then with a mallet 
 work down the lag, beginning in the middle of the side. When the lag 
 is down, round up and smooth with a hammer, after which they may be 
 taken apart, browned and planished. The large half is to be beaded 
 with the hand-swage, as shown in Fig. 71. Tin the edge as far as the* 
 bead ; then put the halves together and solder the seam. The strig 
 or lever is finally soldered on and the article cleaned ready for the 
 store-room. 
 
ART OF COPPKRSMITIIINC;. 
 
 49 
 
 Fig. 68. — Water-Ball and Lever. 
 
 Fir. 69. — Method of Obtaining Circle. 
 
 Fig. 70. — Pattern for Half of Water-Ball. 
 
 Ifllp 
 
 lipiiilif 11 - 
 
 Fig- 7 1 - — Hand-Swfige. 
 
50 ART OF COPPERSMITHING. 
 
 MOUNTINGS FOR COPPER GOODS. 
 
 The preparation of mountings ; that is, spouts and handles for tea 
 kettles, handles for sauce pans, stew pans and all the many kinds of 
 utensils used in a kitchen is the next in order. In London, there are 
 men who rarely do anything else, but prepare mountings for all kinds 
 of brazier's work, but in the country shops braziers prepare the 
 greater part of their own mountings, which affords an opportunity 
 for a boy to learn how to make them that is very seldom open to him. 
 m a large city. Let us consider a few of the pieces among the many- 
 sets of mountings upon which a boy may display his best skill and 
 learn how to manipulate a file and burnisher, so that when the mount- 
 ing is attached to the article it is intended for it will be an ornament 
 and add beauty to the whole fabric. Many an otherwise good piece 
 of work has been spoiled for the want of proper symmetry in the 
 countings or carelessness in their finish. To file and finish mount- 
 ings is tedious work. Side handles for stock pots, fish kettles, and 
 the like ; ears for the cross handles or bails for coal scoops ; sockets 
 for sauce pans, coffee pots and scooplets ; bails, ears and barrel 
 handles for tea kettles, with the spouts for them and coffee pots all 
 this work, though tedious and requiring much care to execute it well, 
 is good to school a boy to patient labor. Common coal scoop bails ; 
 that is, those made for plain bright coal scoops, A, Fig. 72, were 
 usually made of -^-inch pipe nicely rounded up ; filled with rosin and 
 bent, then filed and burnished. In the illustration B shows an orna- 
 mental form of ear. The handles of such vessels as stock pots, tur- 
 bot kettles and preserving pans were of cast copper, Fig. 73. Tea 
 kettle handles were made in a variety of fashions as shown in 
 Figs. 76, 77, 78 and 79. The handle illustrated in Fig. 76 was made of 
 three pieces, a tube, see Fig. 74, and two rods made as in Fig. 75. 
 Sauce pan handles, Fig. 80, illustrates a coffee pot handle. Fig. 81 were 
 of two kinds principally : one B made of wood and inserted into, a 
 copper socket, the other A, a complete iron handle. These handles 
 were japanned when the goods were made brown ; if they were made 
 bright, the wooden handles were oiled, while the iron ones were 
 
ART OF COPPIiRSMITHING. 
 
 51 
 
 if" 3 ^ 
 
 Fig. 72. — Handle for Coal Scoop. 
 
 Fig. 73. — Slock Pot Handle. 
 
 Fig. 74.— Top Piece of Tea-Kettle 
 Handle. 
 
 Fig. y 5 . — Side Piece of Tea-Kettle 
 Handle. 
 
 Fig. ft— Completed Tea-Kettle Handle. Fig. 77.— Design for Tea-Kettle Handle. 
 
ART OF COPPERSMITlflNG. 
 
 Fig. 78. — Design for Tea-Kettle Handle. 
 
 Fig. 79.— Design for Tea-Kettle Handle. 
 
 Fig. 80. — Coffee- Pot Handle. 
 
ART OF COPPKRSMITHING. 
 
 53 
 
 Fig. 82. — Dimensions of Tea-Kettle 
 Spout. 
 
 Fisr. 81. — Sauce-Pan Handle. 
 
 £■—. 
 
 Fig. 83. — Pattern for Spout. 
 
 Fig. 84. — Working the Throat Down. 
 
54 
 
 ART OF COPPERSMITHING. 
 
 Fig. 85. — Candle-Mold Stake. 
 
 Fig. 86. — Spout Partly Formed. 
 
 Fig. 87. — Manner of Holding Spout with 
 Tongs. 
 
 Fig. 88. — Turning Over Laps. 
 
 fig. 89. — Spout Tool. 
 
 Fig. 90. — Spout Lilted with Lead. 
 
ART OF COPPERSMITHING. 
 
 55 
 
 
 a. 
 
 to 
 
 
 to 
 
56 
 
 ART OF COPPERSMITH [NO. 
 
 Fig. 94. — Polishing Spout with Hemp Rope and Emery. 
 
 ""..J'!:^ ^'-^''" ""' 
 
 Fig. 95. — Burnisher for Finishing Spout. 
 
 Fig. 96. — Spout Stake for Pitching Collars. Fig. 97. — Collar Pitched on Spout. 
 
ART OF COPPERSMITHING. 57 
 
 either tinned, or filed and burnished. This work always helped to 
 keep the bov busy. 
 
 Let us make and finish for one gallon tea kettles, a spout and the 
 several kinds of handles. The mouth of the spout on Fig. 82 should 
 be i^4 inch, at the breast, C, 1% inch, and at the end, about yk 
 inch. The pattern for spout, Fig. 83, will be 2 inches wide at E, and 
 2^4 inch at C, and 3 inches from F to G. Cut it off and smooth off the 
 burrs, and on the back of a side stake, or some other suitable stake, 
 Fig. 84, draw over each side % inch and then thin the edge ; 
 then on the-candle mold stake, Fig. 85, turn the stem of the spout and 
 bring the two flaps together as in Fig. 86, and lap the seam together 
 about }i inch. It is then ready for the fire. Charge the joint with 
 spelter and gently dry at the fire, holding the spout with the tongs, 
 Fig. 87 ; when the borax is down and the back is blood red, turn the 
 spelter to the fire and run it down the joint; when cool, round up the 
 stem and file the joint smooth. Next turn the flaps and form the 
 mouth as in Fig. 88, and charge the joint inside and braze it down, 
 leaving the hole at the breast open. Now put the spout tool, Fig. 
 89, in a vise and round up the breast, C, Fig. 82, at the same time 
 drawing in to close up the hole left; when closed it is to be brazed; 
 it is now ready for filling with lead. To do this wrap a piece of 
 thick paper around the end and lay it in a box of damp sand, cov- 
 ering it to within l A inch of the mouth ; then put in a piece of iron 
 rod 5 or 6 inches long, Fig. 90, which forms a sort of handle for hold- 
 ing the spout when at the vise, and fill the spout with nice clean soft 
 lead. When cool, bend the stem as shown in Fig. 91. This used to be 
 done with a mallet over a lead piece, Fig. 92. An improved way is 
 shown in Fig. 93, the bending being done by placing the spout 
 through a hole in the lead pieces, and by means of a rope block and 
 lever the spout is bent by pressing down on the lever. After the bend- 
 ing is done we then true the whole up, making the distance through 
 the breast at C, Fig. 82, a little smaller than the end, so it 
 will go with ease into its place in the kettle. It is then 
 filed, the joint being cleaned up with a half-round file, then 
 rough filed all over. Smooth again with a fine file, and fol- 
 low with emery cloth wrapped around a stick, and finally smooth 
 with a piece of soft hemp-rope and fine emery, taking one hitch with 
 the rope around it, Fig. 94, and pulling it back and forth until fit for 
 the burnisher. Now wipe it clean, and when free from all grit rub a 
 
58 ART OF COPPERSMITHING. 
 
 little sweet oil over it, and with a clean bright burnisher, Fig. 95, take 
 a course all over it. Now wipe it off and examine it, and touch up all 
 parts which may have escaped the burnisher, then cover all over with 
 wet whiting, and at the fire gently run the lead out, being careful that 
 it does not get too hot. Next fit the mouth of the spout to the side of 
 the kettle and on a spout, stake, Fig. 96, pitch the spout, leaving a 
 collar, as shown in Fig. 97, % inch wide ; after which file the jaws in 
 the small end of the spout and tin it on the inside ; it is then ready 
 for the kettle. 
 
 The handles or bails have been shown, Figs. 76 to 79, the barrel, 
 Fig. 77, is sH inches long and 1 inch in diameter; the straps are 1 
 inch wide, 6 inches long and about T V inch thick. In order to braze 
 these straps on the barrels we had two frames, made of inch-hoop 
 as shown in Fig. 98. The frames were made so that when the straps 
 were wired on, the barrel would slide in tight ; they are then charged 
 with spelter and the straps brazed to the barrel. While one is cooling 
 the other can be prepared. When cool, clean and trim off the corners 
 around the barrel and round up the edges of the straps with a file 
 and then burnish them ; finally planish the face and bend as shown. 
 (This kind of bail is probably the oldest in use, for the writer saw 
 when a boy, tea-kettles having the same kind of handle, which could 
 easily be traced back from son to father for 100 years or more.) An- 
 other kind of handle, Figs. 78 and 79, were cast straight, of a flat, oval 
 shape, they also were filed and burnished before bending. In the bar- 
 rel handle, Fig. 76, the straps were brazed to the barrel and then filed 
 up and finished and bent on a suitable bright tool. The sockets for 
 coffee-pot and sauce-pan handles, Figs. 80 and 81, were made of strong 
 copper and finished with file and burnisher. The burnisher, Fig. 95, 
 was made from an ordinary 12-inch safe edge file, with the teeth ground 
 out and ground to the desired shape. It would appear that this 
 trouble was taken in order to retain the original temper given the file, 
 it being the best for this kind of tool. Handles for preserving pans 
 and turbot kettles, Fig. 73, were filed and finished bright in the same 
 way as spouts, the soft rope, Fig. 94, being used to assist m the opera- 
 tion. 
 
 Tea-kettle rings, on or in which the cover sets, were made in two 
 ways : one was to wire a narrow strip, Figs. 99 and 100, and after 
 putting it through the hole up close to the wire, turn the edge back on 
 the inside. The other way was to cut a strip of copper, Fig. A , and 
 
ART OF COPPERSMITHING. 
 
 59 
 
 
 
 S 
 
 ^ 
 
 $ 
 
 
 bo 
 
 IN! 
 
 A?*. 
 
 53 
 
 
 D 
 
 to 
 
 
 
 ■i 
 
 % 
 
 "■« 
 
 ::::::- f 
 
 ^ 
 
 — -jp 
 
 
 ~^R 
 
 * 
 
 
 
6o 
 
 ART OF COPPERSMITHING. 
 
 hammer it while hot in a die, Fig. B , then form it round and 
 solder it together. Next braze a narrow strip of copper around the 
 middle of the ring on the under side, see Fig. C , so as to go through 
 the hole in the kettle and turn over to hold the ring in. This makes 
 a nice looking job. The wire ring was used for common brown kettles 
 and glue-pots. 
 
 Fig. C— Ring for Covet Support. 
 
ART OF COPPERSMITHING. 6 1 
 
 GLUE POTS AND TEA-KETTLES. 
 
 Glue pots may be considered as the stepping-stones to tea kettle 
 making, as the bodies are made the same size and way, and if a boy 
 (or man either for that matter,) will take the necessary care and in- 
 terest while being instructed in the work of making glue pots, he may 
 attain the proficiency necessary to execute the best work, such as is 
 demanded for bright goods. Let us begin to make two round bodies, 
 the same as for i -gallon glue pots, and at the proper place we will 
 branch off, finishing one a brown glue pot, and the other a bright tea 
 kettle, following throughout the methods in vogue when the copper- 
 smith made his own mountings. The body for a gallon glue pot or 
 tea kettle is cut 24 inches long and 6 inches wide, and from an 8 to 
 12-pound sheet. Having cut the body from a 10-pound sheet smooth, 
 cramp and put the edges together, Fig. 101, and braze the joints. 
 After careful examination trim the corners and then knock down the 
 joint on a side stake to make it the same thickness as the sheet. 
 When annealed, divide the depth into three equal parts as shown in 
 Fig. 10 1 and with a racer, mark distinctly, so the divisions may serve 
 as a guide for the work about to be begun. Take the two bodies to 
 the block, and on a head m the straight end of a tea kettle shank, Fig. 
 102, draw in a light course at each end of both with a mallet, keeping 
 the wrinkles that form, in regular order as they appear, and until the 
 course is completed ; then anneal. This should bring in the bottom 
 end enough ; the other end, or that which is for the top, may now be 
 razed down another course with a hammer ; when this is completed, 
 anneal and knock the side out even with the bulge caused by razing 
 down the top. Take it to a bullet stake, Fig. 103, and finish razing 
 down the top until the hole for the cover is 4 inches in diameter. 
 Stag in the bottom, partly on the long-head, and finish it on the tea 
 kettle bottom stake, Fig. 104 ; thin the edge and anneal, and it will be 
 ready for the bottom. The bottom should be about 6 inches in di- 
 ameter, and of about 13 or 14-pound plate ; the hole to receive the 
 bottom should be slightly smaller than the bottom before thinning. 
 The bottom is to be thinned and cramped, Fig. 105, making the cramps 
 about 1 inch long ; open each alternate one and lay in the bottom 
 
62 
 
 ART OF COPPERSMITHING. 
 
 Fig. 101. — Body of Gallon 
 Glue Pot or Tea-Kettle. 
 
 Fig. 102. — Forming Tea-Kettle Body. 
 
 Fig. 103. — Razing Down Top on 
 Bullet Stake. 
 
 Fig. 104. — Turning Lag on Bottom Stake. 
 
ART OF COPPERSMITHING. 63 
 
 which should go in easy, but not too loose ; lay the cramps down on 
 the bottom stake, Fig. 104, and popple the bottom, when it will be 
 ready for brazing. 
 
 The spelter should be fine, clean, and free from dust. With a 
 charger, Fig. 106, made from a ^-inch rod, having the end flattened out 
 like a spoon, lay a little borax and water around the cramps on the 
 outside, and jar it through the joint ; charge the joint on the inside, 
 laying as much spelter on as will when run fill up the joint, follow- 
 ing the zigzag line of the cramps ; when charged, dry slowly. The 
 fire should be clean and free from coal. A nice clean coke fire is best, 
 but if coal cinders are used by way of economy, then prevent as much 
 as possible the coal from coming in contact with the joint. When the 
 spelter is dry take a piece of rough but clean canvas or rag, and brush 
 off all the borax on the outside, so that no inducement be offered to 
 the solder to spread further thanls necessary from the joint while the 
 spelter is being run around the seam. Holding the pot with a pair of 
 tongs, heat the sides gently until the borax is all down ; this is also 
 done for the purpose of distributing or charging the. body with heat 
 before proceeding to run the joint ; then with a steady blast turn it 
 around, turning the pot with two handy pokers or rods. If the joint 
 is perfect take it to a bullet stake and pounce the bottom up enough 
 so that the sharp corners ot the cramps may be filed off easily ; clean 
 them off, then knock the joint down. Cover the surface inside and 
 out with a pickle of salt and water, by immersing it in the 
 pickle tub, and while wet sprinkle a little dry salt around the seam 
 to kill the borax. Then heat it to a bright cherry red in the shade, 
 and thrust it into the pickle tub. If there be any borax left the pot 
 may be put into the vitriol tub for a few hours, scoured clean, then 
 dried in sawdust, when it is ready for planishing. 
 
 Having finished the two vessels as described, the one intended 
 for a glue pot has a coat of Spanish brown rubbed over the outside ; 
 the one intended for a tea-kettle is kept clean and bright. The plan- 
 ishing is first begun on the bottom stake, Fig. 104, and the bottom 
 made flat and true, the lag being rounded up with a mallet, then the 
 side is next planished on a suitable head in the shank, Fig. 107. 
 
 The workman should be seated at the side of the block so 
 his left side is toward it, the arm of the shank extending over 
 the end of the block, the left hand holding the pot or kettle with the 
 fingers inside and the thumb outside ; the right knee should be used 
 
6 4 
 
 ART OF COPPERSMITHING. 
 
 Fig. 105. — Putting in Bottom. 
 
 Fig. 108.— Clamp for Holding Tea-Kettle While 
 Being Tinned. 
 
 Fig. 106. — Charger. 
 
 Fig. 109. — Tow-Wisp Used in Tinning. 
 
 Fig. 107. — Planishing Tea-Kettle Side. 
 
ART OF COPPERSMITHING. 65 
 
 to steady and guide the work, the body of the kettle on the under 
 side resting on the left knee, and the lag of the kettle against the 
 right ; when the side has been run over, the other end of the shank 
 is used and the top planished. They are now to be tinned inside, 
 thus : A little new muriatic acid is rubbed over the inside, which is 
 next scoured and rinsed clean ; then some wet whiteing is rubbed on 
 the outside to keep the fire from affecting the surface. The clamp 
 (see Fig. 108) is fastened to the kettle by means of the link which 
 slides down the rod and thus forms a handle. The inside of the ket- 
 tle is to be rubbed over with soldering acid in which a little salam- 
 moniac has been dissolved, and the kettle heated enough to flow tin 
 or solder, enough of which is melted and poured in so it can be 
 rinsed out and then wiped off with a tow wisp wound around a wire, 
 Fig. 109. After tinning, the inside is washed with clean water and 
 the whiteing washed off ; when it is dry the outside of the kettle is 
 scoured with a piece of flannel moistened with sweet oil and then 
 wiped off clean. It is now ready for the smoothing course of planish- 
 ing, which is done with a spring-faced hammer. The hole for the 
 spout is now to be cut in the center of the side, the hole being made a 
 half-inch smaller than the diameter of the mouth of the spout, to allow 
 of a ^-inch collar being worked out (see Fig. no) to fit m the pitch 
 of the spout. Put in the cover ring, Figs, no and in, and turn the 
 edge back as described in the article on mounting ; then fit in the 
 spout, closing the collar around the pitch with the collar-tool, Fig. 
 xi 3, and soft soldering around the flange on the inside of the kettle 
 The handle of the kettle having been previously prepared with the 
 ring and spout, it is now riveted on, also the ears of the glue-pot. 
 
■66 
 
 ART OF COPPERSMITHING. 
 
 Fig. no. — Tea-Kettle, Showing Spout 
 Attached. 
 
 Fig. in. — Cover Ring-. 
 
 Fig. 113. — Broken View of Collar 
 and Ring. 
 
 Fig;. 112. — Collar Tool. 
 
 Fig. 114. — Glue Pot with Inside Cup. Fig. 115. — Cup for Making Boss on Cover. 
 
ART OF COPPERSMITHING. 
 
 67 
 
 Fig. 117. — Finished Tea-Kettle Cover. 
 
 Fig. ti6. — Bullet Head Hammer. 
 
 Fig. 118. — Finished Tea-Kettle. 
 
 Fig. 119.— Body of Oval Tea-Kettle. 
 
 Fig. 120. — Method of Drawing Oval 
 
 Bottom. Fig. 12 r. — Oval Tea-Kettle ', Showing Top. 
 
68 
 
 ART OF COPPERSMITHING. 
 
 The inside cup of the glue pot, see Fig. 114, is put together and 
 the seam soldered in the same manner as the outside, and the bottom 
 put in in the same way. The top may be wired with a large wire, or 
 an edge laid off square/ to rest on the ring of the outside boiler, the 
 bottom of the cup when hanging in place being about an inch above 
 the bottom of the kettle. The cover for the tea kettle is next in order : 
 the rim is made to fit easy, and so that when the edge of the rim is in 
 the cover and the cover paned down, the cover will set in the seat of 
 the ring, Fig. 113. The cover is hollowed first, and then the boss is 
 worked out in a cup, see Fig. 115, made of a ferrule of strong copper 
 and having a strig ot iron secured in it by pouring solder around a 
 head made on the end of the strig. This cup is held in a vise, as 
 shown in Fig. 115, and the boss worked out with a bullet-faced ham- 
 mer, Fig. 116, then the cover is planished and the rim and knob put 
 in, Fig. 117. The finished tea kettle is shown in Fig. 118. When the 
 kettle and cover are completed they are scoured bright with a piece 
 of flannel moistened with sweet oil, to which a little Tripoli is added 
 
 Dimensions of Round Tea-Kettle. Bodies, &c. 
 
 and finally polished with dry Tripoli powder. Full directions are 
 given in the article on mounting for the making of spouts and 
 handles. 
 
 Oval Tea-Kettles. 
 
 Oval tea-kettles, Fig. 122, have usually been made differently 
 from round ones, as the tops are generally double-seamed on, al- 
 
ART OF COPPERSMITHING. 
 
 6 9 
 
 though occasionally they are ' made with the tops razed down in the 
 same way as are the round ones. There have been quite a number of 
 fashions and some artistic skill displayed on oval tea-kettle covers 
 and handles, much more than on round ones. We will make one, 
 such as are ordinarily made for every-day use (the learner may dis- 
 play his artistic skill at his leisure) to hold 1 gallon, as in the case of 
 the round kettle. The body is cut 23^ x 51^ inches, and from a 10- 
 pound sheet. The body is to be put together in a similar manner to 
 the round one : After smoothing the edges, thin the ends, cramp one, 
 solder the joint, clean it off, knock down and anneal. Then take to a 
 head and work in a light course, beginning one-third from the bot- 
 tom, after which stag in the lag yi inch wide, partly on the head, fin- 
 ishing on the bottom stake (Chap. VII., Fig. 104) and thinning the 
 edge. Cut out the oval bottom Q, Fig. 119, making it a trifle larger 
 than the hole of the lag. Fig. 120 shows method ot drawing bottom. 
 Thin the edge and cramp as indicated in P, Fig. 119, then lift each 
 alternate cramp and put the bottom in from the inside, lay the cramps 
 down close, then braze and finish, and tin as directed for the round 
 
 No. of 
 Pints 
 
 2, . 
 
 3- 
 
 4- • 
 
 5-- 
 
 6.. 
 
 !■■ 
 8. . 
 10.. 
 12 . 
 
 Length 
 bodv. 
 
 of 
 
 16^ inches. 
 
 21% 
 26/ 2 
 
 Depth of 
 body. 
 
 3^3 inches, 
 4/8 
 
 4^8 
 
 4/8 
 
 4/8 
 
 5% " 
 
 5% 
 
 6 
 
 6V 2 
 
 Weight of copper for 
 
 Body. 
 
 Bottom. 
 
 8 pounds. 
 
 10 
 
 pounds. 
 
 8 
 
 12 
 
 u 
 
 9 
 
 12 
 
 (( 
 
 9 
 
 13 
 
 (t 
 
 9 
 
 13 
 
 a 
 
 10 
 
 13 
 
 
 10 
 
 14 
 
 (t 
 
 11 " 
 
 14 
 
 tt 
 
 11 " 
 
 14 
 
 u 
 
 Spout and 
 barrel. 
 
 13 pounds. 
 
 13 
 
 14 
 
 14 
 
 14 
 
 14 
 
 15 
 
 *5 
 
 15 
 
 Dimensions of Oval Tea Kettle and Weight of Copper. 
 
 tea-kettle, truing it up to the shape Q, Fig. 119. Turn the edge for 
 the top and make the top, Fig. 121, which is to be double 'seamed on 
 
7<D ART OF COPPERSMITHING. 
 
 to the body. The cover (see Fig. 122) is to be made in the usual man- 
 ner, the boss being sunk in an oval cup similar to the one shown in 
 Fig. 115. The handle, having been previously made, is to be riveted 
 on and the rivet-heads soldered on the inside. When all is com- 
 pleted, polish for the storeroom with Tripoli, as previously directed. 
 
 tig. 122. — Oval 'lea-Kettle with Cover and Handle Complete. 
 
ART OF COPPERSMITHING. 7 1 
 
 BEER MULLERS. 
 
 Copper beer mullers, or warming pots, will next engage our atten- 
 tion. These are nice little jobs for a boy, progressive in their char- 
 acter, and give, after the first three years of .drudgery, some relief to 
 the monotony of scouring, breaking coke, and other so-called boy's 
 work, the continued repetition of which has often been the means of 
 breaking the spirit and blighting the hcpes of many a good promising 
 lad, who has been kept dragging along, year after year, wasting 
 precious time at work that should have been shared between man 
 and boy, and which could have 'been done without loss or detriment, 
 but rather a benefit to both. I would pause to plead for the boys of 
 the coming generation as I have often done for those of the past, 
 craving for them sympathy, when they have been compelled to com- 
 plain (and justly, too,) of the amount of time which has been sacri- 
 ficed by them in incessant and unnecessary drudgery, often times, 
 too, with a man who was altogether inferior m perception or mechan- 
 ical ability to the lad placed under his control. If a lad is once given 
 a place in a shop to learn any trade, he should have a chance to de- 
 velop at least his own natural ability, even though the kind attention 
 he should receive be withheld. 
 
 Beer mullers are made after three general designs, peaked, open 
 and curved. Our first job at these (and they were the first vessels we 
 began and finished complete) was a half dozen y 2 pints, three with 
 lips and three without. We will now describe the various operations: 
 A y 2 pint (British standard) muller, Fig. 123, measues 2% inches at 
 top, 3^ inches deep and 3 inches at bottom. To describe the pattern : 
 Let C D F G, Fig. 124, represent the elevation of article, which is 
 shown 3^5 inches deep, to allow for wire at top and edge at bottom. 
 Through the center draw the center line K B. Extend the lines F D 
 and G C, until they meet the center line as at B. Then B C and B G 
 are the radii of the arcs which contain the pattern. With B as a 
 center, describe the arcs J N and H L indefinitely. Upon the arc J N 
 measure the circumference of the bottom of article, and from these 
 points, as J and N, draw lines to the center B. Then L H J N will be 
 the pattern for the article shown by C D F G. Having obtained the 
 
72 
 
 ART OF COPPERSMITHING. 
 
 'Fig. 123.— Half -Pint Beer Muller. 
 
 Fig. 124. — Pattern for Muller. 
 
 Fig. 125. — Turning Over Edge for Wire. 
 
ART OF COPPERSMITHING. 
 
 73 
 
 Fig. 129. — Hammer Face Formed 
 
 Fig. 126. — Forming Concave Side of Muller. 
 
 Fig. 127. — Spring-Faced Planishing 
 Hammer. 
 
 Fig. 130. — Creasing Hammer. 
 
 Fig. 128. — Pattern' for Hammer Face. 
 
74 ART OF COPPERSMITHING. 
 
 pattern, it is to be cut out of about 6-pound plate ; thin the edges 
 cramp and form, and braze the seam ; then clean off and knock down 
 the joint, and anneal. Now turn the edge over for the wire, as shown 
 in Fig. 125, and work in a course from the bottom to form the curve 
 or bell at the base, as shown in Fig. 126. It is then ready for tinning 
 inside. When tinned and scoured it is ready for planishing, which is 
 done on a bright side stake, with a small spring-faced hammer, Fig. 
 127 — that is, a hammer with an extra face of thin sheet steel, made 
 and fitted as follows : A piece of sheet steel, of a suitable thickness, in 
 this case about 20 gauge, is cut, as shown in Fig. 128, the two ends 
 turned up as in Fig. 129, to fit the hammer- face, .the lugs being placed 
 in a line with the handle. When fitted suitably lay between the 
 hammer-face and the spring-face two or three layers of French shal- 
 loon, which answers as a cushion; now bind the lugs with a stout piece 
 of binding wire, and turn the points of the lugs down on the wire in 
 such a way that they will tend to draw the spring-face close up and 
 tight to the hammer. After polishing, it is ready for use. The job 
 must now be cleaned inside and out with a piece of nice soft rag, then 
 commencing close up to the wiring edge with the hammer, begin to 
 planish and follow each course around the body until the bottom is 
 reached; then again clean it inside and out, and planish it over again 
 to smooth and finish it. Now put in the wire and then the bottom, 
 which is done thus: With a creasing hammer, Fig. 130, on the creasing 
 iron, Fig. 131, sink the edge around the bottom edge, being careful to 
 make it regular and true. Then lift the edge enough to lay the bot- 
 tom in the crease as shown in Fig. 132, the bottom having been pre- 
 viously tinned and planished, bring the edge down close and solder 
 the bottom around inside, or if preferred the bottom may be soldered 
 on the outside, keeping the soldering-iron as close to the outside edge 
 as possible, that the work may be neatly done. When this is done 
 form the lip on an extinguisher stake as shown in Fig. 133 by placing 
 the cup on the beak, and with a hatchet-shaped mallet sink the wire 
 on each side of the stake, a little at a time, until the lip is formed. 
 Then with the wooden set, see Fig. 133, made of boxwood and smooth 
 like the pane of a hammer, shape the V of the lip on the point of the 
 stake, letting the point extend a third down the body, or they may be 
 left without the V, the wiring only being bent. Make the handle, 
 Fig. 134, 4 inches long from 30-pound plate, the edges being made 
 round and burnished, ana the surface planished smooth; after bend- 
 
ART OF COPPERSMITHING. 
 
 75 
 
 Fi<r, 131. — Forming Crease in Bottom. 
 
 Fig. 132. — Laying Bottom 
 in Crease. 
 
 Fig. 133. — Forming Lip on Mutter. 
 
7 6 
 
 ART OF COFl'FKS.MITillNG. 
 
 ing into shape as shown, rivet on and clean the article. Handles for 
 the three largest sizes of mullers are made hollow and bent, having 
 a flap brazed on as shown in Fig. 135, the small end being flattened 
 and filed to the desired shape. 
 
 Fig. 134.— Handle for Small Mutter. 
 
 Fig- ?35« — Handle for Large Mutter^ 
 
ART OF COPPERSMITHING. 
 
 77 
 
 Fig. 136.— Old Style of Muller. 
 
 Fig. 137. — Covered Muller. 
 
 Fig. 138. — Pattern for Peaked Muller. 
 
 Fig. 139. — Pitched Cover. 
 
78 ART OF COPPERSMITHING. 
 
 The peaked Muller, Fig. 136, is an old design, and was made in 
 two sizes — namely, pint and quart, while the covered mullers of the 
 shape illustrated in Fig. 137 were made in five sizes, from %. pint to 2 
 quart— that is, Vz pint, pint, quart, 3 pint and 2 quart. 
 
 The peaked muller, Fig. 136, is made in two ways; in the one the 
 side is brazed together; in the other it is grooved; if the side is brazed 
 the work is similar to that already described. If the side is to be grooved 
 the pattern is tinned, planished, wired and the edges are turned, be- 
 fore being formed into shape, after which the point is flattened and 
 turned over, as shown in Fig. 136. The pattern for a muller of this 
 conical shape to hold 3 pints is shown in Fig. 138, and should measure 
 6 inches at the brim inside and about 11 long after the point has been 
 flattened and curled. 
 
 The covered muller, Fig. 137, was made similar to the one shown 
 in Fig. 123, but with a socket and wood handle, the body curving the 
 other way, as shown, it also had a pitched cover. To pitch a cover is 
 to raise it in the center, Fig. 139, a certain distance, which is roughly 
 done on the block, Fig. 140, having a suitable hole cut in it for this pur- 
 pose, and with the hammer like the one shown in Fig. 142, having one 
 round face and the other oblong. With the round face sink or beat 
 the copper into the hole in the block, allowing the edge to pucker up 
 all around until the pitch is of sufficient depth, which takes two 
 courses to complete, then raze down the wrinkles with a mallet and 
 smooth with a hammer; next tin the inside of the cover and planish 
 it, first on a small bottom stake, Fig. 141, and then on a side stake, 
 Fig. 142, or some other suitable head, with the oblong face of the ham- 
 mer, and, lastly, on a bright anvil, held in an upright shank, Fig. 143, 
 planish the outer ring and wire the edge. The cover should be large 
 enough, so that the wire of the body will just fit in the wiring of the 
 cover. The joint or hinge of the cover shown in Fig, 144 is slipped 
 through the notch left in the wiring of the body and then riveted to 
 the cover. The bottom may be doubled seamed on or put in as has 
 been described for open mullers. The socket for the handle is placed 
 in the middle of the body, as shown in Fig. 137. 
 
ART OF COPPERSMITHING. 
 
 79 
 
 Fig. 142. — Planishing Cover on Side 
 Stake. 
 
 Fig. 141 .—Planishing Cover on Bottom Stake. 
 
 Fig. 144. — Cover Hinge. 
 
 Fig. 143. — Anvil Held in Upright 
 Shank. 
 
8o ART OF COPPERSMITHING. 
 
 FUNNELS. 
 
 Copper Funnels, Fig. 145, were generally made brown, in size- 
 from pint to gallon, namely : pint, quart, 3 pint, y 2 gallon, and gallon. 
 Let us make one to hold a y 2 gallon ; that is, one into which a y 2 gal- 
 lon of liquor may be dumped without running over. It will be found 
 that an 8-inch cone whose slant hight is equal to its diameter will 
 hold approximately a y 2 gallon, Imperial measure. Funnels have 
 always been made of one style, and formed of one-half a disk whose 
 radius is equal to the diameter of the mouth of the funnel. Braziers, 
 however, tuck in the mouth from 1 to 2 inches, according to the 
 size. Our pattern, then, will be y 2 of a 16-inch disk, % of an inch 
 being added for wire, and the hole for the outlet being 1 and % inches 
 when finished, being cut y& less to allow of a narrow collar being 
 worked out to lap on the spout. Cut out the pattern, Fig. 146, from 
 8-pound plate, thin, cramp, form and join as in Fig. 147, then anneal 
 and tuck in the rim on a side stake, Fig. 148. The edge is next 
 turned for the wire, with a crease iron and hammer, in the same man- 
 ner as the edge of the beer mullers was turned. It is now ready for 
 tinning ; when tinned and scoured, wipe the inside with a soft rag, 
 and rub some Spanish brown over the outside, then planish on the 
 bright head, Fig. 150; put in the wire, Fig. 149, and it is ready for the 
 spout. The spout should be pitched and flanged as at H, Fig. 151, 
 and the outlet collared as at K, so that when the spout is in, and the 
 collar set down close, it will be held fast as at J It is then to be 
 soldered on the inside, being careful that no solder runs through to 
 mar the outside ; put on the ring and clean. Bright heads, Fig. 150, 
 are shaped in such a way that their faces form as it were a section of 
 of the funnel, with the heel made to fit the booge or rim, and are 
 used principally for these funnels and the kind of spirit measures 
 shown in Fig. 152. 
 
ART OF COPPERSMITHING. 
 
 Fig. 146. — Pattern for Funnel. 
 
 Fig. 145. — Copper Funnel. 
 
 Fig. 147. — Funnel Formed and 
 Cramped. 
 
 Fig. 148. — Tucking in Rim on Side Stake. 
 
82 
 
 ART OF COPPERSMITHING. 
 
 ■Fig. 149. — Putting in Wire. 
 
 Fig. 150. — Bright Head on which Funnel 
 is Planished. 
 
 Fig. 151.— Joint Between Spout and 
 Funnel. 
 
 Fig. 152.— One Form of Spirit Measure. 
 
ART OF COPPERSMITHING. 
 
 83. 
 
 COFFEE POTS. 
 
 Coffee pots were made as shown in Fig. 153, and somewhat similar 
 to the muller, Fig. 123, but their hight was two and a half times the top 
 diameter; that is, if the diameter at the top is 4 inches, the pot would be 
 10 inches deep, and the bottom one and a half times the top, or 6 inches 
 in diameter. They were made in four sizes, namely : 3-pint, 2-quart, 3- 
 quart and 4-quart. An imperial y 2 gallon contains 138 cubic inches, and 
 a frustum of a cone whose dimensions are 3^ inches at top, 5^ inches 
 at bottom and '9 inches deep, will hold 150 cubic inches ; but when 
 the curve is given to the side, by working in a course and smoothing, 
 the capacity is reduced enough so that the pot will hold just about. J4 
 a gallon when it is finished. It is well to say here that all such vessels 
 as these only approximate to the capacity named, most of them hold- 
 ing somewhat more than the given amount. The pattern is cut 
 according to the method already shown in Fig. 124, an 8-pound plate 
 being used for the purpose. After the seam has been made and the 
 body annealed, take in a course on a side stake, as previously explained 
 in Fig. 126, until the body appears straight one-third the depth from 
 the top, and then gradually hollow out the remaining two-thirds, bell 
 fashion, down to the bottom ; smooth, true up and turn the edge over 
 for wire, when it is ready for tinning. When this operation has been 
 performed it is planished on a bright side stake, and the wire put in, 
 Fig. 154. The hole for the spout is next cut, the center of the hole 
 being one-third the depth from the bottom of the body, Fig. 155. Cut 
 out the spout, Fig. 156, thin the edge, turn it round and braze the 
 seam ; clean off the seam and tin the spout inside ; then round up and 
 smooth with a mallet, after which take a suitable stick or a file, and 
 with emery cloth lapped around it prepare the spout for the bur- 
 nisher, and burnish it. Now pitch the spout on the under side, 
 Fig- 157, then work out the collar of the pot, Fig. 155 D, to fit in the 
 pitch of the spout, Fig. 157, and then put in the spout. Set down the 
 collar close to the spout with a set shaped like a gouge, the end being 
 square or blunt ; then put in a small rivet at the end of the spout 
 Fig. 155 D, and solder it inside. Next put in the bottom the same as 
 was done with the open muller and solder it inside. The socket for 
 
ART OF COPPERSMITHING. 
 
 Fig. is?,.— Coffee Fot. 
 
 Fig. 155.— Joining Spout to CoffeePot. 
 
 Fig. 154. — Wiring Body of Coffee Pot. 
 
ART OF COPPERSMITH r NO. 
 
 »5 
 
 Fig. 156. — Pattern of Spout. 
 
 Fig. 158. — Socket for Wooden Handle. 
 
 Fig. 159. — Tools for Turning Burr on 
 Cover. 
 
 Fi g- i$T.— Coffee Pot Spout. 
 
 Fig. 160. — Piening Hammer for Covers. 
 
86 ART OF COPPERSMITHING. 
 
 the wooden handle, shown in Fig. 158, is made as before directed for 
 hand bowls and the cover is pitched the same as for 
 mullers.. The coffee pot cover, however, must have a rim about 
 Yz inch wide, when edged ready for the cover. In order to turn the 
 edge on cover (as we had no burring machine), we had to use the tool 
 shown in Fig. 159, of which there were three different sizes. They 
 were called "taking up stakes;" that is, stakes for taking up the 
 edges of bottoms and covers. The bottom end of the stake enlarged 
 so as to fit the hole made for it in the bench. The edge of the cover, 
 after the rim is in, is peined down with a hammer kept especially for 
 the purpose, as shown in Fig. 160. Now put in the joint or hinge 
 through the notch left of the wiring, and through a notch left in the 
 rim of the cover and rivet on the cover, put in the wooden handle, 
 then clean the article for the storeroom. Some coffee-pots had bent 
 spouts, like tea kettle spouts, which made a more ornamental coffee 
 pot than when plain spouts were used. 
 
ART OF COPPERSMITHING. 87 
 
 SAUCEPANS AND PUDDING POTS. 
 
 It is probable that among the culinary utensils made by braziers 
 40 years ago there were more saucepans than almost any other 
 article ; but later on the French stew-pan seemed to supercede the 
 saucepan altogether, excepting in a few instances, such as the 
 smaller sizes, which were made with lips and used for the prepara- 
 tion of hfctle delicacies. Copper pudding pots were also in good de- 
 mand before they were supplanted by those made of cast iron, which 
 were not only tastefully designed, but were much cheaper and safer 
 to use, wh'irc those made_ from copper were apt to be neglected and not 
 kept clean and properly tinned. The progressive braziers were, how- 
 ever, equal to the emergency, and turned their attention to the manu- 
 facture of wrought iron goods, made in the same way and after the 
 same fashion as the copper goods. 
 
 It may be stated here, for the benefit of the learner, that the pro- 
 portions of all vessels are in ratio to one another as the cubes of their 
 diameters ; hence a boy who has the desire to become proficient and 
 make an efficient workman, and understand the proper proportions of 
 the work he is engaged at, should make himself conversant with solid 
 geometry, and thus be prepared to work out any example in cubic 
 proportion likely to be called for. Two examples will be given, 
 showing how the dimensions of all sizes smaller and larger than one 
 gallon may be obtained, providing the utensil is made of a straight 
 strip. The strip for a gallon saucepan is cut 24 inches long by 7 
 inches wide. Let it be required to make one to hold 6 quarts. The 
 strip of metal 24 inches long is to be formed into a cylinder thus : 
 24 •*■ 3.1416 = 7.6394, its diameter, and as all cylinders are to each 
 other as the cube of their diameters, and as we want a cylinder to 
 hold one-half as much more, and in the same proportions as to hight, 
 
 we cube the diameter of the first cylinder — namely -=445.8384, 
 
 7-6394 
 
 and then 445 ' 3 4 ' x 3 — 668.7576, and I/668.7576 = 8.78, the diameter 
 
 of a cylinder required for a 6 -quart saucepan. Then, 7.6394 : 7 :: 
 8.78 : 8.0451, and 8.78 x 3. 1416 = 27.5832. Therefore the sheet for 
 
ART OF COPPERSMITHING. 
 
 Fig. 162. — Copper Pudding Pot. 
 
 Fig. 163.— Pudding Pot Cover. 
 
 Fig. 164. — Braziers' way of Measur- 
 ing Saucepans, etc. 
 
 Fig. 165. — Body Marked for Razing. 
 
ART OF COPPERSMITHING. 
 
 Fig. 166. — Manner for Razing Top Part 
 of Body. 
 
 Fig. 167. — Lag Drawn in for Bottom. 
 
 Fig. 168. — Lipped Saucepan. 
 
 Fig. 169.— Slack Left for Forming Lip' Fig. 170.— Oval Pudding Pot. 
 
9" ART OF COPPERSMITHING. 
 
 a 6-quart saucepan would be about 273^ inches long and 8 inches wide — 
 approximately — that is near enough for practical purposes. Again, let 
 it be required to make a saucepan to hold 3 quarts. Then proceeding 
 
 similarly, as above, = 445.8384, and as there are 4 quarts in 
 
 a gallon, we proceed thus: x 3= 334.3788, and y 334.3788 = 
 
 4 
 
 6.99, the diameter of a cylinder to hold 3 quarts. Then 6.99 X 3. 141 6 — 
 21.9597, the length. Now, 7.6394 : 7 :: 6.99 : 6.40 — that is, the sheet 
 for a 3-quart saucepan would be nearly 22 inches long and 6^ wide. 
 
 Copper saucepans, Fig. 161, were made in sizes to hold from 1 
 pint to 4 gallons. Pudding pots, Fig. 162, from 3 to 6, and sometimes 
 as large as 8 gallons. As the work of making plain saucepans and 
 round pudding pots is the same, excepting a little variation in the 
 shape, we will make one to hold 1 gallon ; the other sizes being made 
 in the same manner. It will be seen from an inspection of Fig. 161 
 that a 1 gallon saucepan is the frustrum of a cone with the base 
 turned in, forming at that point almost one-half an oblate spheroid. 
 The brazier's measurement of a gallon saucepan is taken from lag to 
 brim, as shown in Fig. 164, and should measure 9^ inches. (The 
 writer has one made by himself in the year 1856 which was in con- 
 stant use up' to 1872, and is apparently as good as when new, if re- 
 tinned and made fit for use. This old relic measures 7 inches in 
 diameter at the brim, 6% inches deep, 7% inches at the lag, from lag 
 to brim 9^ inches, and at the swell or belly, 9 inches. It is made 
 from 16-pound plate, with No. 6 wire.) The body for a gallon sauce- 
 pan is cut 24 inches long and 7 inches deep, and may be made from 
 12 to 18 pound plate. The pattern is to be formed and the seam made 
 as previously described ; then divide the depth into three parts, as 
 shown in Fig. 165, and with a mallet proceed to raze in a course a 
 third from the end, as at a ; now turn it end for end and raze in a 
 course, Fig. 166, b, on the other side of the same line we started from 
 before, drawing in the side until it is 7 inches at the top, and about 
 1%. inches at the bottom. Then stag in the lag y 2 inch, Fig. 167, 
 partly on head and finishing on a bottom stake, and thinning the edge 
 on a bullet stake ; cramp and put in the bottom B, braze the seam, 
 clean it off, knock down, and anneal ; then true it up on a long head, 
 from the swell to the brim, and turn the edge for the wire. Now true 
 
ART OF COPPERSMITHING. g X 
 
 up the lag and beige on a suitable round head, and it is ready for the 
 pickle tub and annealing, after which it is scoured bright and dried 
 in the sawdust box. It is now to be put into its final shape and 
 planished all over one course, beginning with the bottom, and next 
 the sides ; then tin it inside with pure tin. After being tinned and 
 scoured clean, it is planished again, this time on a suitable bright 
 head, and smoothed ; then the wire is put in and handle riveted on. 
 The cover is next in order ; the rim of the cover is made slightly 
 flaring, and the top pitched about yi inch ; then tinned and planished. 
 When the whole is complete, as in Fig. 161, it is scoured and polished 
 with oil and tripoli. 
 
 In making lipped aaucepans, Fig. 168, the work is done nearly the 
 same, excepting that while drawing from the beige to the brim 
 enough slack is left at the left of the seam to form the lip — that is, we 
 work around the lip, leaving the brim, as it were, egg shaped, as in 
 Fig. 169, until the planishing is completed and the wiring has been 
 done ; then the lip is put into final shape on an extinguisher stake. 
 The cover is made with a projection to cover the lip, but the rim is 
 round ; the handle is of wood inserted into a socket, as shown in 
 Fig. 168. Lipped saucepans are seldom made to hold more than 
 1 gallon. 
 
 Round pudding pots, Fig. 162, were made similar to saucepans, 
 but with a bail and ears and somewhat less m depth ; thus the body for 
 a pudding pot to hold 3 gallons was cut about 34 inches long and 8^ deep, 
 being worked up m the same manner as a round saucepan, only hav- 
 ing a bail and ears, as shown. The cover for pudding pot is shown in 
 Fig. 163. Oval pudding pots, Fig. 170, were made similarly and cut 
 the same size as the round ones ; both differed a little in shape from 
 the saucepans, the difference being in the beige or belly, which was 
 drawn in at the top and bottom alike. Let us make an oval pot to 
 hold 4 gallons, the body being cut from a 14-pound sheet, being 
 34 x sy 2 inches. The body is to be formed and seam made in the 
 usual manner, and the depth divided into three parts, as shown in 
 Fig. 165, the form of oval is indicated in Fig. 171, making it 12 inches 
 long. The sides are to be razed in at both ends until the beige has a 
 curve of about an inch ; then stag in the lag and put in the bottom, as 
 indicated in Fig. 167 ; true up the body to shape and roughly planish, 
 or run it over with a hammer. Then turn the top edge for wire and 
 tin, after which scour and dry ; then finish planishing and smooth on 
 
9 2 
 
 ART OF COPPERSMITHING. 
 
 a suitable head. Pitch the cover a good % inch and tin, then planish 
 it and put in the rim, which should be about i}& inch wide. Next 
 put on the ears, the rivet holes of which should be countersunk 
 enough so that the rivet heads may be drawn in and be flush and 
 smooth with the surface inside. The bail can be tinned or japanned, 
 as desired. 
 
 Fig. 171 — Plan of Oval Pudding Pot. 
 
ART OF COPPERSMITHING. 93 
 
 STEWPANS. 
 
 As previously stated, stewpans seemed to take the place of sauce- 
 pans in a great measure after their introduction, because they were 
 handier and more easily made; then, again, there were long and rapid 
 strides being made in the perfecting of cooking apparatus in general, 
 all tending to a complete revolution of culinary apparatus and methods. 
 The general progress in education and the advances made on every 
 hand were felt by the braziers, as well as others, and the surround- 
 ing influences compelled them, though a little reluctantly, to keep 
 pace with the advancing tide about them and acquiesce in the de- 
 mand for more tasty and shapely goods. An old-fashioned stewpan 
 is represented in Fig. 172. At first there seemed to be but little at- 
 tention paid to the symmetry of the parts; the handles were roughly 
 made, and apparently without any particular design, so long as it was 
 something to hold by; the flap was clumsily made, seemingly to get 
 as much weight into it as possible. The pan proper was the best 
 piece of work about it, and this, when compared with others of later 
 make, was poor enough, and directly resulted from the opposition to 
 any innovation or change from the old usages, and yet the work 
 on the old-fashioned pan m its way really required more skill than 
 those of a more recent date. The lag being made at first sharp or 
 square, many an otherwise good piece of work has been spoiled in the 
 finishing by being cut through, or nearly so, on the sharp edge of the 
 old-fashioned bottom stake. This was at last obviated by making the 
 lag round, thus adding beauty to the pan and at the same time over- 
 coming all danger of failure at this point. 
 
 Let us make a stewpan after the old-fashioned method, and then 
 show the difference between the old and new methods. At first they 
 were made in accordance with the taste of the master, or if it hap- 
 pened that he was not a practical man, then the workman was relied 
 upon to produce the best design he could; but later more attention 
 was paid to the wants of the cook, and stewpans have been made in 
 several styles to suit their demands — namely, shallow, medium and 
 deep. The shallow ones were one-half their diameter in hight, the 
 medium two-thirds and the deep as high as their diameter — that is, 
 
94 
 
 ART OF COPPERSMITHING. 
 
 
 
 ST 
 
 
 
 
ART OF COPPERSMITHING. 95 
 
 where attention was paid to the matter. There were, however, then 
 as now many different styles, which we will leave to the investigation 
 of the reader, the immediate object being to show him the manner and 
 means adopted to produce the pan, or the execution of the mechanical 
 part; so we will proceed to make one of medium hight to hold a gal- 
 lon. Stewpans were made light or heavy to suit the wants of the pur- 
 chaser, or to meet competition in price; generally they were made 
 heavy. Let the example be made from a 30-pound plate, and of me- 
 dium hight. The dimensions of a stewpan to hold 1 gallon are found 
 in the following manner : A gallon of water (English) contains 
 277.274 cubic inches, and the pan is to be two-thirds of its diameter in 
 
 277 274 
 hight. Then x 3 = 415.91 1, the cubical contents of a cylinder 
 
 as high as its diameter. Then converting this into cylindric 
 
 inches, we have - — '—-— = 529.553, and extracting the cube 
 
 root of this we get y 529.553 = 8.089 for the diameter, and as 
 
 the pan is to be two-thirds of this, — '- — - x 2 = 5.392, the hight of the 
 
 pan inside measurement, to which add the thickness of the metal, 
 and we have 5^ inches for the hight, and 8 inches the diameter, ap- 
 proximately. Then the dimensions of a stewpan of medium hight 
 to hold a gallon would be 8 inches in diameter, and 5^ inches deep 
 when finished ; therefore our pattern requires to be 25^ inches long 
 and 6 inches deep, allowing T / 2 inch for lag. Cut out the pattern 
 cramp it with a chisel and thin. (For the benefit of the learner I will 
 here state that it is the custom among braziers to cut their cramps in 
 heavy metal before thinning ; coppersmiths on the other hand do the 
 thinning first, and cut the cramps after, and both ways have their 
 advantages in particular cases which practice alone can teach and 
 point out). Now form it and braze the seam as previously described ; 
 clean off and knock down ; then stag in the lag, and thin the edge 
 ready for the bottom ; put in the bottom and braze it round ; trim 
 and knock down the seam ; anneal, and true up to size. The 
 lag being carefully formed on the heel of a suitable head, as in Fig. 
 174, it is now ready for the tinning. When tinned and scoured, it is 
 first planished on a bright bottom stake, making the bottom level and 
 true, and then the sides on a bright head in a shank, the smoothing 
 being finished with a spring-faced hammer. The sides and bottom 
 
96 
 
 ART OF COPPERSMITHING. 
 
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ART OF COPPERSMITHING. 97 
 
 completed, the lag was finished up square with a hammer, as shown in 
 Fig - . 175, and here is where the failure came in usually, by the lag be- 
 ing cut through, or nearly so, at this point. The covers were first 
 pitched with a square corner, as shown in the top illustration, Fig. 
 176, the seat being turned with the long face of a coffee pot hammer, 
 Fig. 177, and finished with a planishing hammer on the anvil, shown 
 in Fig. 176. The work on the improved pan would be the same up to 
 this point, the difference being in forming the lag round on the heel 
 of the head, Fig. 178, it being made round and suitable for the pur- 
 pose. This in time was superseded by a lagging machine, upon which 
 dies or wheels (similar to a double seamer) of various sizes could be 
 placed suitable for all kinds and sizes of pots and pans whose sides 
 were made straight or parallel. The covers were also treated in the 
 same way as the lag of the pan. About this time the burring machine 
 was introduced tor turning the seat of the cover and a few other pur- 
 poses, and for a wonder it was received without much opposition. 
 
 The tinning of these improved pans was carried down on the out- 
 side from 1 inch to i^ inches, according to the size of the pan, and 
 was done as follows : The distance it was required to tin down, the 
 side being determined, it was then marked off, and some wet whiting 
 or black and size (plumber's soil) was carefully smeared on with a 
 brush around and up to the mark, to prevent the tin from adhering 
 further than the mark, and to keep it true to it. It was then im- 
 mersed in a pan of liquid tin, Fig. 179 ; a clamp was then-applied, and 
 while the operation of tinning was being proceeded with, inside the 
 outside tinning was wiped off smooth and completed at the same time 
 The planishing was performed as before described, only the lag was. 
 carefully rounded with a mallet, and burnished to correspond with 
 the other finish. The handles were lighter > more graceful, and formed 
 so as to be placed nearly in the center of the side; the flaps were of 
 a triangular shape a/id light, Fig. 173 B, which gave the article a 
 much more finished appearance, and displayed more tasty workman- 
 ship. There seems to have been no- deviation made since either in 
 the pans or their handles, or none to my knowledge. The old style 
 handle and flap is shown in Fig. 173 A. When the pan and cover are 
 finished, the handle of the cover is put on first, and then the handle 
 of the pan. This rule is observed to insure both handles being close 
 and in a line with each other, so that the cook could grasp both han- 
 dles together when necessary to move them about while in use. 
 
ART OF COPPERSMITHING. 
 
 Fig, 179. — Process of Tinning Rim Outside. 
 
ART OF COPPERSMITHING. 99 
 
 STOCK POTS. 
 
 Stock pots were made in several sizes, from 9 to 20 inches in 
 diameter. The smaller sizes were from 9 to 12 inches in diameter 
 and the larger from 13 to 20 inches. They were fitted with pipe and 
 inside grating when required, as shown in Figs. 180 and 181. The 
 work of making stock pots is the same as that of large deep stew 
 pans, excepting that the cover is made to fit on over the outside, and 
 deep enough to be used as a cutlet pan, the pot and cover being 
 mounted with cast copper handles as shown. Stock pots are a good job 
 when made well, and are usually given to old and experienced hands, a 
 young man seldom getting a chance at them. I was never called on 
 to make one, but have noticed that the tools and appliances used in 
 their manufacture were not adapted to the job, and it is a little sur- 
 prising that such good work was produced by their use. I will de- 
 scribe the making of one of the stock pots of medium size, to hold 8 
 gallons standard or American measure, and made from 40 pound 
 plate, and as high as its diameter. The American or United States 
 gallon contains 23 t cubic inches, and the pot is to hold 8 gallons; 
 then 231 x 8 = 1848 inches, and converting these into cylinderic 
 
 T o . o 
 
 inches we have- — - — = 2352.941, and extracting the cube root we get 
 13.3, the diameter, and 13.3 x 3.1416 = 41.7832, the cir- 
 
 4/235 2 94i 
 
 cumference, or length of the pattern, and 13.3, the depth. Add to this 
 y± inch for lag and we have 13.3 + .75 = 14.05, or a piece of cop- 
 per 3 feet 6 inches by 14 inches for the pattern. Cut this out, cramp 
 and thin; then braze the joint, trim, knock down and anneal; then 
 put in the bottom and braze the seam. 
 
 When a boy I saw my father working on these pots occasionally 
 and dragging them about on the forge with a pair of tongs, and have 
 often wondered since how it was that the old braziers never adopted 
 the plan or seemed to think of putting their heavy work in a sling; 
 for after working some years among railway and marine work I re- 
 turned to some of the old shops to work again and found that there 
 had been but little progress made. The same old methods were still 
 
IOO 
 
 ART OF COPPERSMITHING. 
 
 Fig. 1 80. — Stock Pot. 
 
 Fig. 181. —Inside Grating for Stock Pot. 
 
 4 
 
ART OF COPPERSMITHING. IOI 
 
 in use, and to introduce any new ones was almost certain to bring one 
 into contempt, particularly if there was any large number of men 
 employed. 
 
 But to proceed. True the bottom on a square shank, using a suit- 
 able head and carefully keeping the turn of the lag round and as large 
 as the head will permit ; when this is completed, raise up the cover. 
 This cover is raised from a disk, the size of which may be obtained as 
 follows : Let the cover for this size be 2 inches deep, and its diameter 
 13^3 inches, so that it will fit easy ; then, 13.375 X 3.1416x2 = 84.0378, 
 converting this into circular inches we have 84.0378 -*- 0.7854= 107. 
 Now square the diameter of cover, or 13.375, and adding this last 
 result (13.375) 2 + 107 — 285.890625, and extracting the square 
 
 root we get y 2&5.S90 = 16.9 or 17. Raise up the cover to fit the 
 
 pot, tin them both, planish and smooth ; then put on the handles, 
 those on the cover first, then on the pot, placing them in such a posi- 
 tion that they will pass each other when being turned around on the 
 pot. 
 
102 ART OF COPPERSMITHING. 
 
 FISH AND TURBOT KETTLES. 
 
 Fish and turbot kettles were made shallow and similar to stew 
 pans. The work being of the same nature, a general description Of 
 them will avoid unnecessary repetition. There seems to have been 
 one size for turbot kettles. They were made of light copper and of a 
 suitable shape for the fish they were named after, they were about 
 5£ inches high and wired at the brim ; the handles were 
 placed at the two furthest corners ; the cover was pitched about ^ 
 inch, similarly to a stew pan cover, as shown in Fig. 182. The inside 
 was supplied with a perforated fish plate, Fig. 183, having two lugs or 
 handles with which to lift it out ; the plate was tinned on both sides, 
 planished bright, and then wired around the edge. The fish kettle, 
 Fig. 184, was made oblong, with circular ends and straight sides, and 
 about the same depth as the turbot kettle, and supplied with a fish 
 plate, Fig. 185. Any workman who is skillful enough to make a good 
 sauce pan may be trusted with the work of making either of these 
 kettles without fear of failure. 
 
ART OF COPPERSMITHING. 
 
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 BRAISING PANS. 
 
 The body of a braising pan, Fig. 186, is similar to a fish kettle 
 except in shape, which is nearly a true ellipse; the pan, which is about 
 6 inches deep, is made strong and without wire. The cover is a diffi- 
 cult piece of work and requires more skill, as will be seen by referring 
 to Fig. 187. Let us make a cover, and let the kettle measure 15 inches 
 
 long and 11^ wide; then the circumference is — ' x 3.1416 = 
 
 2 
 
 41.626. Now, the outside case or pan of this cover at a, Fig. 187, is 
 about 3 inches deep, and the wire, No. 6, would require another y z inch 
 to cover it. The rim b which covers the kettle is 1 inch deep; add 
 a quarter for seat and an eighth at c to turn on the inside to keep the 
 cover proper in, the cover proper forming the bottom of the real 
 braising pan. We then have for the width of the outer rim Y* + 3 
 + }i + 1 + }£ = 4%- The strip, then, to form the upper pan of this 
 cover would be 41^ inches long and 4^ wide. Cut it out, bend 
 round and braze the joint; trim the seam, knock it down and anneal; 
 take in a course on the head secured in a square shank, as shown in 
 Fig. 188, until the size at x z, Fig. 187, is a good % inch smaller all 
 round than the cover M; now turn it up and work down the seat dvtith 
 a mallet on an anvil, Fig. 189, and bring up the narrow rim to fit the 
 rim of the cover M, Fig. 187. Next raze out the upper part or flare 
 evenly all around until it measures 16 l A inches the long way, and 
 turn the edge for the wire; now make the cover M and tin it inside 
 and scour clean and fit the cover to the rim, planish and smooth both; 
 then put in the wire, set the cover in the seat tight; then turn the edge 
 of the outside rim over it, as shown at c, which finishes the cover or 
 real braising pan. Finally put on the handles and clean. 
 
ART OF COPPERSMITHING. 
 
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 ART OF COPPERSMITH ING. 
 
 Pig. 189.— Working Down the Cover Seat. 
 
ART OF COPPERSMITHING. IO7 
 
 TEA BOILERS. 
 
 Tea boilers, as shown in Fig. 190, were made 40 years ago, to fur- 
 nish a reservoir of warm water, as well as to provide for boiling a 
 larger quantity than the common sized tea kettle would hold. They 
 generally stood on the hob of the fire place, and as close to the fire as 
 was convenient, this gave place to the hob boiler, when the kitchen 
 range was introduced, which cut off much of the brazier's work ; but 
 they are still made and used occasionally in the rural districts of 
 England. The swivel in the bail served to hang it by, where there 
 was a bar in the chimney on which to hang the pot hook and rack, 
 Fig. 191, the loop being made to hang on the teeth of the saw shaped 
 plate, by which to raise and lower the hook on which the boiler hung 
 by the swivel in its bail. Tea boilers were made from about the 
 same weight of copper as the larger tea kettles, and to hold from 2 to 
 S gallons, advancing in capacity y 2 gallon with each size, making 
 nine sizes in all. We will make one to hold 4 gallons. Tea boilers 
 were made of a cylindric form, as shown in Fig. 190, the same depth 
 as their diameter, hence a boiler 12 inches in diameter would be 12 
 inches deep. To find the .size of the pattern or sheet to make a 4-gallon 
 boiler we may proceed as follows: Four gallons (English) contains 
 277.274 x 4 = 1109.096 cubic inches, and converting these into 
 cylindric inches we have 1109.096 -*- 0.7854 = 1412. 01426, and extract- 
 ing the cube root of this we get |/ 14 12.01426 = 11.25, or 11^ inches. 
 Then 11.25 X 3.1416 = 35.343, or 35^ inches for the circumference. 
 As the depth is i\% inches, add to this ]/ 2 inch for the lag, and 
 }( inch for edge to seam on the top ; then the pattern will be 35^6 
 inches long by 12 inches wide, and made from 12-pound plate. Cut 
 out the pattern, cramp, thin, form round, and tie with wire to hold 
 while making the seam, Fig. 192, after which anneal and put in 
 the bottom as previously directed. True to size, and run over the 
 body with a hammer to stiffen it, and turn the edge for 
 the top. The breast, cover and pipe are next in order. The 
 breast has a rise or pitch of one-third, and the rim for the 
 cover, from % to 1% inches deep, finished, according to size — that is, 
 
ioS 
 
 ART OF COPPERSMITHING. 
 
 Fig. 190. — Tea Boiler, 
 
 Fig. 192. — Body and Bottom of 
 Boiler. 
 
 Fi°-. 193. — First Method of Forming- 
 lea Boiler Breast. 
 
 Fig. 191. — Pot Hook and Rack. 
 
ART OF COPPERSMITHING. 
 
 109 
 
 
 
 3 a. 
 
HO ART OF COPPERSMITHING. 
 
 after being wired. Now, the breast or top may be made in several 
 ways — namely, first, hollow it up and pitch the ring, as in Fig. 193, 
 which is done in this way: After the ring is made and wired, take a 
 creasing hammer and then sink the bead in a creasing stake, as shown 
 in Fig. 194, and after putting the collar through the hole, as in Fig. 
 193, turn the edge back, and close the bead and edge down close to the 
 top at one and the same time. Second, the top maybe cut out flaring 
 or conical, as shown in B, Fig. 195, and the ring partly formed before 
 the seam is made. The cone is shown by A B C, and the pattern and 
 ring by xy z, m nj the distance around the pattern x y z being six 
 times the radius A D of the finished cone ABC. Cut out the pattern, 
 cramp, thin, and then work out the collar or ring on an anvil or table 
 of the side stake ; then braze the seam, finish the ring and wire. 
 Third, cut out a disk so that its surface is equal to the breast and 
 ring before wiring ; wrinkle it, as in Fig. 196, and form the 
 ring O P, making the opening about 5 inches in diameter 
 and the required depth, and then work out the wrinkles ; this can be 
 done in one course, if necessary, and in as little time as either of the 
 preceding methods, and is a much nicer job when finished ; now tin, 
 planish, and wire. The cover is made in the same manner as are 
 those for saucepans, and which has been previously explained. The 
 pipe for this size should be about 7 inches long, 1% inches in diam- 
 eter at the large end and to fit the faucet at the other. Cut out the 
 pattern and make a cramp at each end, Fig. 197, and lay the edge 
 close, when turned ready for brazing, then braze. Tin the inside of 
 boiler, pipe and cover, then pitch the pipe for collar, similar to a tea 
 kettle spout, and work out the collar in the side of the boiler about an 
 inch from the bottom, to fit the pipe, as in Fig. 198 ; then brown the 
 boiler, planish and smooth it ; next put in the pipe and double seam 
 on the top ; put on the ears, bail and finally clean. 
 
ART OF COPPERSMITH I NG. 
 
 II I 
 
 Fig. 198. — Separate Parts of Tea Boiler. 
 
 Fig. 197. — Pattern for Pipe. 
 
112 ART OF COPPERSMITHING. 
 
 WARMING PANS. 
 
 Copper warming pans were once quite largely in demand, and 
 kept men bus)r at work for a considerable' time during the year, as 
 almost every household, rich or poor, possessed a warming pan, and it 
 is presumed it would be a difficult task to-day to find a house in the 
 rural districts of England without its warming pan, many of them 
 having been handed down from father to son for generations. Warm- 
 ing pans are made or raised up and formed from a disk whose 
 surface is equal to the surface of the pan and the cover seat, together 
 with the covering of a 5-16 wire. They are wired as in Fig. 199, 
 though they have been made so that the cover fitted into a yk rim 
 turned up on the pan, as in Fig. 200, and left without wire, but in such 
 a case they must be made stronger, the joint of the cover being riv- 
 eted to the socket, as shown. They were made in five sizes — namely, 
 10, ioVz, 11, 11 y 2 and 12 inch. Let us make one to measure 11 inches, 
 and from 10 pound plate (the plate or brazier's sheet, by which the 
 strength was designated, measured 2 feet wide by 4 feet in length), 
 and let it measure at the lag 1% inches less than at the brim, as in 
 Fig. 201. Our first move is to get the size of a disk equal in surface 
 to the pan thus represented ; first the ring a, which is to cover 
 the wire; then the cover seat b ; next the sides of the pan c y 
 and then the bottom of the pan d ; these are all shown 
 separately in Fig, 202. This is probably one of the best 
 lessons in the trade for a boy (or man either) who desires to be fa- 
 miliar with the art of measuring and converting surfaces into forms 
 suited for the work in hand. It will be seen by referring to Fig. 202 
 that there are four different problems involved in this calculation, 
 — namely, the cylindric ring a, the disk ring b, the flaring ring c, and 
 the disk or bottom d. Now we want to reduce these four 
 problems to one form or denomination — that is, to one 
 disk whose surface shall equal the whole of them taken to- 
 gether. First, the cylindric ring #, to cover the wire, 13^ inches 
 in diameter and an inch deep ; then 13.5 x 3.1416 x 1 = 42.4116 square 
 inches. Next the disk ring b, whose outside diameter is 13^ inches 
 and inside diameter 11 inches; then 13. 5 2 — 11 = 182.25 — 121 = 61.25 
 
ART OF COPPERSMITHING. 
 
 113 
 
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 ART OF COPPERSMITHING. 
 
ART OP COPPKK SMITHING. 115 
 
 disk inches. Now, the opening of the pan c at the brim will equal 11 
 
 inches, and at the bottom g}4 inches, and 3. inches deep; then 11 +9.5 
 
 -s- 2 x 3. 1416 X 3 = 96.6042 square inches; and last, the bottom d, which 
 
 is g}i inches in diameter; then q.y = 90.25. Now we must reduce 
 
 the surface of the flaring ring c and the cylindric ring a s which are now 
 
 represented in square to disk inches, and to do this we add them to- 
 
 ,1 -.-■••-., ■, 96.6042 + 42.4116 
 gether and divide by 0.7854; then, — — - = 176.987, and 
 
 adding these disk inches to those of the disk ring b and the bottom d 
 we have 176.987 + 61.25 + 90.25 =?= 328.487; and then extracting the 
 
 square root of this last result we get 4/ 328.487 = 18.124, which 
 
 will be the size of the disk for our pan. Cut it out, smooth 
 the edges and describe the bottom d, as in Fig. 203, and start 
 a course with a mallet on a suitable long head in a square shank, 
 then take a razing hammer and raze down the wrinkles, working 
 nrst on one side of the wrinkle and then on the other, then on the 
 front of it, and continue until all the wrinkles are worked out and the 
 rim has the measure of 13^ inches, as in Fig. 205, annealing at the 
 conclusion of each course. Now work it up until the pan proper is 3 
 inches deep, and measures 11 inches across the brim, as in Fig, 206. 
 Then take it on an anvil, or the table of a side stake, and with 
 a mallet raze down the cover seat or flange B, Fig. 201, leaving the 
 edge of the w T ire standing, while the seat is brought down to its 
 proper width, or 1 % inches wide all around, then anneal. Now true it 
 up to size and shape, then planish and put in the wire. The cover and 
 socket are next in order ; the cover is pitched about J / 2 inch deep and 
 wired on the edge, and a few small holes punched in it, as shown in 
 Fig. 207 ; then planished and smoothed, leaving the cover raised or 
 hollowed, and the bottom a little also, so that it will slide smoothly 
 between the bed clothing. The cover joint, Fig. 208. may be hung on 
 the wire of the pan, as in Fig. 199, or separate and riveted on the 
 socket, as shown in Fig. 200. Now hang on the cover and rivet on the 
 socket, Fig. 209, and put in the handle, which is usually about iy 2 
 inches in diameter and 5 feet long, turned from some nice looking 
 wood and oiled ; then clean with tripoli and oil, and polish wich the 
 dry powder. 
 
n6 
 
 ART OF COPPERSMITHING. 
 
 Big. 207. — The Finished Warming Pan. 
 
 Fig. 208. — Cover Joint. 
 
 Big. 209. — Socket f ot Handle. 
 
ART OF COPPERSMITHINC2. 
 
 II 7 
 
 PRESERVING PANS. 
 
 Preserving pans, Fig. 210, were made in sizes ranging rrom about 
 9 to 18 inches. These pans, like warming pans, have been kept and 
 cherished as heirlooms, passing from one generation to another, and 
 when made strong are very durable — with careful usage they may be 
 m good condition at the end of, a century. Preserving pans are 
 raised up from a disk similar to warming pans, and usually wired 
 with a heavy wire; the pan should be strong, too; therefore let our 
 pan be made of 20-pound plate and 15 inches at the brim, 14 at bot- 
 tom and 4j£ inches deep, including the wiring edge; then a disk 
 whose surface is equal to the surface of the pan is found thus : 
 
 — - x 3.1416 x 4.5 = 204.9894. Converting this into disk inches we 
 
 have — ' ' = 261, and adding this to the square of the bottom we 
 0.7854 
 
 have (14) 2 + 261 = 457, and extracting the square root of this last 
 
 result we get V4T7 2 = 21.377, or 21^8 inches nearly, for the disk to 
 
 make our pan of. Preserving pans are made in the same way as 
 
 warming pans, described in the previous chapter. The first step is 
 
 to mark the side of bottom on the disk and the second to form the 
 
 side wrinkles for razing. When razed up to the proper hight turn 
 
 the edge for wire, as in Fig. 211, and then planish and smooth, being 
 
 careful tc have the bottom level; the sides usually beige a little from 
 
 the bottom up. Finally, put in the wire and clean up with tripoli 
 
 and oil and then put on the handles. 
 
 Fig. 211. — Pan Turned for Wire. 
 
 Fig. 210. — Cotoper Preserving Pan. 
 
Il8 ART OF COPPERSMITHING. 
 
 DRIPPING PAN AND LADLE. 
 
 Dripping pans, represented in Fig. 212, which we will now con- 
 sider, are utensils probably as old as any in the trade, and which are 
 in almost daily use in all the old manor houses and baronial halls of 
 England. Their name is suggested by the use to which they are 
 put — namely, to catch the drip from large joints of meat while they 
 are roasted before the kitchen fire, the spit upon which the joint 
 revolves being turned by a chain from a smokejaek. These pans are 
 considered a good job, and, like stock pots, are usually made by old 
 and experienced hands, or men who have been some time in the 
 employ and have gained the confidence of the employer, and are of 
 known and tried ability ; apprentices rarely have an opportunity to 
 try their skill on these. Dripping pans have been constructed in 
 several ways ; first, with the well in the center of the pan, or in the 
 middle of one end, as shown ; sometimes with legs fastened to the 
 pan ; at other times without legs, but made to fit in a frame with legs. 
 They are usually made in any case as large as the sheet will permit, 
 a sheet being 2 feet wide and 4 feet long, and the sides of the pan be- 
 ing turned up some 3^ inches and wired with a T % rod. The corners 
 may be made square and brazed in the corner, or cut to form a round 
 corner and brazed, or they may be wrinkled, and razed up solid, as may 
 seem most advisable, or as the taste of the employer or the purchaser 
 may require. We will make one to be 3 inches deep when finished, 
 having the corners round and brazed, as shown in Fig. 212. The pan is 
 shown bottom upward in Fig. 213. Let it be made of a common sized 
 sheet and of 20-pound plate, and wired with a T V rod, the corners to 
 be part of an 8-inch circle at the top and flaring at an angle of 120 
 at the lag. Now, this would make the corners what the old braziers 
 called " funnel fashion " — that is, if all the corners were joined to- 
 gether in one entire circle they would be in the shape of a funnel, of 
 6o° at the apex (see Fig. 218). Now, then, square the sheet as in Fig. 
 216, and mark off around the edge the depth of the pan (including the 
 edge for the wire), 3^ inches, drawing the inner lines parallel to sides 
 and ends of sheet. Then draw the line A C, and with G C, 2% inches, as 
 radius, describe the arc G M, which is the size of the circle of the corner 
 
ART OF COPPERSMITHING. 
 
 Iig 
 
 
 IfrBBS^ 
 
 
 IPS 
 
 MpS 
 
 t 
 
 7™ 1 
 
 JpPt 
 
 1 
 
 — 
 
 m 
 
 | 
 
 rfe- | 
 
 piajj|i|S 
 
 
 ^J 
 
 ^ 
 
 1; 
 
 a 1 - 
 
 b 
 
 I 
 
 a 
 
 s 
 a. 
 
120 
 
 ART OF COPPERSMITHING. 
 
 r^ 
 
 C5 (J 
 
 Fig. 216. — Pattern for Dripping Pan. 
 
 .'Fig. 2r7. — Diagram for Cutting 
 Corners. 
 
 Fig. 218. — Corners Bent to Funnel 
 Shape. 
 
ART OF COPPERSMITHING. 121 
 
 at the lag. Now look at the corner marked B. Draw the line 
 Y C, extending it to Z, also X C to W, making the distance in each 8 
 inches, and describe the arcs X V and Y U. (Every boy knows that a 
 half circle turned round and the ends joined will make a funnel.) 
 Then the circle in Fig. 217, which is intended to represent the four 
 corners of the pan brought together, will be 8 inches in diameter, 
 and to make a funnel this size it is necessary to have the half of a 
 circle with a radius of 8 inches, or 16 inches in diameter. Let the 
 circle, Fig. 217, be 8 inches in diameter; then N B D will be the half 
 circle with a radius of 8 inches. Divide the circumference into eight 
 equal parts; as D O, and make the distance X V and Y U in the cor- 
 ner B, Fig. 216, equal to O D, and draw the lines V W and U Z and 
 describe the arcs X V and Y U and P S and S I. Then cut out the 
 pieces V S U and P S I, and the pattern for one corner is complete. 
 Repeat the process at each corner. Cramp and thin; bend up the 
 sides; bring them together and braze the seams; now trim and finish 
 the corners and true up to size and shape, making the middle of the 
 pan sag from 1 to 2 inches, so the drip will flow to the well. If the 
 well be at the end then the pan may be made enough deeper at one 
 end, or the legs enough shorter, so the drip will drain to the well at 
 the end. Next turn the wiring edge, tin, planish and wire. The 
 well, which is next in order, is made about 9 inches in diameter and 
 formed like a basin, or half sphere nearly, as shown in Fig. 214, with 
 flange 3^ inch wide to rivet to the bottom of pan. The strainer 
 ring and cover are made to fit tight inside the well. The ring 
 is about 2 inches deep and goes into the well about )4 inch; 
 there are also slits, as shown, made at intervals of about 2 inches all 
 around, so that no cinders may find their way into the well. When 
 the well is made and tinned inside, and the ring and cover are tinned 
 all over and ready, put in the well and scrub the rivets so the surface 
 is smooth; now put the ring into the well tight and soft solder to its 
 place. The ladle, as shown in the pan, Fig. 215, always accompanies 
 the pan; it is made about 4 inches in diameter, and with the bottom 
 like a shallow cup, the top being full of small holes to answer for a 
 strainer. The ladles are tinned inside and out. The handle is made 
 of iron and from 20 inches to 2 feet long, with a hook at the end 
 by which to hang it. 
 
122 ART OF COPPERSMITHING. 
 
 COAL SCOOPS AND COAL HODS. 
 
 Bright copper coal scoops have been considered an adornment for 
 the parlor, as well as a necessary accompanying adjunct for the fire- 
 side, as long probably as any article which has been wrought out from 
 this sheet metal. There has been called out in their production as 
 much art and painstaking care, perhaps more, as in any other thing 
 upon which the brazier has been called to exercise his skill. They 
 have also unconsciously furnished a stepping stone or preparatory 
 course for the perceptive and studious beginner at the trade. In the 
 manufacture of the various kinds of coal scoops which have been in 
 use up to the present time, scope is given for the execution of some 
 of the prettiest work of which the workman, under ordinary every day 
 necessities, is called on to perform, and, furthermore, they must give 
 much satisfaction to the zealous worker for the labor bestowed. 
 These goods may be made by a skillful workman in any shape to suit 
 the taste and please the fancy of the most fastidious. They furnish 
 sometimes for boys, or young men who are approaching the end of an . 
 apprenticeship, an opportunity of becoming proficient in the use of 
 a hammer. There is, however, little profit in coal scoops ; that is, in 
 those ordinarily in use, for they were among the goods which were 
 paid the least for, considering the labor necessary to produce them in 
 such a maner as the purchaser desired. On this account men sought 
 the assistance of a good careful boy when the opportunity offered, 
 and in this labor a pathway was opened for the boy which was closed 
 in other instances where better wages were given for the work. 
 
 Coal scoops were made in a number of fashions, among which, 
 besides the common hod, Fig. 2ig, were the round mouthed scoop, in 
 Fig. 220; the square mouthed or flat bottom, Fig. 221; the Tudor, Fig. 
 222 ; the Florence, Fig. 223 ; the Nautilus, Fig. 224 ; the Royal, Fig. 
 225 ; the Boat, Fig. 226 ; and the Helmet, Fig. 227. In Fig. 228 is 
 shown a round bottomed scoopet and in Fig. 229 a fiat bottomed scoopet. 
 Some of these names are variable, according to the factories in which 
 they are made, while others have had the same name from the time 
 they were first designed. The hod has always been a hod, and the 
 common round mouth shape, as in Fig. 219, has never received any 
 
ART OF COPPERSMTTTTTNn. 
 
 f23 
 
 Fig. 219. — Com Dion Coal Hod. 
 
 Fig. 221.— Square Mouthed or Flat 
 Bottomed Coal Scoop. 
 
 Fig. 220.— Round Mouthed Coal Scoop. Fig. 222. — The Tudor Coal Scoop. 
 
124 
 
 ART OF COPPERSMITHING. 
 
 Big. 223.— The Florence Coal Scoop. Fig. i2\.— The Nautilus Coal Scoop. 
 
 Big 225.— The Royal Coal Scoop. Big. 226.— The Boat Coal Scoop. 
 
ART OF COPPERSMITHING. 1 25 
 
 other cognomen ; the same with the helmet scoop, Fig. 227, which has 
 always been wrought. The same and will probably continue to be, 
 while the metal is used for this purpose. 
 
 We will now endeavor to describe the manufacture of several 
 scoops in which we participated some forty years since, and while 
 there have been deviations made during this long time, judging from 
 late observations, it would seem that nothing of any marked importance 
 has been introduced to inconvenience one from resuming work as of 
 yore. The hod seen in Fig 219 is of a cylindric form, the mouth be- 
 ing shaped in front similar to one-half an elbow as far as the ears, 
 while the other half curves or returns up a little at the back, perhaps 
 \% inches. Let us cut out and then work two of these hods 
 bright, and let them measure 12 inches in diameter, and from the front 
 of the lip to the bottom, 18 inches, and 13^ inches at the back, or let 
 ABGLK,in Fig. 230, represent the outline of the proposed hod, of 
 which C D F H is the plan. To describe the shape of the top of 
 hod, from A to B would be about 56 . From the point E, which is 
 midway between M and H, on the line A H, with E B as radius, de- 
 scribe the arc B G, which completes the shape of top. To outline the 
 pattern, divide the semicircle CDF into any convenient number of 
 equal parts, in this case six. Lay off the distance O P, equal to the 
 circumference of the circle C D F H, which divide into twice the num- 
 ber of parts, as the semicircle C D F,and erect the parallel lines 1, 2, 3,&c. 
 Place the blade of the T-square at right angles to A K, or, which is 
 the same, parallel to the stretchout line O P, and bringing it succes- 
 sively against the points in A B G, cut the corresponding measuring 
 lines, as shown. Then trace the curved line S I J through the points 
 of intersection, which will give the form of the top or mouth of the 
 hod. Now cut out and scour bright with sand, vitrol and water; 
 rinse in clean water and dry in sawdust, and then remove the saw- 
 dust; clean and place two together and dog them so that they will be 
 held fast; then with a planishing hammer weighing about 4 pounds, 
 proceed to a bottom stake or an anvil; planish the surface in regular 
 blows, lengthwise or crosswise as is most practical, so long as the 
 surface is treated regularly all over and not in a promiscuous way. 
 When the surfaces have been covered entirely, take them apart and 
 scour the hammered side with sweet oil and tripoli, and then polish 
 with the dry powder, being careful that all dust and oil are removed. 
 When this has been done go carefully over each one singly again 
 
126 
 
 ART OF COPPERSMITHING. 
 
 Qq 
 
 ^ 
 
 
 ^ 
 ^ 
 
ART OF COPPERSMITHING. 127 
 
 with a smoothing hammer. When this coarse is completed, wire, 
 form on a former, grove together, and then bottom. The back 
 handle is of cast copper, filed and burnished; the cross handle or 
 bail is of ^4-inch pipe, filled and bent, then filed and burnished. The 
 ears may be cast or wrought, and should be made so the bail will lay- 
 on the wire at the sides, but leave room for the fingers in the loop, so 
 that the handle may be grasped with ease. When the hod and both 
 handles are ready give the hod its final clean up, and rivet on the 
 handles the last thing. 
 
128 ART OF COPPERSMITH I NG. 
 
 MAKING COAL SCOOPS. 
 
 The plain round-mouthed coal scoop, as shown in Fig. 220, is made 
 in four pieces, the bottom H and bridge B being shown separately in 
 Fig. 231. The sheet and wire from which the bridge is made are 
 shown in Fig. 232, while the foot is shown in Fig. 233. Let us work 
 up two of these plain scoops, as shown in Fig. 220, and let them meas 
 ure 15 inches when completed — that is, 15 inches from the back inside 
 to the front of the mouth. Our rule for this particular kind of scoop 
 was that the width should be four-fifths of its length ; hence the width 
 of our scoop across the bridge B or back (see Fig. 235) would be 12 
 inches from X to Z. The bridge itself was one-third the length of the 
 scoop in width when finished, or 5 inches, and the bottom of foot C, 
 Fig. 233, one-half the length of the scoop in diameter ; therefore, the 
 foot C would be 7 y z inches in diameter when finished. 
 
 We will first describe the pattern for the bottom or body, H, Fig. 
 231, as shown in Fig. 234, which from E to F, including %. inch for 
 wiring edge and }£ for back edge, is 15^ inches, and from C to D is one- 
 half the circumference of a 12-inch circle, with the wire edge added ; 
 
 that is, C D = 0.5 + — ^— — = 0.5 + 18.8496 = 19.3496, allowing j4 
 
 inch for wiring; then, with the radius H C, equal to one-half of C D' 
 (9.67 inches), or g^i approximately, describe the semicircle C F D 
 and extend the ends on each side parallel to each other to M N. Then 
 draw M N so E F will measure 15^6 inches, which gives the pattern, 
 of which two are to be cut. We nexi require the pattern of the back, 
 as shown in Fig. 235. The semicircle X Y Z would be 12 inches plus 
 the edges for seam, making 12*4 inches. The radii of arcs X O and 
 N Z is one-third of X Z, with the edge for seam added, making 4^ 
 inches. The radius of the arc O N is equal to X Z, with the edge 
 added, or 12^ inches. With S as center, describe the semicircle X Y Z 
 and divide the diameter X Z into three parts, as X P, P R, R Z, and, 
 with P X as radius, describe the arc X O, and, with R Z as radius, de- 
 scribe the arc N Z. Then, with P M equal to 8 inches, erect 
 the triangle P M R on P R, and, with O M as radius, de- 
 scribe the arc O N, and we have the pattern for the back. 
 
ART OF COPPERSMITHING. 
 
 129 
 
 ^ 
 
 J' 
 
 ba II 
 
 
 Ox, 
 
 ba 
 
 
 
 
 ^ 
 
 V 
 
 $ 
 ^ 
 
 bo 
 
 
 
 
I3O ART OF COPPERSMITHING. 
 
 The length of the bridge (see Figs. 231 and 232) is found as fol- 
 lows : It will be seen that the top part of the back is half an ellipse 
 whose transverse axis is 12 and conjugate 9 inches nearly ; then 
 the length of the bridge will equal one-half the circumference of the 
 
 i-i- ^ Q + 12 -. 10.5 x 3.1416 ... 
 
 ellipse 9+12 thus : z = 10.5 and — = 16.4934 ; to this 
 
 add a ^4-inch for groove and we have the length of the bridge, which 
 is 17 inches nearly. Let it be 17 inches long and 5^ wide, including 
 edge for wire and back, and we have the desired pattern. 
 
 The foot is a part of a cone of funnel fashion and cut obliquely 
 through the sides, as shown in Fig. 220. The scoop is set on the foot 
 in this way to tilt it up, so that any drip from wet coal may drain to- 
 ward the back rather than run out on the floor. In the foot repre- 
 sented at C, in Fig. 233, the riveting flange is turned inside, as shown, 
 but in the foot D (for an iron scoop) the riveting flange is laid off on 
 the outside, there being no flange in front or behind, and only enough 
 flange laid off to get three rivets in each of the flaps. 
 
 In order to obtain the pattern for the foot let E F G H, in 
 Fig. 236, represent the bottom of scoop and A B C D represent the 
 funnel or foot adjoining the same. The part of bottom of scoop 
 which joins the funnel, as X' L Z' is a semicircle struck from the 
 center S'. Produce A B and D C until they meet in the point Y, 
 thus establishing the apex of the cone. Draw the semicircle 
 R S T, representing one half of the profile of the cone at the 
 larger end or base. Divide R S T into any number of equal parts, 
 as indicated by the small figure 1, 2, 3, 4, &c. From the points thus 
 established carry lines at right angles to A D, cutting that line as 
 indicated. From the points thus established in A D carry lines 
 toward the apex Y, as indicated by the dotted lines in the engrav- 
 ing. The next step is to produce, the opening of the funnel, as it 
 would appear when viewed from a point opposite the end, or as in- 
 dicated by M N in the engraving. Lay off the straight line M N 
 parallel to the axis of the bottom, making it in length equal to A D 
 of the elevation. Transfer to it the several points produced in 
 A D by lines dropped from the points in the half profile R S T, 
 and through the points thus established draw lines at right angles 
 to M N, as indicated. Then, with the blade of the T-square placed 
 parallel with M N and brought successively against the points 
 in the line A D, cut corresponding lines drawn through M N. By 
 
ART OF COPPERSMITHING. 
 
 131 
 
 Fig' 2 35- — Obtaining Pattern for Back of Coal Scoop. 
 
 Fig. 236. — Elevation, Plan and Development of Pattern for Foot of Coal Scoop. 
 
132 ART OF COPPERSMITH! NT.. 
 
 this means half of the profile will be obtained, and from it 
 the other can be duplicated, giving the required shape. In 
 the same manner bring the blade of the T-square against 
 the apex Y in the elevation and cut the center line I 7, 
 thus obtaining the point X. Then, with a straight edge cutting X and 
 brought successively against the different points in the profile just 
 established, draw lines cutting the plan of the pipe, as shown by the 
 small figures to the left of L. Then, with the blade of the J-square 
 parallel with the axis of the bottom, and brought successively against 
 the points thus established in the plan, cut lines of corresponding 
 number drawn from the points in A D to the apex Y, or as indicated 
 from C to B. This done, we are ready to lay off the pattern. With 
 the blade of the J-square parallel to A D draw lines from each of the 
 points established between C and B, producing them until they cut 
 the line A Y, as shown. From Y as center, with Y A as radius, de- 
 scribe an arc, as indicated by U Z, and upon it step off the stretch- 
 out of the profile R S T, as shown, marking the points, as indicated 
 by the small figures. From these points draw radial lines to Y, 
 as indicated. Then, with Y as center, and with radii correspond- 
 ing to the points established in A Y, as already set forth, 
 describe arcs, producing them until they cut corresponding 
 numbered lines drawn from the arc Y Z to the point Y. Then a line 
 traced through the intersections thus established, as indicated by V 
 W, will be the pattern joining the cone, as shown in the elevation 
 from C to B. U V W X will be one-half of the pattern, and the whole 
 pattern may be obtained by continuing the same process, or by dupli- 
 cating. Allowance for joining to be made at U V, for wire on U Z and 
 for the flange on V W. 
 
 Having the four patterns, we are now ready to proceed. Dog all 
 the pieces together, two and two, and planish them the first course, 
 having previously cleaned them bright ; then take them apart, and 
 with a clean flannel wisp scour with oil and tripoli and polish with the 
 dry powder. Having carefully removed all oil and dust with a nice 
 soft, clean rag, go over them singly again to smooth and finish. We 
 are now ready to form and put the scoop together. First notch for 
 wire and groove ; then break the bottom on the former, Fig. 238, 
 by bending first one way and then the other, being cautious 
 not to rib it ; proceed slow and easy, carefully avoiding sud- 
 den bends. The former should be at least one-half the 
 
ART OF COPPERSMITHING. 1 33 
 
 diameter of the scoop. When formed, turn the wiring edge and wire, 
 letting the wire come within 2 inches of the notch on each side, and 
 leave the edge open at the end on each side to receive the bridge 
 wire. Now fold the grooving edge and wire the bridge, turning the 
 edge on the inside and sink the wire into a creasing stake, the 
 wire being left out 2 inches at each end of the bridge, as in Fig. 
 232, and bent to hook hold of the bottom (see B, Fig. 231), 
 and complete the wiring of the bottom. The wire of the 
 bridge should butt the wire of the bottom in the middle 
 of the ear. When this is done, groove the bridge to the bottom and 
 finish the wiring up to the turn of the bridge. Now double seam on 
 the back, then make the foot, which may be grooved together or riv- 
 eted, the wiring edge being turned on the inside, and the flange for 
 riveting to be about ^ inch, also turned on the inside. Now prepare 
 the back handles and bails, and clean all up, putting on the handles 
 the last thing. The loop for the scoopet should be about 2 inches 
 wide and riveted to the bridge, in which the scoopet is placed when 
 not in use. 
 
 The flat bottom scoop, Fig. 221, is made in nearly the same pro- 
 portions as the round mouth, Fig. 220, and the work is about the same 
 or similar in the most essential features, the difference being only in 
 its form, shown in the back, Fig. 239, which may be made either with 
 the sides of the bottom straight or curved to suit the taste, as in Y or 
 Z, Fig. 240. If the sides be straight, then the mouth is generally 
 square or angular, as in Fig. 221, but if they are curved, then from 
 the corner of the mouth to the ear it would usually be made curved ; 
 they may, however, be made either way without offending the eye, if 
 
 Note. — In an old shop I once saw and used a simple, yet effective, substitute for a 
 tilt hammer, which is shown in Fig. 237. A large block was made fast to the floor, and 
 an anvil some 8 or 9 inches square on the face set in it. There were four upright tim- 
 bers fastened to the floor and ceiling. The hammer, which weighed from 10 to 14 pounds, 
 was put on a long elastic handle, made of ash and having a sufficient spring to lift the 
 handle after the blow was struck. The shaft was bolted, as shown, to the two upright 
 pillars, and the hammer end of the shaft raised and made to work between two others, 
 as close to the hammer as convenient. One man or boy gave the blow while the other 
 manipulated the work under it. The block was of such a hight that a man could com- 
 fortably slide the sheet or work it about on the anvil, which weighed some 75 pounds or 
 more. The whole contrivance was considered a good tool then, and I have done, and 
 seen others do, some good work with it ; the blow when struck covered a space as large 
 as a half dollar. If a hammer like this were to be provided, the sheets could be planished 
 the first course before the work is cut out. 
 
134 
 
 ART OF COPPERSMITHING. 
 
 Fig. 237. — Spring Hammer for Planishing. 
 
 JO.//V. 
 
 Fig. 238. — Wooden Former. 
 
ART OF COPPERSMITHING. 135 
 
 the work is done well. We will mark one out and describe the varia- 
 tions which may be made in this class of scoop. Let it be required 
 that the scoop shall be 17 inches ; then, as the back of a 15-inch scoop 
 is 12 inches across at the bridge, 15 : 12 : : 17: 13.6 ; that is, 13.6, which 
 in practice would usually be called 13^. Now divide the distance a b 
 across the bridge into three parts, as in Fig. 239 ; that is, 
 
 i^ = 4.5. Then on c d, with c g equal to a d, erect the triangle c g d 
 
 and continue g d and g c to e and/; then with db as radius describe 
 the arcs bf and a e, and with radius g e describe arc ef; then draw b I 
 and a h parallel to d g and c g, and h I parallel to a b, 
 making a h equal \o c k and b I equal to d k. Then h a e bf b I 
 forms the back. If the side is to be curved, then with the radius a b 
 describe the arc b /, as shown by the dotted line, and the form of the 
 back is again complete. The bottom, Fig. 241, or body of scoop from y to 
 Tis 17 inches when finished; from w\.ox two-thirds of 17 or n T 3 o inches, 
 from w to u 6 inches, from u to v io^ inches, from the notch ^ to w 
 one-third of 1 7, or 5 T 6 . Join x P and n; then w T is the pattern for an an- 
 gular fiat bottom coal scoop. If the bottom be curved at the side, then 
 from the point q on the line y T, with q as radius, describe the arcs 
 shown by the dotted lines op and P s, and the pattern is indicated by 
 the dotted lines from to/ and from P to s. The bridge finished will be 
 
 5^ inches wide and one-half of x 3.i4i6,which is 18.0642, long 
 
 without the grooving laps and edges. The foot, Fig. 242, may bo 
 marked out as in Fig. 243, and will very nearly fit, but not near 
 enough. To meet this, in the absence of scientific knowledge, the 
 foot is formed and placed in position on the scoop and marked around 
 with a compass, and then trimmed to fit ; and this means often is 
 adopted in practice to save time, even when the knowledge is 
 possessed by the workmen. The Tudor, represented in Fig. 222, 
 and the back of which is shown in Fig. 244, will now be con- 
 sidered. By examination it may be seen that the measurements are 
 nearly alike. If the scoop is to have straight sides, then a hi b will 
 represent the bottom or body, and a e f b the bridge, taking 
 the dotted lines on each side as the shape. If the scoop is to 
 have the sides of the bottom or body as shown by the semicircle 
 a k b, then the bridge is again shown by a ef b, taking the solid line 
 area on each side as the shape. In these Tudor scoops the patterns 
 
136 
 
 ART OF COPPERSMITHING. 
 
 Fig. 239. — Back for Flat Bottom Scoop. 
 
 Fig. 240. — Bottoms with Straight and 
 Curved Sides. 
 
 Fig. 242. — Section through Foot. 
 
 Fig. 243. — Pattern for Foot. 
 
 Fig. 241. — Pattern for Bottom of Scoop. 
 
ART OF COPrERSMITHING. 137 
 
 tor the bottom were furnished to us ; the illustration will suggest the 
 shape of the sides at the mouth, which is variable, according to the 
 taste of the employer when he superintends the design. I may here 
 say that while these different styles have been frequently made and 
 were fashionable in their turn, I think, generally, those made easiest 
 and with the fewest corners or angles were most popular, aad gener- 
 rally took the best with the purchaser. The planishing is performed 
 as described in the previous article, and the forming suggests itself. 
 The scoopets were made similar and to correspond with the scoop, as 
 shown ; the scoopets were usually made one-half the length of the 
 scoop for this size, and 6% inches across the bridge ; that is, the 
 scoopets were about one-eighth the size of the scoop. They were 
 supplied with a socket and wooden handle, japanned, oiled or 
 polished. 
 
 The Nautilus is next in rank, and is represented in Fig. 224. In 
 this style of scoop the bridge is formed in such a manner that it sup- 
 plies one-half the back, which is razed down from the end of the bridge, 
 as it were, while the other half of the back is raised up from the bot- 
 tom or body. Now, these are a good job, and require altogether 
 another method for their construction than the preceding styles. 
 The back when complete, it .will be seen, is one-half a hollow 
 sphere, the bridge being a little in excess in the front, 
 to ornament or give a finished aspect to the scoop. Let 
 us cut one out, required to measure 16 inches, and pro= 
 ceed to work it up. Proceeding as before, 15 : 12 : : 16 : 12.8, or 12^ 
 
 inches we should call it in practice ; then — — ^— - — = 20.0277 ; 
 
 that is, the circumference of the bottom half of the scoop is 20 
 inches. Let Fig. 245 represent the pattern for the bottom of 
 our scoop, to describe which we proceed as follows : Draw a b, making 
 it 20 inches from a to b, and erect the perpendicular c d at the 
 middle ; now lay off the distance c d on perpendicular equal to 16 
 inches. Draw e b and/ a parallel to c d, and f e parallel to a b ; then 
 dividing f e into three equal spaces,/^, g h, h e, and with the radius 
 fg (that is, g /), describe the arcs g m and h n, from / and k as 
 centers, and we have the form of the mouth indicated by m g h n. 
 Now we want the back, which may be raised up solid, or cut and 
 brazed together if time is an object. If the end is raised up solid, 
 it will be seen in Fig. 246 that the whole back finished forms a half 
 
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 ART OF COPPERSMITHING. 
 
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ART OF COPPERSMITHING. 1 39 
 
 of a hollow sphere approximately, the curve of the razed down 
 bridge being made spherical, while the curve of the raised up back is 
 elliptical in form when finally finished, u u being the foci. 
 The pattern, however, it would seem, was cut to suit a spherical end, 
 the deviation being made during the process of raising, as the surface 
 is about the same or near enough for practice. Let the pattern then 
 be made to suit a spherical back of 12^ inches diameter across the 
 bridge, as above ; then from a to b, Fig. 245 is 20.0277 ruches, and from 
 
 ( a c )+ cu 
 a to c one-half of a b, or 10.01385; then ^* c ' = s uj that is. 
 
 ( 
 
 10.01385 A , •' 
 
 i-i J + 5.00697 
 
 5-°° 97/ _ I2 ^ ^he ra ^f us s & (that is, s 11). Describe the 
 
 arc a u b, and the surface outlined by the segment a u b c will be equal 
 approximately to the back required, but the parallelogram a T R b 
 containing the segment a v b is in excess of needs by the corners v R 
 b and v T a, and the segment is lying the wrong way. Turn it, or 
 describe it as shown by R c T v, and with the radius v R describe the 
 semicircle R u T, forming the lune R c T u, and we have the pattern 
 T U R n h g m for the bottom or body completed. Now cut it out and 
 wrinkle up the pattern around the lune, Fig. 247, forming at the same 
 time the turn at the mouth as shown in Fig. 248, making the wrinkles 
 small at the sides, and enlarging them in proportion to the sur- 
 face to be operated on. Then take it to a suitable head, Fig. 249, in a 
 square shank, as in Fig. 250, and proceed to work up the back until 
 the distance across the bridge is 12^ inches and the back is the curve 
 required. Now mark out the bridge, using Fig. 251, and the dimen- 
 sions delineated by a v b u, as in Fig. 245, leaving on one 
 side enough in excess so that it may hang over in front 2 inches, as 
 shown, in Fig. 246. Extend Y u, Fig. 251, 2 inches to x, and form the 
 lune a x b y, and the pattern of the bridge is complete, but without 
 edges for wire or groove, which must be allowed and left on. To raise 
 up the bridge, wrinkle the edges both sides, Fig. 252, in the same 
 manner as the bottom, and sink the center in a hollowing block, Fig. 
 253, letting the wrinkles f->rm regularly round the edge until the 
 proper curve is reached. Then take it to the shank or bullet stake, 
 
140 
 
 ART OF COPPERSMITHING. 
 
 Fig. 247. — Wrinkling up the Pattern. 
 
 Fig. 248. — Mouth Formed on Pattern. 
 
 Fig. 249. — Head Used in Working up 
 Back. 
 
 Plllllllllllll ' 
 
 Fig. 250. — Working up Back and Bridge for Nautilus Scoop. 
 
ART OF COPPERSMITHING. 141 
 
 shown at the right in Fig. 250, and with a razing hammer raze down 
 the wrinkles one course, and then wrinkle again until the desired 
 curve is obtained. When this is accomplished trim the edges on each 
 side ready for the wire and groove, then planish and smooth both 
 bridge and body, and wire both, leaving the wire out at each end of 
 the bridge, and turn the grooving edge inside so that it will lap over 
 the bottom. Now lock them and groove them together, letting the 
 end of the bridge wire butt the wire of the body in the middle of the 
 ear of the bail. Then make the foot and prepare the bail and back 
 handle, and clean all up, riveting the foot and handles on the last 
 
 thing. 
 
 If the back of the body for a Nautilus scoop is cut to bring it near 
 the shape requi'red, and then brazed together, it may be formed, or 
 the pattern may be cut as follows, see Fig. 254: (The pattern of the 
 mouth is the same as in the last example, and has been already 
 described.) In Fig. 255 let A E C B represent the back of the scoop 
 and A B the radius of the curve. Draw A D perpendicular to A B, 
 and from B lay off the distance B C, one-fourth of the semicircle G E 
 C B, and draw B D through C ; then B D in Fig. 255 will represent 
 and be equal to a R. u R, T S and b s. in Fig. 254. Divide a b in Fig. 
 254 into four equal spaces, ap,p c, c and b, and with p c as radius 
 describe the semicircle y p. Now, with the radius R a (that is, D B 
 in Fig. 255), describe the arc a u, and with S b, also equal to D B, de- 
 scribe the arc T b. Then, with s in Fig. 254 (that is, D C in Fig. 255), 
 describe the arcs v and/ x, making them equal to y and p y respect- 
 ively : join u x and T v, and the pattern is complete and ready for 
 work. First punch two small holes at/ and and thin the edges and 
 cramp them one side ; then form and bring the edges together and 
 braze them, as shown in Fig. 256. Clean off the joint, knockdown ana 
 anneal and wrinkle the edges,as in Fig. 256, and then proceed to pounce 
 the bottom into shape on a bullet stake, at the same time break- 
 ing down the corner or lag along the curved seam. While this is being 
 done, the side and bottom will bulge out sufficiently to give it the re- 
 quired shape if it receive the proper treatment, which treatment, 
 however, can only be learnt by practice or from a tutor on the spot. 
 When the bottom is prepared, proceed as before to trim, planish, put 
 together and finish. 
 
 The Royal comes next. This scoop has no bail, but is mounted 
 with a handle similar to the back handle, as shown in Fig. 225. The 
 
142 
 
 ART OF COPPERSMITHING. 
 
 Big. 251. — Pattern for Bridge. Fig. 253. — Sinking the Center fo the Bridge. 
 
 Fig. 252. — Bridge with Edges Wrinkled. 
 
ART OF COPPERSMITHING. 
 
 143 
 
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 ^ 
 
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 ^ 
 
 1 
 
 ft. 
 
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 ft. 
 
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 ft. 
 
144 ART OF COPPERSMITHING. 
 
 bridge is made a little stronger and the wire about two sizes larger 
 than usual, to strengthen the bridge enough to bear the strain of 
 carrying when filled with coal. The pattern for the bottom may be 
 the same as for the round-mouth scoop, or, as is sometimes done, made 
 a little fuller, or to rise about i inch in the curve at the mouth, 
 as shown in Fig. 257. When the bridge, see Fig. 258, has been brazed 
 to the bottom, the back end is wrinkled and razed in, forming the 
 curve, as shown in Fig. 257. After this is done the back is cramped 
 in. The wiring is made to go completely round the scoop, commenc- 
 ing and finishing in the middle of the bridge. The scoopet is made 
 to correspond with the scoop. 
 
 The Boat, Fig. 226, is next in order. It will be seen that this 
 scoop is formed like and a little in excess of three-fourths of a sphere 
 that is, up to and where the lip commences the back and bottom, so 
 far as the ears are, are formed similar to the Nautilus ; the other 
 quarter, when half up, being worked out again to form the lip, similar 
 to an earthen jug. Let it be required to make a Boat scoop of the 
 same dimensions as the Nautilus — namely, 12^ inches across the 
 bridge. The bridge may be cut from the pattern already described 
 (allowing for the extra dip in the front), and the bottom may be made 
 thus : Conceive the bottom to be one-half a sphere, 12)4' inches in 
 diameter, then a disk whose surface is equal to this half sphere of 
 12^ inches will be : 
 
 V 12.75 x 3.1416 
 
 o. 7 2 8 5 4 " = l8> ° 312 
 Then draw the line A B in Fig. 259, making it 18 + inches long, and 
 draw D C at right angles to it ; then with the radius P C describe 
 the semicircle A C B. This forms the pattern for the back of the 
 bottom, A E B for the front, and the lune A D B E is the pattern for 
 the lip. Then A D B C is the pattern required for the bottom of the 
 boat scoop without wiring edge. Wrinkle up the edges and raise up 
 the back and sides with a razing hammer on a bullet stake until the 
 curve has reached the middle of the back, and as far as the lip in 
 front, leaving wrinkles enough to form the lip in the second course ; 
 then proceed to work back the lip of the mouth with a round-faced 
 mallet, which will require perhaps three courses. After the 
 desired shape is obtained, planish and smooth ; then wire both bridge 
 
ART OF COPPERSMITHING. 
 
 H5 
 
 Fig. 257. — Side Elevation of Royal Scoop. 
 
 Fig. 258. — Patterns for Bottom and Bridge of Royal Scoop. 
 
146 
 
 ART OF COPPERSMITH INC. 
 
 Fig. 259. — Pattern for Bottom of Boat Scoop. 
 
 Fig. 260. — Side Elevation of Helmet Scoop. 
 
 Fig. 26 r. — Body of Helmet Scoop 
 Brazed Together. 
 
ART OF COPPERSMITHING. 1 47 
 
 and bottom as directed for the Nautilus and put them together ; 
 clean up and put on the mounting. 
 
 The Helmet scoop, Fig. 227, was considered at one time by old 
 braziers as the summit of excellence in this line ; but I think that a 
 careful study of the subject will show that there is as much or more 
 skill required to produce the Natilus or the Boat as is required for 
 the Helmet. They however, all demand proficiency and along, care- 
 ful training with much patience to acquire the skill necessary for the 
 execution of the various steps through which they pass to completion. 
 In my boyhood we knew nothing of -buff wheels or any of the other 
 devices which have sometimes been used to substitute this labor ; our 
 work was smooth and complete from the hammer except the final 
 scouring to remove the hand or finger marks. While it was a tedious 
 task to acquire this proficiency, it was a continual source of pleas- 
 ure and profit to any who possessed the attainment. 
 
 We will make a Helmet scoop, and then describe the planishing 
 and smoothing as I was taught to do it. It will be seen by reference 
 to Fig. 260 that the scoop, if made true by a workman, is two-thirds of 
 an ellipse, with the lip added, as shown by the outlines G D A C. The 
 foci of the ellipse are B and S, which are obtained thus, and form the 
 foundation of the work. Draw B A equal to the depth of the scoop, 
 and D C at right angles to it ; divide B A in two equal parts at S, and, 
 with S A as radius, describe the arc I H ; then with S A lay off from A. 
 each way the distances A I and A H, and through S draw the line H 
 N, cutting the line N B C at N. Now, with K H describe the arc H 
 C, and with J I describe the arc I R, and draw R D at right angles to 
 N D ; with N D as radius describe the arc G D, and G D A C forms 
 the outline of the body required. Continue I M through M to F, and 
 with B A or K H describe the arc X B C, and join G X, giving the 
 curve of the mouth when finished. To fashion this we must prepare 
 a cylinder, indicated by the dotted lines running through E B C P O 
 in Fig. 260, and more clearly shown in Fig. 261. The envelope or pat- 
 tern for Fig. 261 may be drawn similar to that described for a coal 
 hod in a former chapter. The pattern then being given cramp, put to- 
 gether and braze, trim the joint, knock down and anneal, then wrinkle 
 at O P, and on a head in the square shank raze in the end so that 
 the seam of the bottom may be covered by the edge of the foot when 
 riveted on. When the proper size, stag in the edge to stiffen, and 
 proceed to work out the lip, after which put in the bottom ana true 
 up to shape and make the foot ready. ,. 
 
148 ART OF COPPERSMITH [NG. 
 
 PLANISHING AND SMOOTHING. 
 
 Planishing as understood by braziers is the art of first molding 
 smoothly or shaping the metal when first formed ; second, hardening 
 or closing the grain, and third, by the aid of the hammer giving it 
 a gloss or a kind of case-hardening sufficient to receive the final polish 
 with tripoli, which is a very fine powder having a purple hue. To 
 planish the goods under consideration, it is necessary to have the 
 heads as near their curves as possible, and the square shank of the head 
 should be taper enough to make it fit tight into the tools which receive 
 it ; the convex curves of the round heads may run from 4 inches 
 to 2 feet or more, the long heads the same, the long heads being 
 about twice their width in length. It is also necessary to have a few 
 saddle heads for such work as requires them, and though we had no 
 bright mandrels then, later experience has taught me that they would 
 have been better adapted to our use for many things than the little 
 short heads we had. Our hammers were various, some with round 
 and some with square flat faces, see Fig. 262, or commonly called so, 
 and ranged from 10 ounces to 3 or more pounds. The concave ham- 
 mers, Fig. 263 — that is, those whose faces are hollow — ranged from 
 a circle of 4 or 5 inches to 15 inches, and were used for spheri- 
 cal or ball-shaped work. The saddle hammers, Fig. 264, and 
 those with long faces were used for such work as helmet scoop lip ; 
 we also had a number of bright bullet or convex hammers for special 
 purposes. 
 
 Now, let us suppose we have heads and hammers suitable for the 
 Royal scoop, and that the scoop has been scoured clean and bright. 
 We first take it to a long head, and commence by smoothing down all 
 the irregularities with a clean, smooth-face mallet. Take then a 
 suitable flat-faced hammer weighing, say, about 1 pounds, and com- 
 mence with blows from back to front in the middle of the bottom, 
 and in regular succession until the edge is reached, making each line 
 of blows lap a little at their edges; now work up the other side 
 and over the bridge. Then proceed with the back in circles on a 
 bullet stake, or a head in an upright shank, the same way until the 
 
ART OF COPPERSMITH1NG. 
 
 I 19 
 
 Fig. 262. — Round-Face Hammer. 
 
 Fig. 263. — Concave-Face Hammer. 
 
 Fig. 264. — Saddle-Face Hammer. 
 
150 ART OF COPPERSMITHING. 
 
 first course is completed. Next give it a good rubbing down with a 
 clean rag, so that the blows of the next course, which is done with a 
 spring-faced hammer, may be readily seen. When this course is fin- 
 ished the scoop should be in good shape. With a flannel wisp scour 
 with sweet oil and tripoli, and clean off carefully all oil and dust. 
 Look over and examine to find omitted spots and touch them up. 
 Then muffle the head with a piece of shalloon or a piece of skin parch- 
 ment drawn tight over it, and go over the work lightly to finish. The 
 spring face may be changed from hammer to head, according to the 
 ingenuity of the workman and to suit the work in hand. The shal- 
 loon supplies the place of a spring face, as also does the skin, their 
 purpose being to take off or counteract the effect of the impact of the 
 hammer, the impinging of which on a naked head causes a sharp 
 ridge all around the blow, and this can only be obviated by the 
 muffler inside or by the spring face outside. The concave 
 and all other hammers may be fitted with false or spring 
 faces, according to the work for which they are to be used. 
 
 The parts of the Nautilus may be treated in the same manner as 
 directed for the Royal. The Boat and Helmet scoops will call into 
 requisition both flat and concave, as well as long and saddle-faced 
 hammers. In working around the lip of these scoops it should be 
 stated that the lips should be bright and smoothed on the inside as 
 far as the eye catches them at first sight ; the rest is left dead — that is, 
 as the skin or shalloon leaves it, clean but dull, not bright. 
 
 The planishing described in the foregoing is for the best kind of 
 bright work. The next grade is for common brown work, which is 
 finished in two courses. The brown used is good Spanish brown, put 
 on dry with a tow wisp, well rubbed into the grain and applied so that 
 plenty hangs on, but uniformly all over ; it is then hammered into the 
 grain in the first course, and then smoothed in the second. Another 
 style of planishing is executed in a way that every blow may be seen 
 distinctly and in regular succession, and is adopted in that kind of 
 goods where closing the grain or hardening is the principal object m 
 view, as in washing coppers and some other work ; while for many 
 rough kinds of braziery, such as carboys, sugar molds, pump heads, 
 air vessels and various kinds of boilers, the hammering is done in a 
 promiscuous way, so long as the surface is covered and the work 
 hardened sufficient to maintain its shape. 
 
AKT OF COPPERSMITHING. 151 
 
 CRANES OR SYPHONS. 
 
 Cranes or syphons may be said to possess or perform the func- 
 tions of a self-acting pump, but their operation, in reality, is only the 
 effect of destroying the equilibrium of the liquor by the unequal 
 lengths of the legs or ends of the bent tube through which the liquor 
 passes. The liquor acts as if it were a rope hanging or passing over 
 a nicely adjusted pulley wheel, Fig. 265, the excess of weight on the 
 one side pulling the lighter or shorter end over; or, as the perpendic- 
 ular hight of the column A C, Fig. 266, is greater than that of B D, 
 and the pressure of the atmosphere the same at both orifices, the 
 pressure or weight of water at C is greater than at D, and therefore 
 the weight at A, Fig. 267, overbalances that at B, and draws the 
 liquor over the bend. In the meantime the atmospheric pressure at 
 the end B is forcing the liquor up through the orifice at B, and it con- 
 tinues to. flow from A until the liquor in the vessel falls to the level 
 of the orifice B. These simple machines were made for, and are 
 principally used by, brewers and wine and spirit merchants to draw 
 off the contents of casks of various kinds, where it is not desirable 
 to insert a faucet. They are usually formed of a copper tube about 
 1% inches inside, and with a cock at the longer end, as shown in Fig. 
 268, for the purpose and convenience of stopping the flow when 
 necessary. They are also supplied with a small tube, E, running 
 along the side, by which the liquor is made to flow when 
 the air has been exhausted through it by the mouth, the long 
 end of the syphon being stopped with a cork or by the hand covering 
 the orifice, or the syphon may be charged through a stopcock with 
 funnel at the crown G when the liquor to be drawn off is of an offen- 
 sive nature, as is sometimes the case. The inside of the bend H is 
 reinforced with a saddle piece from A to B to protect the bend from 
 the hoops of barrels being emptied. The stopcock was soldered to its 
 place and the end lengthened out with two plumbers' joints, D and F, 
 and the ends strengthened as. at C, to shield it from contact with the 
 ground while moving it about when in use. A pipe of 25 to 30 pound 
 plate was considered fairly strong. 
 
 We will make one, and let be 1% inches inside (the thickness of the 
 
152 
 
 ART OF COPPERSMITHING. 
 
 .1 
 
 u 
 
 D_ 
 
 Fi%. 265. — Rope and Pulley Illustrating Fig. 266. — Water Columns in Syphon, 
 Syphon. 
 
 Fig. 267. — Syphon in Operation. 
 
 Fig. 268. — Copper Syphon. 
 
ART OF COPPERSMITHING. 1 53 
 
 metal will be about 1-16 inch) ; then to make a pipe 1-16 inch thick and 
 1%. inches inside diameter we have 0.0625 + J - 2 5 x 3 T 4 T 6 = 4- I2 33> or 
 4^ inches wide, and some 7 feet long.* Now thin the edges on oppo- 
 site sides and trim and smooth them with a file and anneal ; when 
 cool scour clean and take it to a vise and with a razing hammer sink it 
 between the jaws of the vise or some other suitable tool, such as a 
 blacksmiths' swedge block (if handy). When half turned finish it on 
 1 inch steel bar, closing the edge uniformly down the whole length. 
 Now jar some borax and water through the joint and charge it with 
 solder, which may be done on the' outside or inside, as preferred by 
 the operator, although it is the best job when charged inside. Dry 
 carefully, and when the borax is all down run the solder down the 
 joint with a moderately brisk but clean fire. When cool examine and 
 repair any deficiency ; then trim the joint and swage on the bar; then 
 anneal, and fill with rosin, and in the absence of any other conven- 
 ience it may be bent in a well-worn hole in the edge of the bench. 
 Before bending see that the edge of the seam is perpendicularly in 
 the center of the pipe and that it laps toward the inside of the bend> 
 because if it is bent with the seam lapping toward the outside there 
 is a tendency to break. Be careful that no cinders or other foreign 
 matter gets into the pipe ; and have the rosin clean and solid when 
 cool. When bent and the resin has been taken out solder in the sad- 
 dle piece, A B, put on the rings, C and K, and fasten in the cock; next 
 put on the air tube, F, below the cock, clean off all the soft solder 
 practicable and finish up clean. 
 
 * Note. — The first syphon I saw when a boy was made in three pieces — that is, the bend and 
 two legs soft soldered together. The reason for this was, our sheets were only 4 feet long ; and 
 again, our forge was not adapted for this kind of work. The next one was made in two pieces 
 arid brazed together and bent after. The last one was in one piece of solid drawn tube with 
 the cock and the air tube brazed on. 
 
154 ART OF COPPERSMITH I NO. 
 
 PUMPS. 
 
 Copper pumps, or rather pump heads with cylinder, have been 
 and are now made in several different styles and shapes to be used 
 for various purposes; among which are those made for brewers and 
 bargemen, tanners, oilmen and others. The pump illustrated in Fig. 
 269 is the simplest kind made, so far as the brazier is concerned. It 
 consists of a straight piece of pipe of the desired length, usually from 
 8 to 10 feet long, with a flange at each end, the head being made large 
 enough to hold about two strokes — that is, to have room enough so 
 that it may not overflow while in operation. The head is a straight 
 cylinder, Fig. 270, having the bottom turned in far enough to take 
 the bolts so that it may be bolted to the flange, as shown, the bolt 
 heads being on the inside; the spout, Fig. 271, is flanged and riveted 
 to the side of the head near the bottom. The iron ring and double 
 eye, Fig. 272, in which the handle works, is then riveted to the top 
 edge and the copper turned over evenly all round the rim. 
 
 We will make one 10 feet long from bottom to spout, and let it be 
 t-i6 inch thick and 2^4 inches in diameter inside; then we have 0.0625 + 
 2.5 x 3. 1416— 8.0503, or 8 inches; cut the strip and trim the edges, an- 
 neal and scour clean. Now lay it in a trough, Fig. 273, made by a 10 
 x 2-inch oak plank, having two other pieces 2 inches thick fastened 
 to its sides, making a trough about 5 inches wide. With a mallet sink 
 the sheet in the trough; then turn it over on the mandrel and finish 
 the turning, being careful to keep the seam straight and closed down 
 evenly (I have sometimes put a cramp at each end and one in the 
 middle to keep the joint close). Now jar some borax and water 
 through the seam and with a reed, Fig. 274 (that is, a strip of light 
 copper about 1 inch wide turned half round), filled with solder, charge 
 the seam by sliding the full reed through the length of the pipe, and, 
 turning it over on the joint, jar the solder out of the reed and remove 
 it. Take the tube to the fire and dry it; then gradually make it hot 
 all along, and when the solder is all down, run it down the seam on a 
 moderately brisk fire. When cool examine and repair all faulty 
 places, if there are any; clean off the joint and planish on a smooth 
 mandrel as near the size as you have at hand, and then braze on the 
 
ART OF COPPERSMITHING. 
 
 J 55 
 
 
 a. 
 
 ^ 
 <• 
 
 & 
 $■ 
 
 1 
 
 
156 
 
 ART OF COPPERSMITHING. 
 
 11111 
 
 Fig. 275. — Barge or Tanners' 1 Pump. 
 
 Fig. 278. — Pump 
 Barrel. 
 
 Fig. 276. — Head and 
 Cylinder. 
 
 Fig. 277. — Pump for Pipe or Hose 
 . Connection. 
 
ART OF COPPERSMITHING. 157 
 
 flanges. Make the head to hold, say, i gallon. A strip of copper 24 
 inches long and 6 inches wide would make 1 gallon head, but there 
 must be in addition 1 inch to turn in for bolts and y^ inch to turn over 
 the iron ring, making the width, therefore, 7^ inches. Cut it out and 
 work it up, and make the spout 2 inches in diameter, flange it, fit it 
 and rivet it on, and then bolt the head to the flange and clean up. 
 The cylinder for this pump is made of gun metal and the clacks are 
 all ground in the pump, as it is used principally for hot work. 
 
 The next pump, Fig. 275, is used by bargemen, tanners and others 
 to pump liquids from barges and tan pits, wells, cellars, foundations, 
 &c. This pump is somewhat similar to Fig. 269, but is usually fur- 
 nished with a wooden bucket and leather clack; the bottom clack is 
 also of leather, although it may be, and often is, fitted with brass 
 bucket and clacks when made for brewers. The pump, when com- 
 plete, is usually 10 feet from bottom to the delivery spout, but they 
 are made whatever size is required, so that any number of men may 
 be used to work them. It will be seen that the cylinder of this pump, 
 in which the bucket or plunger works, is enlarged, and forms part of 
 the pump, and is drawn in small enough to suit the suction pipe, 
 which is invariably the same size as the bucket clack, so that the full 
 column or capacity of the suction pipe may be thrown from the de- 
 livery spout. When this pump is correctly made the barrel is per- 
 fectly cylindrical, and is a good job when completed. Let us make one 
 and suppose the cylinder to be 4 inches in diameter inside and 2 feet 
 long, and let it be 1-16 inch thick; then 0.0625 + 4 x 3.1416 = 12.75, the 
 circumference or width of the sheet required. Cut it out and trim off 
 the burrs and trim; cramp, making the cramps about 2 inches long, 
 turn and bind with wire, and close down the joint carefully, so that the 
 inside is smooth; that is, after the joint has been laid with a hammer. 
 Then take a mallet and with a few smart blows bring the joint down to 
 the spindle, which should not be less than 3 inches in diameter; next 
 charge the joint and let the solder follow the zigzag course of the 
 edges of the cramps; dry and heat the back of the pipe to take off 
 any spring, and then turn the joint to the fire, and run it down, care 
 being taken that the fire is clean. The suction pipe is made in a 
 similar way, but need not be cramped. Flange the cylinder G, Fig. 
 276, and draw in the end, making a collar, say, 1^ inches wide, and 
 fit the suction pipe to it and tin both parts of the joint. Make the 
 head Y, Fig. 275, about 8 inches in diameter and the same in depth to 
 
158 ART OF COPPERSMITHING. 
 
 the turn of the bottom. To do this there is required a strip 10 inches 
 wide, together with y 2 inch to turn over the ring and double eye, 
 making - a strip 10^ wide by 25^ inches long. Cut it out and form 
 and raze in the bottom end of G, so that the hole is 4 inches. The 
 barrel, or cylinder, may now be riveted to its place and the suction 
 pipe joined to it by a plumber's joint, D, Fig. 275, or it may have a 
 socket joint, Y, also soft soldered. Solder the length of pipe together, 
 making the whole, wUen complete, 10 feet from bottom to delivery 
 spout. Now put in the lower clack about 12 inches from the bottom, 
 then the bucket and clean up. The next pump, Fig. 277, is made in 
 every way similar to the last, excepting that it has a flange brazed at 
 the bottom of the barrel, Fig. 278, while the additional coupling flange 
 is attached to a piece of iron pipe and screw threaded, for iron pipe or a 
 leather hose. 
 
 The pump, Fig. 279, is used by oilmen and others to lift oil out of 
 barrels and is a good job for a young man approaching the end of his 
 apprenticeship. The head is made spherical, and the spout after being 
 bent extends from the pump about 2 feet. The pump from clack 
 to delivery spout is usually irom 4 to 5 feet long and 2 inches in 
 diameter. The spout is tapering from x% inches at the bend to 2 at 
 the flange. This head may be formed from a strip of metal the 
 required size, as shown in Fig. 280, the two ends being razed in 
 similar to a round tea kettle body, leaving the wiring edge as the work 
 proceeds. When the bottom end is razed in sufficiently the short 
 flange pipe or flanged collar is cramped in as shown and brazed; the 
 head is then planished brown and wired and the collar tinned. The 
 flange of the spout, Fig. 281, is worked out so that it will fit on the 
 underside of the head to empty it and the operation of flanging is 
 performed during the turning; that is, it is begun while flat, and as 
 the work proceeds the spout curls round the seam, being on the under- 
 side. When flanged and the seam soldered, fill with rosin or lead and 
 bend the end. Now make the pipe, Fig. 282, and let it be 2 inches 
 inside diameter. Cut out the strip, thin, sink in trough, Fig. 273, and 
 finish, turning on the bar and making the joint straight. Solder it 
 downward, clean off and put it on the bar, Fig. 283, then with a swage 
 and a sledge hammer smooth the pipe, making it cylindrical and 
 smooth, so that a brass plunger or bucket will work uniformly through 
 it. Next swell out the end to receive the collar of the head, Fig. 284, 
 which must be the same size as internal diameter of the pipe, so that 
 
ART OF COPPERSMITHING. 
 
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 ART OF COPPERSMITHING. 
 
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 the joint may be smooth inside. Rivet on the spout, solder in the 
 head, fit in the clack and the bucket, put in the handle and clean 
 all up. 
 
 The next pump, Fig. 285, is called a single jigger. This pump is 
 mounted on a heavy cast-iron plate with avenues or water courses on 
 the underside. The cylinder and first bend with flange is cast of gun 
 metal, and the stand or upright pipe and air vessel are made of 
 copper. The outlet or discharge pipe may be either soft soldered or 
 plain, or it may be riveted and soldered, or brazed on. The air 
 vessel may fit on the inside or "end of the pipe, or be swelled 
 out to receive it. The handle, or jigger, is fastened to the stand pipe 
 with a clamp and bolt, which is made to form the double eye for the 
 jigger which is suggested by the sketch. 
 
 The last or double-jigger pump is shown in Fig. 286, and as far as 
 the brazier is concerned, is the same as the pump, Fig. 285, with the 
 addition only of the J piece at Y, the cast-iron plate also being 
 made larger to conform to the needs of the two cylinders forming the 
 double-action pump. 
 
 And now in closing my recollections of light sheet copper work- 
 ing or braziery, from early childhood to manhood, if I have been 
 fortunate enough to have supplied the means of helping some 
 struggling, earnest boy on the road to success, the purpose of these 
 articles is acccomplished. At the same time, it is hoped by the writer 
 that they may be read with a degree of pleasure and profit by some of 
 the elders of the craft. 
 
'1 62 ART OF COPPERSMITHING. 
 
 RAILWAY AND MARINE 
 
 COPPERSMITHS AND THEIR APPLIANCES 
 
 Men skilled in the art of working sheet copper are usually divided 
 into three classes, which may almost be designated as three separate 
 trades. The first and most ancient have been known for centuries as 
 braziers. These men were employed in the manufacture of all kinds 
 of cooking- utensils, transmitting their craft from father to son for 
 many generations, and have guarded their patrimony with a jealous 
 eye. The next division was turned in the direction of larger and 
 heavier vessels, such as brewing coppers, tallow coppers, dyers' cop- 
 pers, stills of various kinds and vacuum pans for refining sugar, worms 
 and coils, pumps, and many other heavy articles and vessels. These 
 men are called coppersmiths, and properly so, because a majority of 
 their work has no need of soldering or brazing, and as a rule they are 
 poor brazers. With the advent of the steam engine another and third 
 branch was called into existence. These men are employed about 
 locomotive and marine engines, and seldom seek employment in any 
 other line. Their work principally consists in making pipes of various 
 sizes, forming bends, tee-pieces, cross-pieces, and, in fact, twisting a 
 copper pipe into any conceivable shape required to fit the position it 
 is intended to occupy. We shall for the present engage the attention 
 of the reader to this last class of coppersmiths, and endeavor to de- 
 scribe a well-appointed shop for this kind of work. The first and 
 most essential thing for a healthy coppersmiths' shop is a lofty, 
 spacious room ; if possible, not less than 20 feet high, with a floor 50 
 x 60 feet ; the light should, if practicable, come from the roof through 
 opaque glass ; the roof should be furnished with dormers having mov- 
 able slats, which may be raised and lowered as occasion requires to 
 let out the fumes and gases that arise from the fuel in the forges and 
 from the metal which is being worked, for they are often of a most 
 repugnant and almost suffocating nature. The room having been ob- 
 tained and provision made for the easy exit of the poisonous gases, 
 benches for the accommodation of from six to ten men may be erected 
 and fixed firmly against the wall on one side of the shop to suit con- 
 venience, as shown in Fig. 287. The benches should not be less than 
 3 feet wide and 3 inches thick, of some hard wood. They should 
 
ART OF COPPERSMITHING. 
 
 163 
 
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 -jf VISE 
 
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 -0-VISF 
 
 -|f VISE 
 
 TOOL BLOCK 
 
 MANDREL BLOCK 
 
 SHOP 
 
 5o' X 60 ' 
 
 BENDING BLOCK 
 
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 B 
 
 CAULDRON FURNACE' 
 
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 BRICK FORGE 
 
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 BRICK FORGE 
 
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 Fig. 287. — Plan of Shop. 
 
164 
 
 ART OF COPPERSMITHING. 
 
 
 
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ART OP COPPERSMITHING. 1 65 
 
 be provided with capacious drawers for the tools of each man, with a 
 vise at each drawer, Fig-. 288, the vises being- not less than 8 feet 
 apart. The bench may reach as far as necessary along the side of the 
 shop, and may turn at the end as far as the door. The doors should 
 be in the middle of each end, and large enough to allow such work to 
 pass through as is likely to be done, and admit a current of air readily 
 when necessary. On the opposite side of the shop three forges may 
 be placed, two made of brick, and one, A, of iron. The two of brick, 
 Fig. 288, should be about 3 feet high and 3 feet wide, and reach 5 or 6 
 feet from the wall. In the center of" the top is the fire hole, which is 
 about 10 inches wide and 12 long and from 8 to 10 deep. The blast 
 can be supplied in the most convenient way, either from a fan or a 
 large bellows ; if from bellows, they should be hung overhead out of 
 the way, so as to be convenient for the two outside forges, pipes being 
 laid so the blast can be carried from one fire to the other, and to all 
 if necessary. The iron forge, Fig. 289, should be made of ^-inch 
 boiler iron, and so constructed that the side leaves can be taken off 
 easily when necessary. 
 
 In the spaces between the three fires should be two pits of con- 
 venient depth to receive from 8 to 10 feet of pipe. These pits are 
 about 3 x 4 feet and 6 deep, and covered with a lid of 2-inch oak plank; 
 one plank of the lid or cover being left loose, to give access to the 
 pit. In one of the outer corners of the pits a blast pipe is fixed for 
 -work which must be done over or near a pit. On the same side of the 
 shop is a bin to hold coke, Figs 287 and 289, and which is placed close 
 to the door. On the opposite side and in the space from door to wall 
 a furnace is erected having a cast-iron caldron for the purpose of 
 melting lead, also a fire to melt the rosin used to fill pipes for bending. 
 Above each of these fires and forges is a kind of tramway for wheels 
 to run on, the lower wheel carrying a chain, as shown in the cuts. 
 The chain should be large enough so that a hook at each end of it can 
 be readily caught in the links. The chain is used to hoist up and 
 sling the work that it may be easily manipulated over the fire and at 
 the mandrel block. To the wall is fixed a hitching hook for the pur- 
 pose of tying the fall end of the chain when work is slung over the 
 fire. The tramways are conveniently placed so that work may be 
 easily carried from one place to another and to and from the fire; also 
 to hold the work balanced while being operated on at the mandrel 
 block or bench. The mandrel block is made of cast-iron plates some 
 
1 66 
 
 ART OF COPPERSMITHING. 
 
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ART OF COPPERSMITHING. 1 67 
 
 2 inches thick, and about 5 feet long and 4 feet wide, stoou on edge, 
 2 feet apart. The plates, which are firmly fixed opposite eaoh other, 
 have holes in them both round and square to receive round und square 
 mandrels, which go through both plates, so that the mandrels may be 
 securely wedged and held fast in their places. Some 20 feet from the 
 back or furnace end of shop floor is fixed a cast-iron post, B, from 
 12 to 14 inches square. This post is for the purpose of bending pipe, 
 and is called a bending block. It should be placed as near the middle 
 of the shop as convenient, and must be firmly set in the ground with 
 a good broad foot at the bottom, as it requires considerable power to 
 bend 5-inch pipe filled with lead, and if the block is not solid the 
 power used in bending would loosen it. The top of the block has a 
 ledge 4 inches deep for a strap to rest upon, the strap holding the 
 lead-piece. The strap is of iron, 1 inch thick and 3 inches wide, made 
 like a square staple with the ends drawn down so that a i^-inch 
 thread can be cut on them. Another piece of iron with holes in each 
 end is made to go over the threaded ends of the strap. This strap is 
 to hold a thick lead-piece on top of the block, the lead having a hole 
 m it large enough to take the pipe in easily which may be required to 
 be bent. 
 
 Since this article was prepared I have been favored by Mr. More- 
 ton, one of the workmen in the coppersmiths' shop of the London and 
 Southwestern Railway of London, England, with two views of the in- 
 terior of a new and larger shop than the one above described, the 
 arrangement of which is a little different from the old shop. In these 
 two illustrations of the new shop, Figs 290 and 291,1 notice the old 
 brick forge has been discarded and the position ot all the forges has 
 been changed. The new ones are apparently placed in the middle 
 of the shop, which has probably been found more convenient The 
 first object in the picture, Fig. 290, is the floor block, with a bottom 
 stake standing in it. A little to the right of this is an anvil, used to 
 work down the saddles of bends which are made in two halves. (One 
 of these bends is lying on the end of the mandrel block in Fig. 291.) 
 
 On a table near are two brass valve covers, the crowns of which 
 have just been brazed in. The next thing beyond these covers is a 
 forge, in which there was a fire when the picture was taken. Other 
 prominent objects are three brass dome covers, the making of which 
 will be described later. 
 
 The next thing we notice is a coping, which is made of sheet 
 
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 ART OF COPPERSMITHING. 
 
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ART OF COPPERSMITHING. 
 
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 iron and screws as a finish to the lagging of the back end of the fire 
 box. Under the left-hand end of this coping is a pit with a blast pipe 
 at the southeast corner of it. Hanging on the wall is another kind 
 of coping for the front end of the fire box, and which connects the 
 lagging of the fire box with that of the boiler. The traveler chains 
 used for slinging work are all clearly shown hanging at different 
 points m the shop. In the other picture, Fig. 291, taken from another 
 point, the benches are shown. The principal object on the bench is 
 another iron coping finished ready for fitting, and in the corner are 
 two long boiler steam pipes 6 inches in diameter, which are the larg- 
 est pipes usually made in a locomotive shop. The next thing is the 
 mandrel block, upon which are lying four cods, six small heads of dif- 
 ferent shapes and three large long heads: In the end hole at the left 
 hand of the mandrel block is a wooden bar made to receive the shank 
 of the large heads, the end of the bar being shoed with an iron strap 
 to keep the head in and form the hole for the head shank. 
 The shop, it will be noticed, is illuminated by electric light, 
 two lamps being shown. In the left-hand corner of the mandrel 
 block, and securely fastened, is a 3-inch round iron bar about 7 
 feet long, upon which are two cast-iron blocks that slide up and 
 down the bar as required. These blocks have holes in them to 
 receive mandrels, and are made fast by a suitable set screw at the 
 back, which holds the block at any required hight when the main 
 mandrel/block is too low for the work in hand. A little to the left of 
 this bar is a screw jack, used to hold up one end of a pipe at the fire 
 or for other purposes. On the wall may be seen various wire tem- 
 plates of delivery and other pipes. Altogether these pictures afford 
 an interesting peep into a London railway coppersmiths' shop. 
 
ART OF COPPERSMITH INC. 171 
 
 MAKING COPPER PIPE. 
 
 Copper pipes until recently were made by hand in 10 and 12 fool 
 lengths, and from y 2 inch in diameter to any required size, and so great 
 was the demand with the advent of the steam engine that many men, 
 who were called pipe makers, were employed exclusively in making 
 copper pipes and brass tubes. The marine coppersmith is now sup- 
 plied with all sizes of straight pipes ready to his hand, but formerly 
 he made them all. There have been rapid strides made in this art, 
 and, like all other arts, that of the coppersmith has had to succumb to 
 the march of scientific and practical research. Copper pipes are now 
 drawn and made without seam, yet it often happens that the copper- 
 smith is called on to make a few lengths in an emergency, and the 
 most efficient method of doing this by hand will now be described. 
 If the sheet of which the pipe is to be made is heavy the edges are 
 thinned on the opposite sides of the strip; it is then turned and lapped 
 only. If, on the other hand, the sheet is light, the edges must be 
 cramped before thinning. If the pipe to be made is more than 6 feet 
 long, we use a trough, Fig. 292, made of two long planks about 2 
 inches thick, placed in crossed pieces similar to a sawbuck, and lying 
 at right angles to each other. The sheet is laid in the trough and a 
 straight bar is dropped on the sheet metal, which yields to the falling 
 bar, and the first form is thus given to the sheet. It is then further 
 rounded by placing it the other side up over one of the edges of the 
 trough and bringing it together with a mallet. When brought together 
 sufficiently the joint is laid even on a long steel bar fastened at 
 one end in the mandrel block. If the pipe is to be made of thin 
 sheet metal, then the joint should be cramped together. This is 
 done by cutting the edge on one side about every 2 or 3 inches 
 with a chisel held slanting so that the cramp will form a lap where 
 cut, as shown in Fig. 293. The edge is now suitably thinned, after 
 which the sheet is turned round. The outside cramps are then lifted 
 so as to admit the other edge, which is not cut, and which is put 
 between the cramps, one going inside and the other outside. 
 
 The pipe, Fig. 294, is then bound together with pieces of binding 
 wire placed about 2 feet apart and pulled up tight, the cramps are 
 closed down and the joint laid evenly with a hammer or mallet to suit 
 
172 
 
 ART OF COPPERSMITHING. 
 
 Fig. 292. — Trough for Forming Copper Pipe. 
 
 Fig. 293.— Edge of Sheet Cramped. Fig. 294.— Pipe Ready for Brazing* 
 
 Fig. 295. — Reed for Placing Spelter on Seam. 
 
 Fig: 296.— Portable Supports for Holding Pipes while Brazing. 
 
ART OF COPPERSMITHING. 173 
 
 the joint required. The joint must now be made to chatter — that is, 
 jarred to loosen it enough so that the spelter may have room to flow 
 freely through the joint when it is being brazed. All the foregoing 
 directions having been followed successively, we now proceed to 
 charge the joint with spelter. The spelter is mixed with clean water 
 and borax, equal amounts of spelter and borax by measure being 
 used. The best results follow if the mixture is made ready two or 
 three days before wanted. To charge the joint take a strip of metal 
 and form it into a V-shaped reed, Fig. 295, the length of the pipe 
 and large enough to hold a sufficient quantity of spelter for the joint. 
 Fill the reed evenly with spelter, and then slide it carefully 
 through the pipe, laying it evenly on one side of the seam. 
 Then turn the reed over on the seam, jar the spelter out of it 
 and carefully remove the reed. The pipe is then ready for the 
 fire. The fire must be clean and made of clean coke, care being taken 
 that 110 lead or soft solder is on the forge or in the fire. The pipe is 
 laid on the supports, Fig. 296, which are made of angle iron and bolted 
 to a heavy foot so as to stand firm. The angle irons have holes 
 punched about 1 inch apart, and a ^-inch rod run through with a 
 wheel between the standards having a groove in it large enough to 
 lay the pipe in so that as the joint is brazed it can easily be drawn 
 through the fire without any unnecessary friction. During the process 
 of soldering a pan of powdered borax must be at hand in case at some 
 point the spelter should need more to flux it. After the pipe is cooled 
 the seam is cleaned off by a sharp file and taken to the mandrel, and 
 with a bright top swage it is rounded up and smoothed ready for use. 
 
 PIECING AND JOINING PIPES. 
 
 There are two ways of piecing or joining copper pipes — namely, a 
 flush joint and a socket joint, soft soldering and hard soldering or 
 brazing being employed. The manner of making a flush joint for 
 soft soldering is shown in A and B, Fig. 297. A represents a flush 
 joint prepared and ready for soft soldering. B represents a socket 
 joint prepared for soft soldering. C a flush joint for hard solder, and 
 D a socket joint for hard solder. The socket joint is adopted when 
 it is necessary to preserve the full bore of the pipe ; the flush joint 
 when it is necessary to retain the exact size outside, as in the case of 
 a gland, or where a screw nut has to pass over the joint. 
 
 In Fig. 297, A, it will be noticed that one piece has been reduced, 
 or swaged down ; this may be done with a top and bottom swage used 
 
J 74 
 
 ART OF COPPERSMITHING. 
 
ART OF COPPERSMITHING. 175 
 
 by blacksmiths, if proper care be exercised, and the part operated on 
 kept soft, or it may be reduced with a raising hammer. The inner 
 piece should be carefully fitted, and, where reduced, of sufficient 
 length to allow of its being kept cool at the end, so that it will retain 
 the solder when the fire is applied to the joint. The female or outside 
 piece should be thinned at the end, and the male or inside piece care- 
 fully hammered (not filed) to fit the scarf of the female end, which 
 should project from the side sufficiently so that a suitable stick or bar 
 of solder, when the -joint is made hot enough to melt solder, can be 
 drawn around the joint without any of it running down the outside, or 
 when being filled from a ladle of solder, as is often done. Sometimes 
 it is best and most convenient to wipe a plumber's joint, as it often 
 happens that a fire cannot be applied or used in the work, either from 
 its situation or because it would be unsafe to apply a fire. 
 
 The socket joint, Fig. 297, should be carefully fitted as in the case 
 of A, the projection of the edge of the socket answering the purpose 
 of the projection as in the flush joint A — namely, to insert or run the 
 solder into the joint. 
 
 The flush joint C should have the same care given to it as in the 
 case of A and B, but with this addition : On the female end a collar or 
 flange must be laid off of the desired width, as shown, to form a chan- 
 nel or receptacle to hold enough spelter or hard solder when melted to 
 fill the joint full. 
 
 The socket joint D is prepared the same as B. These sockets are 
 made or enlarged on a suitable mandrel or steel stake by hammering 
 until expanded to the proper size ; the flange or collar is then laid off 
 and the two ends are fitted easy, so the male end will go snugly into 
 the socket without binding, but with sufficient room for the solder to 
 flow freely about it and fill the joint full and make it solid. If the 
 foregoing instructions are closely followed we are now well on with 
 the work to be accomplished. We must now tin the joirit (coat the 
 ends with tin), both male and female, if for the joints shown by A and 
 B ; but the male end should be tinned only to within % or y 2 inch of 
 the end. On this spare space a little plumber's soil is applied to pre- 
 vent the solder flowing down too far while the joint is being made. 
 To clean the joints for soldering cover the parts with a strong solu- 
 tion of common, salt and water, heat them in a clean coke fire to a 
 cherry-red heat, and then plunge into water; next scour with a clean 
 tow wad and sand and water, and finally dry. The pipes are now 
 ready to place in position for the fire. 
 
I76 ART OF COPPERSMITHING. 
 
 Having secured a suitable position, the application of the fire 
 is next in order. In Fig. 298 is shown my first fire pot, which subse- 
 quently went through some two or three transformations, but was only 
 improved to a limited extent by being cast in halves to suit some pur- 
 poses, and in three sections for work of larger proportions. The first, 
 however, was a ring of No. 20 sheet iron, about 3^2 inches deep, and 
 perforated with holes, which, in the aggregate, were equal to or a little 
 in excess of the capacity of the supply pipe. Around this iron ring was 
 placed a hollow half-round ring made of copper, to receive and con- 
 fine a blast from a fan, or wind from a bellows. The copper was in- 
 closed as shown by section in the flanges of the iron ring, which was 
 closed down close to the hollow half-round copper ring top and bot- 
 tom. The supply pipe was flanged and riveted to the hollow copper 
 ring as shown, the supply pipe being about 2 inches in diameter. The 
 holes in iron ring were burred toward the inside, projecting enough to 
 assist in holding a coat of fire clay to protect the iron from the action 
 of the fire and keep the ring from burning. This answered for a time, 
 and was fairly successful, but many little difficulties, and sometimes 
 great ones, attended its use. The next pot, Fig. 299, was constructed 
 in a similar way ; but the iron ring was of boiler plate, about % inch 
 thick. This obviated the use of a fire-clay lining, and was a partial 
 success until we got a job for which it was not applicable, in conse- 
 quence of its being a complete ring. This compelled or suggested 
 that the pot should be made in two parts, which was done in the best 
 way that would answer the purpose. This one finally gave way to one 
 of cast iron, a little different in shape, but the same in principle. 
 
 Fig. 300 shows the shape of the last pattern, which was of cast iron. 
 It will be seen that the cavity for the blast was easily provided in 
 this form, and the inside wall was made thick enough to render the 
 lining unnecessary. With this pot the bottom of a joint could be more 
 successfully kept cool, so as to check the molten spelter from running 
 down too far, or leaking through the joint at the bottom. For gen- 
 eral purposes this was the best, and we are not aware that it has ever 
 
ART OF COPPERSMITHING. 1 77 
 
 been improved. Fig. 300 also shows a sectional view of this pot cut 
 through the feed pipe. For large work it is necessary to have the 
 blast let in on both sides, and sometimes in three directions, the pot 
 being then made in sections, with a feed pipe in each section, 
 care being taken that none of the inner holes are opposite the inlet 
 * last pipe. 
 
 Fig. 298.— First Form of Fire Pot. 
 
 Fig. 299. — Second Form of Fire Pot. 
 
 Fig. 300. — Cast-Iron Fire Pot. 
 
178 ART OF COPPERSMITHING. 
 
 FIRE POT SET FOR BRAZING JOINT. 
 
 We shall now proceed to make use of the fire pot, and describe the 
 process of hard soldering- or brazing by its aid. The pipe having been 
 placed into position, care is taken that the socket is level across the 
 brim, perhaps secured in the pit, or fastened to the forge or other 
 suitable and convenient place, so that the roller and chain overhead 
 is handy if necessary to the job. By referring to the engraving, Fig. 
 301, the clamp to hold up the pot is seen, which is made of 2^ x % 
 inch iron, the arms being formed so that they will clasp the pipe, and 
 are held there by two bolts, as shown. There may be space between 
 them, so that they could be used for different sized pipe. These 
 clamps are fastened up under the bottom of the socket, then the plates 
 which form the fire-pot bottom are laid on, as shown in Fig. 302. Now 
 spread a thin coat of moist fire clay over the plates, and hollow it up 
 the socket from 1 inch to 1^ inches. This is to keep the joint cool at 
 the bottom, so that as the spelter melts it will not run down through — 
 that is, not lower than the clay. Now place the fire pot in position, 
 as shown in Fig. 303. This is the most critical and important feature 
 of the work. Care must be taken to have the pot level with the 
 socket flange which is to hold the solder. The pot would be better 
 rather below than above, for if the spelter be too far out of the pot 
 the blast will be too low down, and if it be too low in the pot there is 
 danger of running out the seam in the upper pipe. Then, again, the 
 joint cannot be skimmed off handily or so well attended to. When 
 the pot is in position draw the clay around the bottom of it on the 
 outside, so that the flame will not escape between the pot and bottom 
 plates ; then apply the blast pipe. If the joint be less than 6 or 7 
 inches in diameter one blast pipe will be enough, if the blast is of 
 sufficient strength, but if the pipe to be joined be larger than 7 or 8 
 inches, then there should be two entries, as in Fig. 303. The joint is 
 now filled with clean mixed spelter and borax. If the joint to be made 
 is on brazed pipe, then spread a little of the moist fire clay over the 
 seam up to the rim of the socket. Fasten the two screw clamps, 
 Fig. 304, opposite each other on the top end of the pipe, and pass the 
 chain through them and hook in a link or hook around the chain. 
 
ART OF COPPERSMITH INC. 
 
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l8o ART OF COPPERSMITHING. 
 
 On the other end of the chain a counterbalance weight is attached, 
 nearly equal in weight to the male part of the job, or upper piece, or 
 the chain may be fastened to the hitching hook on the wall in such a 
 way that it will take the weight of the top piece of pipe while the 
 joint is hot. 
 
 We are now ready for the fire. First, place a little dead charcoal 
 on the wet clay, then put in a layer of live hot pieces, and cover them 
 with a few more dead ones, and fill up with nice clean coke of the 
 size of a walnut, covering the spelter some 2 inches ; that is, pile the 
 coke up around the pipe in a conical form from the edge of the pot, 
 Then let in the blast slowly and be patient until the joint is just red- 
 hot right through. While this is going on slowly, touch down the coke 
 into a compact mass. When the joint is red-hot take the coke back a 
 little from the pipe and dust a little freshly-powdered borax on the 
 spelter ; by this time the fire should be m good condition. Draw the 
 coke up to the pipe again and replenish the fire and let in the blast at 
 a brisk rate, keeping a watchful eye on the spelter and the blast slide. 
 When the spelter has run and the joint is full and well fluxed, skim 
 it off with a hot iron poker or a rod, Fig. 305, flattened at the end, 
 and stop the blast ; take off the pipes and lift the pot, then throw a 
 little common salt on the joint to kill the borax, which is hard on a 
 new file. In all cases the draft through the pipe should be stopped, 
 as the cold air going through tends to keep the joint cold, and in the 
 larger pipes greatly retards progress. The directions above given 
 are intended especially tor learners, although old hands would save 
 themselves some time, and often trouble, were they in the majority 
 of cases to follow them out. The practice in many shops is to make 
 a large fire on the brick forge, and then take a shovel full of hot 
 coke and fill the pot with it ; and a failure is often th e result. But 
 practice will partly balance the chances, because a man must make 
 himself acquainted with the " ropes " (customs) of the shop in which 
 he gets employment, no matter how absurd they are. Advance or 
 innovation is seldom countenanced by workmen without trouble. I 
 never failed when the fire was started with charcoal as above 
 
 directed. 
 
 Soft Soldering the Joint. 
 
 To make a soft solder joint, the fire pot is placed in position in 
 the same manner as for brazing, and charcoal is used in preference 
 to coke entirely. The solder is run from a suitable stick or from a 
 
ART OF COPPERSMITHING. 
 
 181 
 
 ^£"-"3°4- — Screw Clamps for 
 Holding Pipe. 
 
 Fig. 306. — Charcoal Fire Pot 
 Within a Pipe. 
 
 Fig. 305. — Skimming Rod. 
 
182 
 
 ART OF COPPERSMITHING. 
 
 ladle. Joints in small pipes may be made with the aid of a pair of 
 round tongs made hot. Joints in large pipes are sometimes more con- 
 veniently made by a pot of burning charcoal, Fig. 306, applied on the 
 inside, held by and lowered into the pipe with the chain, care being 
 taken to keep the lower end of the joint cool, and sizing the male 
 part with size made of lampblack or ivory black and gold size, or any 
 other pigment that will answer to prevent the solder from running 
 through the joint. The fire pot for large soft solder joints is made 
 to fit easily, and to hold a sufficient quantity of charcoal to /do the 
 work required. The bottom end of the pipe in this case is kept open 
 if possible, so as to permit the draft, which in the other case it is 
 necessary to stop. It will be seen that the bottom of the socket must 
 be kept cool enough to stop the solder from running through ; or the 
 possibility of a leak may be prevented by rubbing into the inside 
 some moist clay, if one can get to it to do so. 
 
ART OF COPPERSMITHING. 1 83 
 
 TEMPLATES. 
 
 Taking templates for bends is an important feature as an adjunct 
 to the successful performance of the operation of bending ; for if the 
 template be taken without a proper knowledge, trouble often ensues. 
 Many a good piece of work has been mutilated and valuable time con- 
 sumed by ignorance on the part of the maker of the bend, or the 
 maker of the template, or perhaps it should have been said, from the 
 want of a mutual understanding between them, when it happens that 
 the coppersmith does not take the template himself. Templates for 
 use at the bending block are usually made from an iron rod, which is 
 stiff enough to retain its form without fear of alteration while being 
 handled. It should be formed so that it will run through the center 
 of the pipe after it is bent. Templates for large work are usually 
 made by a pattern maker, showing the exact curve by cutting boards, 
 and nailing the flanges to them in the position desired. When the 
 position the pipe is to occupy affords sufficient space, due regard, care 
 and attention should be exercised so that the pipe when finished will 
 hang perpendicular, and lie horizontal, and the bends occupy as near 
 as practicable the center of the space through which the bends run — 
 that is, neither cramped nor straggling, but filling the space with a 
 flowing ease. Having the templates in proper shape, we will now 
 proceed to filling and bending. 
 
 FILLING AND BENDING. 
 
 All copper pipes and brass tubes should be carefully annealed 
 before bending— that is, that part which is to be bent ; the other ought 
 to be left hard. The part to be softened should when hot be a cherry 
 red in a clear north light (not sunshine); when cold the part to be 
 bent is filled with either lead or rosin, whichever is the more suitable 
 to the particular bend it is required to make. If the desired bend is 
 short— that is, part of a small circle— lead is the best for the pur- 
 pose, new soft lead without any foreign substance mingled with it. 
 If, on the other hand, an easy, flowing bend is desired, then rosin 
 is the best adapted to the nurpose. If the bend is to be made at the 
 end of a long pipe it is not necessary to fill it the whole length. We 
 
184 
 
 ART OF COPrERSMITHING. 
 
 Fig- 307.— Bending Block Arranged for Use Fig ' 2>oS.—Back Plate for Bending 
 with Back Plate and Center Pin. Block. 
 
 Fig. 309. — Bending Block Arranged for Use with Lead Piece and Back Plate. 
 
ART OF COPPERSMITHING. 1 85 
 
 usually roll up hard a ball of waste or paper and ram it in tight as far 
 as it is necessary to fill it, and then pour in the lead or rosin as the 
 case may be. When the work is done and the lead is out, heat the 
 pipe blood red and the wadding will fall out, or it may be blown out 
 by applying the blast pipe to it. We now proceed to the bending 
 block. The center pin is used when from the nature of the work noth- 
 ing will answer in its place. It is adapted to a great many forms of 
 bending which practice alone can teach the learner. It will be no 
 ticed in Fig. 308 that the back plate is a piece of iron, usually about 
 1% inches thick, with two legs, the top of the bending block having 
 four holes an equal distance apart at each corner to receive the two 
 legs on any side, so that with the center pin the bending may be 
 done on whichever side of the block is most convenient to the 
 operator. 
 
 Fig. 307 shows the block ready for bending. A, loop ; B, packing 
 C, lever ; D, pipe to be bent ; E, center pin, and F, back plate in po- 
 sition. The pipe is first marked by laying the straight part of the 
 template on the pipe and running the curved part along until the 
 straight part at the other end of the template lies level on the pipe 
 again, and marking with chalk where the bend begins and terminates 
 on the pipe. It is then laid between the pin and back plate, Fig. 307, 
 or put through the hole in the lead piece, as shown in Fig. 309. Be- 
 tween the plate and pipe is put a soft piece of wood or lead, and be- 
 tween the pin and pipe a piece of thick sheet lead ; these are to save 
 the pipe from being marked by the pressure exerted against the pin 
 and back plate in the operation of bending. (It is always necessary 
 to have a helper at the block when bending.) Now put the loop A on 
 the pipe and slip the lever C through it, which may be of iron or 
 wood — in some cases a wooden lever is the best, in others an iron one. 
 Then put a block of soft wood, B, between the lever and pipe. After 
 the loop is on one mark and the other mark behind the pin, or just 
 inside the hole in the lead piece, then apply the necessary pressure to 
 bend it to the required curve. The rope loop A, Fig. 307, is made of 
 one strand of rope and formed like a sailor's grommet. The copper 
 loop shown at the side in Fig. 309 is made of a strong piece of sheet 
 copper. Sometimes the rope is the best adapted to the, job in hand, 
 at other times the copper loop ; experience must dictate this. With 
 the apparatus described, pipes up to 5 inches in diameter may be bent. 
 If anything larger is needed, a hydraulic press must be provided. 
 
1 86 art of coppersmithing. 
 
 Made Bends. 
 Bends that are not filled and bent are made in two ways princi- 
 pally and in halves ; one way the seams are on the side, the other the 
 seams are in the throat and back. When the seams are on the side 
 the inner piece is called the saddle and the outer piece the back. To 
 make a bend saddle and back, take two strips of copper, each one-half 
 the circumference of the pipe in width ; let the saddle piece be nearly 
 the diameter of the pipe shorter than the back piece ; file the edges of 
 each piece up carefully, half round, so that there are no rough burrs 
 or small cracks left made by the shears in cutting the strips. Bend 
 each to the working template. It will be found that the saddle, as 
 the edges are being turned over on a mandrel, has a tendency to open 
 out straight ; this may be obviated by bending the saddle piece a 
 third smaller than the bend is required to be when finished, as shown 
 in Fig. 310 ; that is, if a mallet is used in making the saddle. If the 
 saddle is made with a hammer and drawn over on an anvil, the ham- 
 mer will curl it around enough to the template, because the edges-will 
 be drawn longer. When the work is performed with a mallet the 
 center is upset nearly as much as the edges of the strips are drawn, 
 and a more equalized thickness is obtained and therefore a better 
 bend. The back is turned similarly, under the same conditions, to 
 the saddle, and the edges are puckered or wrinkled at regular inter- 
 vals and then brought round to the template by hollowing in the cen- 
 ter of the back in a hollowing block, Fig. 311, allowing the wrinkles 
 to come up regularly until the back has curled round about a third 
 less circle than the template. Gradually work out the wrinkles, first 
 a little on one side and then on the other, over a J-stake, as shown in 
 Fig. 312, until they are worked down and the edges are smooth and 
 fit the edges of the saddle half. Then thin the edges with a double 
 paned hammer on the inside of the two halves, saddle and back, and 
 file the edges true along them. They will now be ready for softening 
 and cleaning, which is done at one and the same time by covering the 
 parts with strong brine of salt and water and heating to a cherry red 
 (out of the sunshine), and quenching in a vessel or trough of clear 
 water, and scouring with a clean tow wad and clean sand and water. 
 It is now ready for cramping, as shown in Fig. 310. When cramped, 
 open the cramps and bring the back to it ; let one go inside and one 
 outside ; pull them up together in a vise and wire them together, as 
 shown at D in Fig. 313. Dress down the cramps and hammer them 
 
ART OF COPPERSMITHING. 
 
 I8 7 
 
 Fig. 310. — Made Bends. —Seams 
 on\Sides. 
 
 Fig. 31 1 . — Hollowing Block for Forming 
 Made Bends. 
 
 Fig. 312.— Half Bend Being Worked 
 Over T-Stake. 
 
1 88 
 
 ART OF COPPERSMITHTNG. 
 
 Fig. 313. — Mandrel Block. — Lads Keyed to Bent 
 Mandrels. 
 
 Fig. 314. — A Cod. 
 
 \ / ,.--; 
 
 Fig. 315. — Made Bends. — Seams on Fig. 316. — Diagram Shoiving Size of Bend, 
 Throat and Back. 
 
ART OF COPPERSMITHING. 1 89 
 
 close and even on a bent mandrel and a cod to fit. A cod is an egg- 
 shaped casting, Fig. 314, having a square hole through its transverse 
 axis, so that it can be keyed on the end of a bent square mandrel, as 
 at D and E, one end of which is fastened in the mandrel block T, Fig. 
 313. After the cramps are hammered down smooth, chatter the joint, 
 when it is ready for charging with spelter and the fire. 
 
 Seam in Throat and Back. 
 
 We will now work on the other two halves, top and bottom, Fig. 
 315. In working these two halves into shape, the method usually 
 adopted by workmen is to draw the throat down on an anvil, and then 
 hollow up the back in a block ; but this is not satisfactory nor can a 
 real good job be done in this way, because the throat is drawn thin 
 too much by the hammering and there is difficulty in keeping the 
 work to the template ; then, again, there is an excess of stuff in the 
 back ; yet this method is still in use. While engaged at this kind of 
 work the writer discovered a very much better way by which the 
 throat is scarcely touched ; and when the bend is finally shaped 
 the throat is practically the same thickness as the sheet from which 
 it was cut. This method has never been taught to any one but one 
 apprentice boy, and it is given to the public now for the first time ; 
 that is, the formula. All bends are in the abstract but sections of 
 a hollow cylindrical ring, and a square bend is one-fourth of a hol- 
 low ring, having the straight part, if any, joined to it or left unbent. 
 A little mathematical knowledge is now required to be able to fully 
 understand the ground work or the theoretical part. Referring to 
 Fig. 316, let the inner dotted diameter of the diagram be equal to 
 9, and the diameter of pipe X equal 6 ; then the outside diameter 
 of the diagram will be 21. Now we want to unroll the outside edge 
 of one-halt of this hollow ring, see Fig. 317, wnen cut horizontally, 
 yy\ and form it into the frustum of a cone, E. To do this we pro- 
 ceed thus : First find the convex surface of the whole ring. Here 
 the inner diameter of the ring is 9, and the diameter of the thick- 
 ness or size of pipe is 6 ; then (9 + 6) x 6 = 15 x 6 = 90, and 90 x 
 (3.1416)' 2 = 90 x 9.8696 = 888.2685, tne convex surface of the whole 
 
 ring ; then 888 - z68 5 = 444 1342, one-half surface, and 444- 1342 = 
 
 2 7854 
 
 565.488 + . Now add the square of 9, the inner diameter of the bend 
 or ring, to this last result, and 565.488 + 81 = 646.488. Extracting the 
 
190 
 
 ART OF COPPERSMITHING. 
 
ART OF COPPERSMITHING. I9I 
 
 square root of this last sum gives us 25.4262, the outside diameter of 
 the circular disk G, Fig. 317. Now we want to transform this flat 
 disk ring G into a frustum of a cone, E, whose convex surface is 
 equal to the fiat disk ring G. Practice has shown that a frustum of a 
 cone formed of 315 of a circular ring is the best pitch it can have to 
 obtain the result required with the least work. To raise this disk to 
 
 a frustum of a cone proceed thus : 2 5-4 2 —^ = 14.5292, the radius 
 
 or slant hight of the complete cone of which the frustum E is a 
 part. Now take for a square bend one-fourth of 315 of circle D, or 
 78. 75 , F, and add to it whatever is required for the straight part at 
 either end, if any ; then round up the edges with a file (as before 
 directed), smooth, and it is ready for forming up into a half bend, pro- 
 ceeding as follows : Take two pieces of copper, F, and curl them round, 
 a third smaller in diameter, Fig. 318, in the throat than they are re- 
 quired to be, the circular part forming one-fourth of the cone E, and 
 turn them right and left in opposite directions, forming one-fourth of 
 a cone with the part intended to form the bend. Now turn the 
 throat in to begin the forming, A, Fig. 318 ; then turn the outer edge 
 up and pucker or wrinkle the edge at regular intervals, as shown in 
 B, Fig. 318 ; then take it to the hollowing block. Fig. 311, and sink it 
 in the hollow in the corner, letting the wrinkles come in regularly all 
 alike, until it is curled up enough, Fig. 319 ; now work out the 
 wrinkles, partly in the block on the inside and part on a cod outside, 
 until the edge is smooth and the two edges of the halves fit each 
 other, Fig. 320. Then thin the edges, file them true, cramp one-half 
 and bring the other to it and wire ; dress down the cramps and 
 •chatter the joint ; it is now ready for charging with solder and the 
 
 fire. 
 
 Template Boards. 
 
 The template boards are a very useful and convenient contrivance, 
 made for the purpose of substituting the position in which pipes are in- 
 tended to be coupled or occupy on an engine or tender or in a ship's 
 hold. The single board is shown in Fig. 321. This board, or rather 
 two boards, are hinged together at A and provided with two wings, 
 B, about 1 inch wide, similar to that of a pair of compasses. These 
 wings are fastened to the bottom leaf of the board, and slide through 
 a loop which is fastened to the side of the other leaf. The loop is 
 provided with a thumb screw, which holds the upright leaf in any 
 position the flanges of a pipe may require. The double board, Fig. 
 
192 
 
 ART OF COPPERSMITHING. 
 
 
 .& 
 
 'G 
 
 
 s 
 
 ^ 
 
 •2? 
 
ART OF COPPERSMITHING. 
 
 r 93> 
 
 322, is similar to the single board, but has two leaves. This board is 
 to take the set of S bends, which are set at right angles to each other, 
 as shown by the pipe standing on the double board, Fig. 322. Here 
 is an example of its practical use. It often happens in the case of 
 steam pipes, feed pipes and suction pipes that the pipe breaks off 
 close at the back of the flange A, Fig. 323, and the flange is not dam- 
 aged or the pipe either further than the flange being broken off, and 
 it is necessary to put the flange back on the pipe again without piec- 
 ing, and to have the bolt holes in the exact position after the pipe is 
 repaired as they were before the pip'e was broken. Suppose the pipe 
 is broken at the bottom flange C, Fig. 321. First match the fracture 
 and take a template of it on the board by making the board fit the 
 flanges, as shown. When they are in their true position, as they were 
 before the pipe broke, mark the flanges around with a pencil on the 
 board and all the bolt holes ; then make a chisel mark on the edge of 
 the flange, and at this point mark it on the board. Now all is ready 
 to proceed with the repairing. Anneal and clean the end of the pipe 
 inside and outside, and make a short thimble 2 inches long, D, Fig. 
 326, of light copper and fit it tight into the end of the pipe, and place 
 it so that when the flange is put on over it the thimble will come 
 through the flange E, Fig. 323, % inch. Braze the ferrule in the pipe 
 on two sides inside, and run off all the old solder from the flange A, 
 and when cool fit it to its place again, being careful to match the 
 fracture exactly and the holes and chisel mark on the template board. 
 Then turn the end of the ferrule over the flange, forming a rivet, 
 and draw the flange close to its place. Make a collar of a strip of 
 thick copper, B, Fig. 324, and scarf the ends, and after bending, C, 
 Fig. 325, put it around the fracture F, Fig. 327, making it wide enough 
 to cover the break % inch. Then wire it on tight, and after care- 
 fully charging it with solder around the top edge of the collar, sling 
 it over the fire and run the solder. When the solder is set the wire 
 may be taken off, while it is yet hot, quite easily. It the instruction 
 here given be carefully followed, a strong, substantial job will always 
 result. 
 
i 9 4 
 
 ART OF COPrERSMITHING. 
 
 Fig. 321. — Single Template Board. 
 
 Fig. 323. — Broken 
 Pipe. 
 
 Fig. 322. — Double Template Board. 
 
ART OF COPPERSMITH I NG. 
 
 195 
 
 itbuu^Miiii 
 
 Fig. 324. — Copper Strip. 
 
 Fig. 325.— Collar. 
 
 Fig. 326. — Thimble- 
 
 Fi?. 2,27.— Method of Mending Fracture. 
 
'ig6 ART OF COPPERSMITH I NG. 
 
 PATCHING PIPES. 
 
 Patching copper pipes, like most other branches of the copper- 
 smith's art, requires perception first, and then skill, with patient, per- 
 severing ingenuity. Pipes are liable to so many different kinds of 
 "fractures and breakages that one can hardly prescribe beforehand a 
 remedy suitable for all the many contingencies that may arise. We 
 will, therefore, mention a few occurrences that are happening fre- 
 quently, and let them act as stepping stones to the performance of 
 others that may call for the attention of the operator. It often 
 happens that pipes burst at the seam ; this may arise from one of 
 several causes — namely, from imperfect brazing, such as overheat- 
 ing while at the fire, or not enough heat to fuse the spelter so that it 
 firmly adheres, or from freezing, continual jar, overpressure from 
 force pump or flaws in the metal. If a fracture should occur from 
 overheating — that is, if the part has been burnt — it is best to cut it 
 out, as it can never be successfully repaired. 
 
 If ever so good a job be done it is all to no purpose, seeing the 
 foundation of the work has been made rotten, and it is useless, ex- 
 cept in cases of extreme emergency, to waste time or material on it. 
 If the fracture arises from the want of heat, or the spelter has not 
 been run enough to adhere to the joint, then open the joint and 
 properly clean it ; then close it down and give it a coat of warm 
 borax and water, the borax having been previously dissolved in 
 water ; jar this through the joint, then charge it with spelter, either 
 inside or outside, as seems best. If outside, the addition of a little 
 spelter inside will do no harm if care is taken to see that it is com- 
 pletely run. If from freezing, the fracture may be anywhere as well 
 as at the seam ; then the metal will be parted as if cut through with 
 a knife. If this be the case, file it down at the fracture, as at C in Fig. 
 328, so that where the split is the edge is thin, making a scarf 
 similar to those at the seam, and clean the split carefully on 
 the edges. Make the patch a, thinning the edges down to 
 a suitable thickness, b, and so that the edge of the patch will 
 just cover the outside edge of the scarf on the pipe at c. When 
 the patch is properly fitted, anneal it with some salt previously put 
 
ART OF COPPERSMITHING. 
 
 I 9 7 
 
 *V 
 
 s 
 
 ft 
 
 *, 
 
 § 
 
 £ 
 
 &■ 
 
 S3 
 
 to 
 
 J" 
 
 !& 
 
 -£?• 
 ^ 
 
 a 
 
 
 ^ 
 
 5> 
 
 
198 ART OF COPPERSMITHING. 
 
 over it ; when scoured clean cover it with a thin coat of fine spelter 
 and run it smooth at the fire, throwing off all that will leave it while 
 hot (this is to answer the same purpose as tinning). Wire the patch 
 to the pipe, as shown in Fig. 329, the wires being sufficiently close to 
 keep it from bagging when hot ; charge it with spelter, one-half on 
 the pipe and the other on the patch, then make the pipe red hot all 
 around at the back of the patch and along the length of it, preventing 
 oxidation of the spelter by a supply of borax. When sufficiently hot 
 gradually turn it over ana offer the spelter to a brisk fire. It should 
 run easily, and if carefully performed, a good, sound and durable job 
 will be insured. The cleaning off of the patch is next in order, which 
 may be done as tastily as the job will admit of, to make it look as if 
 the work had been performed by a mechanic. If a fracture is caused 
 by continual jar or overpressure by a force pump, it will in all proba- 
 bility be like that caused by freezing, and may be treated the same. 
 Flaws in the metal are from many causes, and their particular condi- 
 tion must govern the measures to be taken to remedy the defects. If 
 • in large work the flaws may be cut out and a piece cramped in or 
 riveted, and then brazed. It often happens that continual jar pro- 
 duces a lateral fracture at right angles to the length or around the 
 flange, immediately above the spelter. To repair this a collar e, Fig. 
 330, from y 2 to y± inch wide, is prepared of about the same thickness 
 as the pipe. The pipe is cleaned as far up as necessary, then the col- 
 lar is prepared to suit and covered with spelter as before directed, 
 then coiled around the pipe and wired close, as &X.d, Fig. 331, the wire 
 being placed on the upper edge of the collar to form additional room 
 to lay the solder, care being taken that the collar fits tight up to the pipe. 
 If the work is on a small pipe it is left open so that the heat may 
 readily run up through the pipe to assist in the running of the spelter 
 laid about the upper edge of the collar d. If it be a large pipe on 
 which the work is being performed, then the end is stopped with a 
 piece of sheet iron, clipped and bent at the edges, which is placed 
 about a foot up the pipe, instead of 3 or 4 inches, as when brazing on 
 flanges, as previously described. 
 
AKT OF COPPERSMITHING. 
 
 199 
 
 OUTLETS. 
 
 Outlets are made in two ways principally, and may be soft sol- 
 dered to their places, riveted and soft soldered, or brazed after bei^g 
 fixed in their positions, as the circumstances of the case may require. 
 In many kinds of work where outlets are necessary they are more 
 often soft soldered in place than brazed, but in marine work all are 
 brazed, excepting when they are worked out from the main pipe, and 
 can be of any size to suit the requirements of the work in hand. We 
 will suppose that in the example before us the pipe, Fig. 332, is 6 
 inches in diameter, and an outlet 3 inches in diameter is required at 
 the point V. A short piece of pipe to form the outlet, of the length 
 required, is cut to fit the pipe, the outlet being drawn a little taper- 
 ing at the bottom ; then the edges are rounded up smooth and free 
 from cracks, and a flange from y 2 to % inch wide is laid off from the 
 edge, the flange being next fitted close to the main pipe. The hole in 
 the main pipe is cut out about ]/ 2 inch smaller than the hole is required 
 to be when finished, and a bur is worked out from the main pipe, as 
 shown at T, and made to stand up % inch inside the outlet when it is 
 placed on the pipe. Let the bur fit close and snug on the inside of 
 the outlet, and the outlet flange fit nicely down on the main pipe. 
 When the flange on the outside is fitted, clean the place it is to occupy 
 by the heating process, using the salt and water pickle before making 
 hot ; also clean the outlet the same way. When this is done spread 
 an even coat of fine spelter on the flange of the outlet on the inside, 
 Fig 333, letting it extend as far into the outlet as the bur of 
 the main pipe is likely to reach. Now take it to the fire, and run the 
 solder smooth all around the flange, giving it a coat of spelter all 
 around evenly. (This is to answer the same purpose that tinning 
 does when making soft-solder joints.) Cool it in clear water, 
 when the face of the flange should look like a piece of 
 clean sheet brass. Place it in position and wire it fast 
 to the main pipe. It may now be brazed on the brick forge, 
 Fig- 334, by laying solder y 2 inch wide, more or less, around the joint, 
 one-half of which should be on the outlet flange, the other on the 
 
200 
 
 ART OF COPPERSM [THING. 
 
 ■Fig. 33 2 - — Manner of Attaching T-Joint to Pipe. 
 
 Fig. 333. — Outlet with Flange Covered 
 zvith Spelter. 
 
 Fig. 334.- — Brick Forge Used in Brazing. 
 
ART OF COPl'ERSMITHING. 
 
 20 1 
 
 \ 
 
 Fig. 335. — Balloon Fire Pot Used in Brazing. 
 
 Fig. 337. — Burring 
 Pin. 
 
 Fig. 336. — Working Outlets from Pipe. 
 
202 ART OF COPPERSMITHING. 
 
 main pipe ; heat the main pipe slowly until it is blood red in the 
 shade ; by this time the borax and spelter on the joint should have 
 the appearance as if varnish was among the spelter, caused by the 
 melting of the borax. Now offer the spelter to a brisk fire so it will 
 flow with ease and fill the joint right-through to the edge of the bur. 
 inside. If, however, it is inconvenient to handle the job by reason of 
 its size and weight, or some other contingency, a balloon fire may be 
 brought into service with advantage, and, as stated in a previous 
 article, the fire may be taken to the work, as in Fig. 335. This fire 
 pot is called a balloon fire pot from its similarity to a balloon. It is 
 made of boiler iron, and usually from 10 to 12 inches in diameter and 
 12 to 14 long, with a conical point at the bottom, at the end of which 
 is an opening about 2 inches in diameter, through which the flame is 
 driven by the blast, which is conveyed from the supply pipe to the pot 
 by means of a hose. The cover is a flat piece of heavy boiler plate. 
 Before using this fire pot it should be lined on the inside with about 
 ^ inch of fire clay. The work is first made ready for this fire by 
 heating it, as near as can practically be done, to a red heat, so that 
 the pot may not have to supply too much heat to the parts surround- 
 ing the joint, but that all its power or intensity may be concentrated 
 on the point where it is required and most necessary ; when this 
 instruction has been carried out the work is ready. The pot having 
 previously been hung in position, it is now filled with live hot coke, 
 which is made to lie compact in the pot, when it is then brought to 
 the joint and a brisk blast thrown on the spelter, which will quickly 
 run if it has been properly handled and kept in condition with a suf- 
 ficiency of borax, and the parts adjacent to the joint have been 
 kept hot. 
 
 Outlets intended to be soft soldered should be fitted with the 
 same care as are those for brazing, and may be riveted as at V, in Fig. 
 332, in addition ; in some cases this is quite necessary and should not 
 be omitted. To work outlets from the main pipe we proceed as fol- 
 lows : On the pipe, Fig. 336, at the point where the outlet is to be, 
 measure off the distance equal to one-half the circumference of the 
 outlet required ; from the two extremities of this half circumference, 
 and between them, measure each way a distance equal to the turn to 
 be made for the flange I. Now drill two small holes, and with a file 
 round up the edges of the holes smooth ; then insert the bar, Fig. 337, 
 and with the end jar or drive out the collar while the pipe is hot; 
 
ART OF COPPERSMITHING. 203 
 
 when it is out as far as necessary, slit it down between the holes as at 
 A, Fig. 336, and open it out until completed as shown. Care must be 
 taken to file the edges of the outlet up round and keep them that 
 way, so that no rough burs are left on. With ordinary mechanical 
 ability an outlet can be worked out from the main pipe long enough 
 to get on a flange, I, Fig. $$6, by which to make connections witt 
 other pipes. 
 
204 ART OF COPPERSMITHING. 
 
 EXPANSION JOINTS. 
 
 Expansion joints are used in places where a long length of pipe 
 is necessary to conduct steam or hot water from the boiler to its 
 destination. These joints are made of any required size to suit the 
 particular case, and are a means whereby the expansion caused by 
 the heat may be taken up, and when the contraction takes place on 
 cooling the deficiency may be supplied. Fig. 338 represents a broken 
 view of an expansion joint in its finished state. Now we desire the 
 easiest way to form this, so that the outer edge of the part intended 
 to supply the elasticity may be about one-half the thickness of the 
 original sheet from which it was cut, and give the required flexibil- 
 ity to the joint. First represent one-half the joint in outline, as in 
 Fig. 339, b d c e ; divide the diameter c d into six equal parts ; second* 
 divide the diameter b e into four equal parts, and through the points 
 /and h draw the lines f g and h g, passing through the points/ and 
 s j then, with the length of the curved lines, b d a.n<\ c e, measure off 
 a distance equal to them on the lines .$• h and / f extended, and with 
 the radius g v and g s describe the arcs x y and z n. Now develop or 
 unfold the convex surface of the frustum, Fig. 340, along the curved 
 line x y, making the line x y equal to the circumference of the trun- 
 cated cone, Fig. 340. Draw lines x z y n j then the pattern x y 11 z will, 
 when turned round, form the envelope of the surface of the trun- 
 cated cone, shown in Fig. 340. Having the pattern, two pieces are to 
 be cut from a sheet of copper of the required thickness. Thm the 
 edges, cramp them and make the joints by brazing ; when this has 
 been done, clean them off and knock them down ; then anneal. Mark 
 off with a gauge or racer, Fig. 341, the distance of the straight part 
 in Fig. 338, as further shown in O M, Fig. 342, and with a bullet ham- 
 mer inside, or a hammer pein outside, draw or stretch the edge one 
 course out ; now turn the big end up, and take a course around that 
 on the mandrel, Fig. 343, expanding or stretching the edge in each 
 course as indicated by the dotted lines is Fig. 342, annealing at the 
 end of each spell. When by these stretching courses the outer edges 
 are of the required size, turn it back again and with it hanging on the 
 mandrel, take in successive courses with a mallet until the straight 
 
ART OF COPPERSMTTITTNG. 
 
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ART OF COPPERSMITH ING. 
 
 207 
 
 part remaining is of the curve desired. True the job up, smooth and 
 planish on a suitable mandrel ; then turn up the bottom edge all 
 around, as shown in Fig. 338, and bring the other side to it and place 
 it inside this edge and close it down. Charge with spelter and braze 
 it round, then clean off the joint and braze on the flanges. 
 
 The foregoing specimen may be changed in form — that is to say, 
 instead of the outer edge being put together sharp, we sometimes 
 find it more suitable to make the edge round, as shown in Fig. 344. 
 The process of making this joint is similar to the last example up to 
 the point of preparing for putting together, when in this case the 
 edges should be worked up in an easy curve, so that when they are 
 brought together they would make a half circle, and form the out- 
 line of a body like an oblate spheroid or a skittle ball. The edges 
 are then cramped together, as shown, and after the seam has been 
 properly closed down on the head and bent shank, as represented in 
 Fig. 344, the work should be slung over the fire for brazing, and have 
 enough solder placed inside to flow around the seam. If carefully 
 charged, however, it may be soldered from the outside, being slung 
 at the fire in the same way. 
 
 Fig- 345 is similar also to the first pattern, Fig. 338, but made 
 double. The middle section in this one is made like the inside half 
 of a cylindrical ring or the outside rim of a pulley wheel. The two 
 outside pieces are made nearly like the single joint first described, 
 with the addition of the circular or saddle piece between them, as 
 shown in Figs. 345 and 346. Fig. 345 shows the joint put together ; 
 Fig. 346 shows them separated for closer inspection. This is called a 
 double joint, and will be readily understood from the engraving. 
 Fig. 347 is another form of expansion joint, which is frequently used 
 where there is plenty of room for it, and is a good device for the 
 ourpose for which it is intended. The engraving fully explains 
 itself. 
 
208 
 
 ART OF COPPERSMITHING. 
 
 Fig. 346.— Joint with Parts Separated. 
 
 Fig. 347. — Bent Pipe Expansion Joint. 
 
ART OF COPPERSMITHING. 
 
 209 
 
 TEE PIECES. 
 
 Tee pieces are made in several ways, but there are only two in 
 common use as a general rule. These are, when the three passages 
 are all of one size, as in Fig. 348, and when the inlet is equal to the 
 two outlets or the reverse, as in Figs. 349 and 350. The first is 
 formed by making two saddle pieces, a cap or bottom piece, and 
 gusset, A, as in Fig. 348. This piece of work would look better 
 without a gusset, as in Fig. 351, which can be done by leaving the 
 corners on the two saddle pieces aud squaring them up before 
 putting together ; but there is the advantage of economy in favor 
 of the gusset, as there is always a good supply of pieces available in 
 all shops. The tee in Fig. 349 is formed of two taper pieces, the large 
 end being equal to one-half the circumference of the inlet at one end 
 and half of the circumference of the outlet at the other. This can be 
 made with or without a gusset, as desired. The large end or stem 
 should be kept the same thickness or diameter right through to the 
 bottom or cap, and the other two taper off as if two frustums of 
 cones were joined together at the base, the small ends having a short 
 distance of them parallel from the end for a flange to fit on, to make 
 connections with other pipes. I have made small tees from one piece 
 cut from the sheet, as in Fig. 352, by working down the throats into 
 shape with a razing hammer and forming the two outlets by bending 
 the pattern in the middle and bringing the two edges together. The 
 stem is thus in two halves, while the part forming the two outlets is 
 one continuous piece, having the seam in the two throats, as in Fig. 
 352. There is no reason why a large one could not be made the same 
 way with economy in labor, but I never made one nor saw one made 
 
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 ART OF COPPERSMITPIING. 
 
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ART OF COPPERSMITHING. 211 
 
 THREE-WAY PIECES. 
 
 Three-way pieces, Fig. 353, are made by putting together three 
 saddle pieces and a gusset, the outlet pipes being an equal distance 
 apart and usually of one size. They sometimes require one outlet 
 equal to the other two in area. If the two inlets are made to approach 
 nearer to each other than in the three-way piece, and the outlet equal 
 in area to these two, as in Fig. 354, it is called abritch piece, and is 
 made of pieces similar to those described for Fig. 349, excepting the 
 crotch piece at the bend or turn is cut a third through on each side, as 
 shown, and a gusset, A, cramped in and brazed; then the other two side 
 pieces are brought together and wired, the seam dressed down and 
 then brazed. 
 
2 12 
 
 ART OF COPPERSMITH ING. 
 
 Pig. 353. — Three-Way Piece. 
 
 Fig. 354. — Britch-Piece with Large 
 Inlet. 
 
ART OF COPPERSMITH INC. 213 
 
 CROSS, OR FOUR-WAY, PIECES. 
 
 Small four-way pieces are made similar to three-way by joining 
 four saddle pieces together with a gusset, unless some special purpose 
 calls for another method. In large work two ways are adopted. 
 The first by cutting out two pieces as shown in Fig. 355, 
 and razing down the throats and making the four joints by cramp- 
 ing the pieces together in the four throats or saddles, and brazing. 
 The other by making it in two halves with the seam on the side and 
 cramping together, as shown in Fig. 356. To do this with the least 
 amount of labor, we must reduce the surface of one half of the piece 
 to a flat sheet of metal, as in Fig. 357, proceeding as follows : From 
 the point A, Fig. 358, with the radius A B, describe the arc B C ; divide 
 the arc B C into three equal parts ; through the two points B and D 
 draw the line G E ; on the opposite side of the figure draw E H, simi- 
 lar to G E; then B I H G will represent a frustum of a cone. Now 
 find the convex surface of the frustum which is thus represented 
 Let B I H G, Fig. 358, be a frustum of a cone, and let I B = 3 
 and H I = 4, and H G = 5. Then the convex surface of the frus- 
 tum = 3 + 5 x 3-141 _ ^ Q 2 6$6, an( j converting this into circular 
 
 2 
 
 or disk inches we have y' 2 5 _ 64. Now add the square of the di- 
 
 0.7854 4 
 
 ameter B I 3 2 = 9; then 64 4- 9 = 73, the convex surface of B I H G in 
 
 circular inches ; extracting the square root we have V 73 = 8.544, or a 
 
 disk of sheet metal 8 544 inches in diameter, as in Fig. 357. Draw the 
 
 line through the center O, and from the points P and G draw the lines 
 
 N P M and S G V at right angles with the diameter P G, and measure 
 
 off from the points P and G one-fourth of the circumference of I B 
 
 Fig. 358, making the lines M N and V S join R M and U N, which are 
 
 tangent to the circle. Then the pattern V S M N, Fig. 357, will equal 
 
 approximately the convex surface of E, Fig. 357. 
 
 Having cut two pieces of copper like the pattern in Fig. 357, they 
 
 are ready for forming after the edges have been rounded smooth. 
 
 Begin this process by wrinkling or puckering, as in Fig. 359, then with 
 
 the razing hammer, Fig. 360, raze the wrinkles down on a suitable 
 
214 
 
 ART OF COPPERSMITHING. 
 
 Fig. ^.-Pattern for One-Half of ^e.-Four- Way Piece Made of Two* 
 
 Four-Way Piece. n . . , 
 
 ■* Pieces, Seams on Side. 
 
 Fig. 357. — Method of Obtaining Pattern Fig. 358. — Diagram for Obtaining Pat- 
 for One-Half of Four- Way Piece E. tern for One-Half of Four- Way Piece. 
 
ART OF COPPERSMITHING. 
 
 215 
 
 Fig. 359. — Method of Forming E, Fig. 357. 
 
 Fig. 360. — Razing Hammer. 
 
 Fig. 36L — Mandrel for Working Out Four-Way Pieces. 
 
2l6 ART OF COPPERSMITHINO. 
 
 mandrel, Fig. 361 (secured in the mandrel block or bench strap), to 
 form the frustum, and when it is of a sufficient length turn the two 
 ends to form the cross way. 
 
 Practice and experience only can supply the place of an instructor 
 when making this bend. Care must be taken during the work not to 
 press it too severely or work the metal when it is too hard, but anneal 
 it at the close of every course ; when properly formed, the edges can 
 be trimmed off and thinned from the inside. Now take the crown of 
 the cone, about J4 inch from the edge, round up the edge free from 
 rags and chisel marks, and then turn out the edge level with and 
 forming a part of the outlet, thus extending its length that much 
 further. It is next covered with salt and water, made blood red and 
 quenched in clean water, scoured and dried. The halves, after one 
 has been cramped, are now brought together and wired ; the seam 
 dressed down and brazed, the work being slung in the traveler chain 
 from overhead if necessary. When the seams are cleaned off and the 
 work again scoured clean, it is put in shape and final symmetry on a 
 cod. The seam is knocked down and the piece planished over to 
 smooth and harden it. The mandrel, Fig. 361, is a piece of cast iron 
 or steel some 6 inches in diameter having a 2-inch square hole in the 
 center, so that it will slide on a square bar ; the four sides are planed, 
 turned or cast from a pattern so they are segments of four circles 
 from 9 to 20 inches in diameter, to suit the different sizes of pipes or 
 cylinders. The mandrel is about 3 feet in length. It is necessary to 
 have several of these mandrels of different sizes and lengths to suit 
 different work. 
 
ART OF COPI'ERSMITUING. • 217 
 
 THE SADDLE FIRE. 
 
 Bends made with the seams on the side are brazed on the brick 
 forge ; but those with the seam in the throat and back must have a 
 fire for the purpose, and made narrow enough to suit the curve of the 
 throat seam. This fire is very useful for a great many special pur- 
 poses besides the one under consideration. It is made of pieces of 
 >4-inch boiler iron, Fig. 362, with four legs made of angle iron ; the 
 hight of the fire being the same as the brick forge. This fire is about 
 6 inches wide, 18 inches at the bottom where the blast pipe lies, and 
 24 inches at the top, and 10 or 12 inches deep. It is coated with an 
 inch of fire clay, and left to dry hard ; it is then fit for use. It could 
 be lined with fire tiles inside, made to fit, which would be better, if 
 they are obtainable ; if not, then fire clay must be used. The blast 
 pipe, Fig. 363, at the bottom of the forge, is perforated with holes, 
 whose aggregate area is equal to about twice the area of the convey- 
 ing blast pipes, because when necessary the wind is let in at both 
 ends. There should be two fires of this kind, one hollowed out, as it 
 were, to fit the pipe nearly, Fig. 362 ; the other straight across, Fig. 
 364, as they are often very convenient. 
 
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 ART OF COPPERSMITHING. 
 
 
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ART OF COPPERSMITHING. 219 
 
 MARINE WORK. 
 
 In the preceding chapter we have been speaking of small bends ot 
 from 4 to 5 inches inside diameter, which is the largest size usually 
 made in locomotive works or railway shops. Marine work for war 
 ships or ocean steamers is very much larger, requiring heavier tools 
 and appliances, and we shall now describe some of the means em- 
 ployed in the working up or making of pipes and bends from 6 to 15 
 inches in diameter and upward. By a careful study of the engravings, 
 Figs. 365 and 366, which we here present, * the reader can get a better 
 idea of what marine work is than by the best written description with 
 out their aid. These large pipes and bends here represented in Fig. 
 365, judging by the bench vise, the jaws of which usually measure 
 from 5 to 6 inches wide, are about 15 inches in diameter, and, as will 
 be noticed, the bends are made saddle and back, which is the usual 
 "way of making tnem when the bend required is of a reasonably long 
 curve. A specimen may be seen in the middle of the two pipes, one 
 of which is slung over a fire, the back being slung to the traveler by 
 suitable hooks and in position for annealing. The large pipe slung 
 on the right-hand side of this back has just had. a flange brazed on ; 
 the one on the left hand, it will be seen, is in position, and 
 has a fire pot placed around it, for brazing a round joint, or 
 joining this bend to another pipe. Carefully notice the standards 
 upon which the bottom or floor of the fire pot is arranged. The pot 
 ■appears to have two inlets for the blast, one on each side of the pot, 
 so that the fire may be regulated in such a manner that all the solder 
 will be run at the same moment of time, and the joint skimmed off 
 all round instantly when ready. A little at one side of this pipe is an 
 open hearth under a chimney, where the coke is prepared and made 
 hot for the fire pot, a pan of coke being at hand. The apparatus oppo- 
 site the hearth is for straightening and rounding up the pipe after the 
 seam is made. The bend, which is slung and balanced at the vise 
 
 * These engravings are from photographic views of the interior of the coppersmiths' 
 shop of Messrs. 'Maudsley, Sons & Field, one of the oldest and largest marine engine 
 builders of London, England, and kindly furnished by them especially for this work. 
 
220 ART OF COPPERSMITHING. 
 
 uench, is in position for truing up and planishing on a cod. The next, 
 object is a wooden template for a pipe with two short bends in it, and. 
 showing the position of the flanges ; further on are two breech pieces, 
 which appear to have their seams recently soldered or brazed to- 
 gether, the seams being in the saddles or throats — that is, they are 
 made in halves and from a sheet about a quarter inch thick. The 
 several other pipes lying around are of minor interest, but the view, 
 as a whole, gives a clear idea to the learner and those interested of 
 what is necessary for a well-appointed shop. In the other plate, Fig. 
 366, the first object on the left hand is an old bending apparatus, 
 which no doubt is still found to be very handy. The next is a large 
 bend, apparently about 20 inches in diameter. The main object is a 
 hydraulic bending table, the whole machine being clearly shown, with 
 a pipe about 8 inches in diameter in position for bending, and having 
 one bend already completed. Carefully examine this machine. 
 The hydraulic cylinder and piston are placed in an immov- 
 able position at the table, and before it in a groove in the 
 table is a large screw, to which is attached the handle on 
 the right hand of the table. The two upright pillars on which 
 the concave blocks revolve are drawn together or spread apart by a left 
 and right thread, the link placed over the pillars being to regulate 
 and hold the pillars securely to the place required. These concave 
 blocks revolve to suit the condition of the pipe as the power of the 
 piston is exerted to bend the pipe between them. The workman's 
 chalk mark is plainly visible, showing where the bending is to be, or 
 the power applied to effect the bending. The link which helps to 
 hold the pillars in position is provided with a screw and sliding block 
 so that it may be lengthened or shortened to suit the distance the 
 pillars are required to stand apart. Another and longer link is lying 
 on the floor to be used for longer bends. The next prominent object 
 is a pipe with a double bend. These bends have been soldered together 
 just where the workman's file is lying, and the joint has been made 
 with a round fire such as we have described in a previous chapter. 
 Behind this pipe is the back of a bend in course of construction. The 
 block on which it is being worked is cubical and made of cast iron 
 or some hard wood. The holes or hollows are plainly shown in the 
 block, and each face has a different size and hollow to suit different 
 sized pipe. Notice the travelers at each mandrel loop along the 
 bench and at other parts of the shop which show how the work may 
 
Fig. 365. — Interior Viezv of Coppersmith Sh 
 
Fig. 365. — Interior View of Coppersmith Shop of 
 
 Maudsley, Sons & Field. 
 
 [221] 
 
[222] 
 
 Fig. ^.—Interior View of Coppersmith Shop of Maudsley, Sons & Field. 
 
op of Maudsley, Sons & Field. 
 
 [221] 
 
ART OF COPPERSMITHING. 223 
 
 be slung and manipulated with as much ease as possible. These views 
 were taken from opposite corners of the shop, so that all the most 
 important appliances could be clearly shown. The other objects are 
 of minor interest.* As I have said before, these larger bends can be 
 and are made saddle and back, according to the capacity of the work- 
 man or the desire of the employer ; but much better results may be 
 obtained by competent workmen when the seam is in the throat and 
 back, especially if the inside curve of the bend is short or of small 
 diameter. 
 
 * These photographs have only been recently obtained. When the articles were written 
 they were entirely from memory, and after 20 years' absence from a coppersmith's shop I 
 notice by them there has been no material advance. 
 
224 ART 0F COPPERSMITHING. 
 
 MAKING LARGE BENDS. 
 
 The large bends, Fig. 367, cannot be brought together after being 
 formed by a vise ; it is therefore necessary to use a chain and lugs, A, 
 and pull the halves together with a bolt. Neither can they be dragged 
 along on the fire, owing to their weight, which would crush the coke 
 and break down the fire, besides exposing the joint to probable injury 
 while hot. They must be slung as shown in the illustration, so that 
 the joint will lie level when on the side, and so that it can be brought 
 to the fire continuously and with ease. When the slinging chains are 
 properly adjusted, the sling is hooked to the traveler chain overhead, 
 and the work may then be handled over the fire with ease. In the 
 case of the joints being in the throat and back, as in Fig. 368, the 
 halves are brought together with the chain and lugs as before 
 directed, and then wired ; then two screw clamps N and U are 
 fastened at each end, through which chain M is passed loosely. A 
 hook and pulley, O, are now applied, the loose chain running through 
 the clamps over the pulley wheel and the hook hooked to the traveler 
 chain P from overhead, as before. By this means the throat seam 
 may be easily handled, as also the back one, reversing the screw 
 clamps to suit, as in Fig. 369, and guiding the work with the tongs K. 
 A good fire is to be kindled in the forge, Fig. 362, with a supply of 
 coke in the pans or hoppers on each side. The back of the bend is 
 usually brazed first on the brick forge, and then the throat on the 
 portable forge, Fig. 362. It sometimes happens that a job cannot be 
 got at even with this narrow forge fire, or there is no convenience by 
 which it can be used to advantage. When this is the case we carry 
 the fire to the job, instead of the job to the fire, and charge the joint 
 with spelter outside, carrying the fire inside with a pot having a 
 hose pipe attached to it, Fig. 370, and slinging the fire on the traveler 
 chain from overhead. The fire pot for this operation is made similar 
 to those used for the joining of pipes, but with a bottom fixed to it. 
 The work to be done governs the size and shape ; it may need to be 
 of an oval shape in some cases. 
 
ART OF COPPF.RSMITHING. 
 
 5? 
 
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226 
 
 ART OF COPPERSMITHINGt- 
 
 Fig. 369. — Bend Reversed and with Tongs for Guiding. 
 
 Fig. 370. — For table Fire Pot to go Inside of Bends. 
 
ART OF COPPEKSMITHING. 227 
 
 DOUBLE BENDS. 
 
 In large work we have only noticed so far single bends. We now 
 come to double ones, which are, as occasion requires, twisted from a 
 flat S-bend to any engle required. When bends require to be twisted 
 they are made single and then joined and brazed together, as in Fig. 
 371. The operation is the same in principle as that described for 
 joining straight pipe, the difference being only in the size of the fire 
 pot arid the manner of application, which is shown in Fig. 372. Four 
 upright standards, with holes in them, are placed in position near the 
 pipes, and the bottom plates laid on the two rods, which are put 
 through the holes in the standards at the proper hight. The bottom 
 bend is held in position so that the socket is level and securely 
 fastened there, the top bend held in position and balanced with the 
 traveler chain and then lowered into the socket. The pot is then 
 placed around the joint as before directed, Fig. 373, which may be in 
 two or three sections, see Fig. 374, so the blast can be applied by two 
 or three supply pipes, as is most convenient or may be desired to suit 
 the work in hand. After the seams of each bend have been dressed 
 off clean and are in proper shape, they are cleaned with a pickle made 
 of vitriol and water, about one part vitriol and two parts water, which 
 may be varied to suit the requirements of the job. When it is 
 thoroughly scoured and all the acid washed off in clean water and 
 dried, it is usual to rub some dry Spanish brown all over, so that in 
 hammering the hammer marks can be more plainly seen. It is then 
 taken to the mandrel block, where it is planished true and into its 
 final shape on a cod, and hardened by closing the grain of the metal 
 with a hammer at the same time that it is planished. 
 
228 
 
 ART OF COPPERSMITHING. 
 
 Fig. 371. — S- Bends Made by Joining 
 
 Fig. 372. — Bends at Right Angles Arranged 
 for Brazing. 
 
ART OF COrPERSMITHING. 
 
 229 
 
 Fig. 373. — Fire Pot in Position for Brazing. 
 
 Fig. 374. — Viezu of Fire Pot. 
 
230 ART OF COPPERSMITHING. 
 
 BRAZING ON FLANGES. 
 
 The brazing on of flanges, large and small, has caused as much or 
 more objectionable language to be uttered than almost any other 
 operation usually performed in a coppersmith's shop, owing princi- 
 pally to a want of a little knowledge, or the possession of an inquiring 
 mind ; sometimes, too, owing to the greed of a manufacturer 
 who will palm off a flange for pure copper that will not bear 
 enough heat to' run the spelter. This entails much trouble and 
 annoyance to the workman, and not a little loss to themselves, 
 because the extra time spent and liability of failure more than 
 balances the advantage sought to be gained by the use of spurious 
 metal. In speaking thus I do not wish it understood that pure cop- 
 per is the best material from which flanges can be made, for the 
 best flanges the writer ever operated on were cast from a mixture 
 composed of 1 pound of old copper and 1 pound of brass tubes, which 
 reduced to its elements would make the flange about 16 parts 
 copper and 3 of zinc ; this makes the flange stiff and close 
 grained, and much better for general purposes than pure copper. 
 Having a good flange provided, the next thing is to have it properly 
 prepared while at the lathe ; the only thing, however, that concerns 
 the coppersmith is the hole into which the pipe is to fit. This should 
 be tapered }i inch so that it will drive on tight, the end of the 
 pipe being reduced that much. On the face side an eighth counter- 
 sink should extend into the hole one-fourth of its thickness. When 
 the flange is eased on the end of the pipe and the pipe is through a 
 short distance, drive it back into the countersink, turning it over a 
 little toward the face of the flange. It is now ready so far for braz- 
 ing, but before taking it to the fire, if the pipe is small, it is sufficient 
 to stop the opposite end of the pipe with a ball of waste or a wooden 
 plug, so that the heat cannot run up through the pipe. Around the 
 countersink of the pipe, which is through the flange, rub some soft fire 
 clay, and a little up the seam if it be brazed pipe. It is now ready 
 for charging and the fire. Flanges for large pipes are bored the same 
 as small ones, but it is necessary to take a little more precaution in 
 preparing for the fire, so that the heat does not run up through the 
 
ART OF COPPERSMITHING. 231 
 
 pipe. In this case take a disk of light sheet iron about 3 or 4 inches 
 larger than the diameter of the pipe and clip this disk all around with 
 the shears at intervals of about 1 inch ; now turn the edges up, form- 
 ing a kind of pan, the places clipped acting as a spring. This pan is 
 crowded into the end of the pipe about 4 or 5 inches from the end, and 
 some soft fire clay is plastered in the cracks of the pan all around the 
 edge, and also around the edge of the countersink of the flange. The 
 edge of the fire clay should be an inch or two above the flange, or above 
 the thickness of the flange, and so that no flame goes up the pipe. 
 See that the joint of the pipe is welLcovered with clay a little beyond 
 the top of the flange where the solder is to lay. Sling the pipe so 
 that it will hang level, and it is ready for charging and the fire. If 
 the flanges are of doubtful metal, try their quality before putting on 
 the pipe by trying to run a small portion of the spelcer on the flange 
 first. If it is suspected that the spelter will not run on the flange, it 
 should be rerun — that is, remade — to do which take 1 pound of the 
 spelter and melt it and add 1 ounce of zinc while it is in a state 
 of fusion, and when cool enough to just char a hazel stick, place 
 it in an iron mortar previously made warm, and break it up again. 
 Then try it on the flange. If it still takes too much heat, or 
 more than it is thought the flange will bear, lower it again with zinc 
 until it runs at a low enough temperature to preserve the flange and 
 there will be no danger of failure. Never use what is called black 
 solder or spelter ; it is only used by those wanting a sufficient knowl- 
 edge concerning spelters suitable for their work ; neither be tempted 
 to add tin under any circumstances. 
 
232 ART OF COPPERSMITHING. 
 
 SHORT BENDS. 
 
 Another bend of a special kind is sometimes needed to be worked 
 on the end of pipes when it is required to get the shortest possible 
 turn that can be made so that a flange will set right down close on the 
 straight part of the pipe, as in Fig. 375. To turn this bend we proceed 
 as follows : First measure along the pipe a length equal to one-half the 
 circumference of the pipe on which it is required to make the turn, 
 Fig- 376., At the point B make a small hole, and with a round file 
 round up the edge all around the hole carefully. Now take the steer 
 bar, Fig. 377, having the point bent as shown, make the pipe red hot 
 about the hole, insert the point of the steel bar and jar it out with a. 
 hammer, as shown in Fig. 378, until there is a burr or turn, C, as high as_ 
 the flange is thick on the long part. Then cut the pipe from the hole 
 to the end, as in Fig. 379, and run out the seam at the back if it is a, 
 brazed pipe. If it is drawn pipe make a hole at the back or opposite 
 side (without burring), and cut the pipe down as far as this hole and. 
 open it out, as in Fig. 380. Flatten out the flaps. Then with the radius 
 of a circle whose circumference would be equal to one-half of the cir- 
 cumference of the pipe describe the curve shown in Fig. 380, E, and; 
 from the line where the burr or bend turns take 78.750 of the circle (as 
 shown in a former chapter), of which the section X is a part. Now 
 thin the back edges of the flaps of the turn, Fig. 381, and work them> 
 over on a cod or some suitable bullet stake, and if large enough cramp it; 
 then close the seam, and finish by brazing, Fig, 382. This is a method 
 of making a short turn which it is often necessary to adopt in steam- 
 boat work, and when it happens that workmen do not know how to 
 make this turn a casting has to take its place at a much, greater cost. 
 
ART OF COPPERSMITIIINr,. 
 
 233 
 
 Fig. 375. — Short Bend. 
 
 Fig. 379. — Manner of Cutting Pipe. 
 
 tig. 376. — Pipe Measured for Bend. 
 
 Fig. 380. — Pipe Opened Out. 
 
 Pigr, 377. — Burring Bar, for Enlarging 
 Hole for Bend. 
 
 Fiz. 381. — Fdo-es Thinned. 
 
 Fig. 378. — Enlarging Hole with Bar. 
 
 Pig. 382. — The Pinished Bend. 
 
234 ART 0F COPPERSMITHING. 
 
 AIR PIPES. 
 
 Air pipes are used by ocean and other steamers for conveying 
 fresh air from the upper to the lower decks and are somewhat similar 
 in form to the bowl of a tobacco pipe, Fig. 383. They are frequently 
 made of copper, the mouth being of any size required to catch and 
 convey a sufficient quantity of air to the lower decks and cabins. 
 When made of copper, the easiest and most economical way is to make 
 the bend of three pieces or sections, as shown in Fig. 384. After the 
 pattern has been cut out, the pieces, b and c, Fig. 385, are thinned at 
 each end and cramped ; they are then bent, as in Fig. 386, and held to- 
 gether with dogs, dor f, Fi^s. 387 and 388, at each side, as shown. 
 
 Now wrap a chain around the section, as in Fig. 386, and sling it 
 to the traveler so that it hangs level. Take a little warm borax and 
 water, the borax having been previously dissolved, and jar the joint 
 so that some of the liquid may penetrate through and all around and 
 under the cramps in the joint, then charge it, laying the spelter on 
 first with a short reed. Move the spelter over the edge of each 
 cramp in a zigzag form, then slowly dry it ; when dry, slowly heat it, 
 first on one side and then on the other, until the part is red hot and 
 the spelter is all down on the joint ; next bring it over a brisk flame 
 and run down the seam. The directions given may be followed for 
 the other two sections. When the seams are cleaned off and knocked 
 down and the sections annealed, open them and round them up on 
 the mandrel block for the next step, which will be to draw the edges 
 in at the back part extending to one-fourth of the circumference 
 from the center of the back each way. This is done on a suitable 
 head, Fig. 390, secured on a bent bar fastened in the mandrel 
 block B, the part drawn in forming part of the regular curve 
 and some 2 or 3 inches wide. When* this is done sufficiently, 
 pare the edges true, and see that the two parts which are to be 
 joined together are exactly the same size in diameter, or as 
 near so as possible ; then thin them with a hammer, which may 
 need to be done with the pane if the copper is heavy, or with the face 
 if it is light. When the edges are thinned and the ragged edges, if any, 
 
ART OF COPPERSMITH! NG. 
 
 2^5 
 
 
236 
 
 ART OF COPPERSMITHING. 
 
 Fig- 385- — Pattern of Air Pipe Section. 
 
 Fig. 387.— Spring Dog. Fig. 388.— Screw Dog, 
 
 Fig. 386.— Section of Air Pipe Ready 
 for Brazing Seam. 
 
 Fig. 389. — Chain Hook. 
 
ART OF COPPERSMITH I NG. 
 
 237 
 
 ■Fig- 39°-— Planishing the Air Pipe on Head and Mandrel. 
 
 Fig. 391. — Mandrel on Trestle Frame. 
 
2^8 ART OF COPPERSMITHING. 
 
 filed smooth cramp one side, making the cramps which will be on the 
 inside one-half longer than those on the outside. Bring them together 
 and secure with the lugs and chain, as in Fig. 384, the hooks g, Fig. 389, 
 being made to hook on the ends of the pipe. When the seam is closed 
 down true make a suitable cradle with wire and sling it, and proceed 
 to charge the cramps, following them in their zigzag path so that the 
 spelter covers the edges of the cramps, not forgetting to jar through 
 it previously a solution of borax. Dry the spelter and heat the joint 
 slowly. When hot enough show it to a medium brisk fire and run the 
 joint around. After the circular joints are made, knocked down and 
 annealed, scour it clean with vitriol and water and rinse off clean and 
 dry it. When dry rub it over with Spanish brown. Now shape it up 
 true and planish on the double-faced head, Fig. 390, at the mandrel 
 block, finishing the small end on the mandrel C. The endless rope 
 and small pulley D has a weight hung to it sufficiently heavy to coun- 
 terbalance the weight at the large end. The chain and pulley E and 
 sling hooked to the traveler chain assists the operator by balancing 
 the work and giving him power to manipulate it with ease. 
 
 The straight conductor pipe to convey the air to its destination 
 is usually of light copper and made in lengths of from 6 to 8 feet 
 long. Straight steam pipes may be made from material from yk 
 to % inch thick and from 6 to 8 feet long. To planish these pipes 
 after being made and properly cleaned a mandrel is placed on a tres- 
 tle frame, Fig. 391, which supports the bar at both ends, or one end 
 may be secured in the mandrel block and a screw crutch, A, Fig. 392, 
 placed under it at the other end to support it. The mandrel should 
 run through the entire length of the pipe, or as nearly so as is prac- 
 ticable. 
 
 The planishing should begin in the middle and finish at the ends; 
 that is, about 2 feet at a time, beginning with the first 2 feet in the 
 middle of the pipe, then finishing up at the joint after the planishing 
 of the whole length has previously been completed. The planishing 
 is done with a bright double-faced hammer, No. 3, Fig. 393, of suffi- 
 cient weight, a number of which form the necessary equipments of a 
 shop, and vary in size and weight from 8 ounces to 3 pounds or more, 
 having square and round, flat and bullet faces, others having two 
 panes for razing down, and bullet faces for hollowing up. These 
 hammers are carefully looked after, and kept bright by being cleaned 
 on a buff-board before being put away in the rack, and greasing with 
 
ART OF COPPERSMITH I NG. 
 
 2 3 9 
 
 Fig. 39 2 -— Mandrel for Planishing Long Pipes. 
 
 Fig- 393- — Hammer Rack. 
 
240 AUT OF COPPERSMITHING. 
 
 pure goose grease to protect them from the various gases and acid 
 vapors which always occupy a coppersmith's shop more or less. The 
 hammers shown in the rack, Fig. 393, are No. 1 round face and pane; 
 No. 2 round and square face ; No. 3 two round faces ; No. 4 cross 
 paned ; No. 5 two flat paned ; No. 6 bullet or hollowing. 
 
ART OF COPPERSMITHING. 24 L 
 
 HOLLOW SPHERES. 
 
 The forming- of spheres or balls has taxed the ingenuity of the 
 youthful metal worker, it is presumed, in all ages ; the coppersmiths 
 of my youth have, and those at present engaged in the craft will con- 
 tinue an ineffectual wrestle with this problem until there is a more 
 universal application of the system of industrial or technical educa- 
 tion so happily inaugurated now in some of the large cities. How 
 strange it is that our public educators scarcely ever seem to venture 
 from the beaten paths of school book routine for the purpose of 
 assisting the student to grasp a subject or shed a little light by 
 which a pupil can mark out his course prior to an apprenticeship 
 The properties of circles, squares, cubes and spheres are all Greek to 
 the majority of boys sent into a shop ostensibly to learn a trade, 
 and particularly does this happen in country places, as in the writer's 
 case, where among all the men he was brought in contact with it is 
 not remembered that one could measure the superficial area or solid 
 contents of a single vessel they were working at in a mathematical 
 way ; it seemed one continual grope in the dark, guessing, or work- 
 ing by rule of thumb. It is hoped that this chapter may be so clear 
 that any one who will exert an effort to make himself familiar with 
 any ordinary work on mensuration will be able to form a hollow 
 sphere of any metal ductile enough to bear the different operations 
 necessary to its formation. The greatest stumbling block has been 
 a want of knowledge as to the exact size of patterns necessary to 
 cover the surface. It is a well known property to those versed in 
 geometry that the convex surface of a sphere is equal to its circum- 
 scribed cylinder, or the surface of a sphere is equal to four times its 
 generating circle ; that is, the surface of a sphere is equal in area to 
 that of four disks whose diameter is the same as that of the sphere. 
 Then the surface of one-half a sphere would be equal to two disks 
 the same diameter as the given sphere. Now, as hollow spheres, or 
 balls, are usually raised up in halves, therefore to make a ball we 
 must first start with two disks of metal, the surface of each being 
 equal in area to the sum of two others whose diameters are the same 
 
242 
 
 ART OF COPPERSMITHING. 
 
 Fig. 394. — Disk for Half Ball. 
 
 bi%. 395. — Disk Wrinkled for Forming. 
 
 Fig. 396. — Disk with Wrinkles Partly 
 Drawn Out. 
 
AR'I Of* (OITKRSMITIIING. 243 
 
 as the diameter of the hollow sphere required ; that is, the two taken 
 together shall equal four times the surface of a circle whose diam- 
 eter is equal to the diameter of the ball required. 
 
 Let it be required to make a hollow sphere, or ball, 9 inches in 
 diameter; then 9x9x2 — 162, the number of circular inches in the 
 convex surface of one-half a sphere 9 inches in diameter; therefore, 
 
 V- 
 
 9X9x2 = 12.729, the diameter of a disk of metal required to 
 
 make one-half a hollow sphere, or ball, .9 inches in diameter, no allow- 
 ance being made for the thickness of metal or for joining together. 
 Let us add these now, and suppose the metal to be }$ inch thick, and 
 that the joint requires ^-inch lap, which will be a quarter on each 
 half; then the area of this }4 -inch band for lap or joint will equal 
 9.125 x 3.1416 x .5 = 14-3335- Converting this into circular inches we 
 
 have — -j— = 18.25. Dividing this by 2 and giving one-half to 
 
 18.25 
 each disk we have — = 9.125. Therefore, the whole value of one 
 
 disk for one-half of a 9-1'nch hollow sphere }£ inch thick, and % inch 
 for lap will be (9.125) 2 x 2 + /9.125 x 3.1416 X5 + .7854^ = 175.6562 
 
 2 ' 
 
 and extracting the square root of this last result we have 13.2535, the 
 size of a disk required for one-half the ball. 
 
 We will now proceed to raise these halves to the spherical form. 
 First, divide the diameter A D, Fig. 394, into four parts, as shown by 
 A B C D, and with the radius B O describe the circle B C, which will 
 be about fc/% inches in diameter. Wrinkle the disks in spaces of 
 about 2 inches apart at the outer edge, forming a pan, as shoMrn in 
 Fi g- 395 ; now take ^ to tne noor block, Fig. 397, and on a suitable 
 bullet head in the shank S take in the first course, draw out the 
 wrinkles, working first on one side of each one, as in Fig. 396, and 
 then on the other until they are all worked out and are smoothed 
 down. Now smooth it some with the face of a hammer. This will 
 conclude the first spell. Anneal it by heating to a cherry red, cool in 
 water and wrinkle again, making the wrinkles which were the lower 
 ones in the first spell the upper ones in the second, and continue the 
 process with the razing hammer until the last course. This is brought 
 up to the size without wrinkling. It should be a little under size, 
 because smoothing and planishing will expand or draw it some, there- 
 
244 
 
 ART OF COPPERSMITH TNG. 
 
 Fig. 397. — Floor Block with Stakes and Head for Forming Half Balls. 
 
 Fig. 398. — Section Showing How Half 
 Ball is Fortned. 
 
 Fig. 399. — Finished Half Ball. 
 
ART OF COPPERSMITHING. 245 
 
 fore it may be about 8j4 inches in diameter when finishing the last 
 course before smoothing - . We now are supposed to have two pans as 
 shown at R in Fig. 398, that are about 6 inches at the bottom, and 
 4% inches at the side. These are to be taken to the block and on a 
 suitable bullet head, S, or bullet stake, T, Fig. 397, break down the lag 
 or corner of each pan with a mallet. As this is being done, the curve 
 will be bulged out, part in the bottom and part in the side, as indi- 
 cated by the dotted lines in Fig. 398. It is now easy to smooth them 
 down true to the size required, after which anneal, clean and planish, 
 as in Fig. 399. They are then ready to put together and finish the 
 sphere. 
 
 The directions in the foregoing are for metallic balls raised or 
 formed of two solid pieces or halves — that is, with the middle seam 
 only. It often happens, however, that time is an object in the con- 
 struction, as also sheet metal of a sufficient size or convenient shape 
 from which to make a ball in two solid parts. When this is the case, 
 it may be made in this way : Let it be required to construct a ball 10 
 inches in diameter; then proceed as follows to get out the pattern 
 for one of the halves : In Fig. 400 on the line A B describe the semi- 
 circle B C A, 10 inches in diameter, and with the radius A E divide 
 the circumference of the semicircle into three equal parts, as shown 
 by B H, H G, G A. Divide the versed sine C D into two equal parts, 
 and through the center of it draw the line Y X and similar lines V Y 
 and X O parallel to B H, H G and G A; then the convex surface of a 
 truncated cone, Fig. 401, represented by the lines V Y, Y X, X O, 
 Fig. 400, will equal approximately the convex surface of one-half of 
 a sphere, which is represented by the semicircle B C A. Extend 
 V Y and O X to K ; then with K as center describe the arc O N S 
 and with the distance V O space off three spaces on the arc O N S, as 
 shown. With the radius K X describe the arc X M Z and join S K ; 
 then O N S X M Z will be the pattern for the frustum of a cone, Fig. 
 401. File and round up the edges to rid them of all rough burrs, 
 cracks or flaws, and thin the edges O X and Z S. Cramp one side ; 
 then double up the pattern, as shown in Fig. 402, and braze the seam 
 as directed for section of air pipe. Clean off the seam and knock it 
 down — that is, hammer it down so that the joint is the same thick- 
 ness as ;he rest of the sheet ; then round it up true, producing the 
 sides of an inverted pan without a bottom, shown in Fig. 401. The 
 next step is to prepare the pan for the bottom. 1. Commence to form 
 
246 
 
 ART OF COPPERSMITHING. 
 
 Fig. 400.— Method of Describing Pattern for Half Ball. Fig- 402.— Showing Pat- 
 tern Doubled Up. 
 
 Fig. 401. — Pattern Formed with Seam 
 Brazed and Lag Raised. 
 
 Fig. 403. — Raising Down the Lag for 
 Bottom. 
 
ART OF COPPERSMITHING. 247 
 
 the lag by a course around the small end about fy inch wide on the 
 end of a mandrel of suitable size ; then anneal on the brick forge, 
 cool and take to the floor block, and on a bottom stake, Fig. 403, finish 
 razing down the lag for the bottom. Next cut out the bottom, which 
 may be the exact size of the hole or a trifle larger, and thin the edges 
 both of the bottom and the part forming the lag, after which 
 cramp the bottom with a chisel if it is of heavy copper, and with 
 the snips or shears if of light. Open the cramps far enough so that 
 the bottom may be put in from the under side, or inside, each alter- 
 nate cramp going through the hole ; that is, one inside and one out- 
 side. Place it on the bottom stake and smooth down the seam and 
 " popple " the bottom by a few blows in the center, then spring it in 
 and out a few times — this will loosen the joint and answer the same 
 purpose as chattering straight seams, to give room for the borax and 
 spelter ; it- is now ready for the fire. Charge the seam with spelter 
 as previously described, following the cramps in their zigzag path 
 around it ; then take it to the fire, and when the borax and solder are 
 thoroughly dry roll the sides of the pan around on the fire, using a 
 pair of duck-bill tongs for the purpose, until the fire can just be seen 
 through it. Show the seam to the fire, turning the pan while the 
 spelter is running ; then cool, clean off the joint and knock it down 
 smooth, and afterward anneal it. Take the pan to a suitable bullet 
 head and raze a course at the brim, enough to make it about g}£ 
 inches in diameter ; then break the lag down, round up smooth and 
 planish. To one who is apt and quick at perception the outlines 
 suggested above will give the cue for many similar pieces of work 
 which offer themselves occasionally to the practical coppersmith or 
 sheet-metal worker, who is called on sometimes for something out of 
 the common run of every day work. One of the uses to which an 
 article of this kind may be and often is put to when suitably perfo- 
 rated is a strainer to keep out rubbish that might interfere with the 
 working of bilge pumps on ships, or it may be used wherever it is nec- 
 essary to have a strainer with capacity largely in excess of the pipe 
 leading to the pump. 
 
248 ART OF COPPERSMITHING. 
 
 BRAZING SHEET BRASS. 
 
 In both marine and locomotive work there is sometimes consider- 
 able ornamental brass work of various kinds, such as edging for 
 splashers, coping, hand rails, domes and a variety of moldings, and I 
 have often witnessed a good deal of annoyance and disappointment 
 among workmen (myself included) on account of their want of knowl- 
 edge in relation to the law of expansion and contraction while 
 attempting to braze joints necessary to the completion of their work. 
 Then, again, the many different kinds and qualities of brass made 
 and sold often lead men into trouble, partly through the deception of 
 the dealer or manufacturer, but mainly through their own ignorance 
 of the nature of the material they are expected to work up. 
 
 There are so many mixtures called brass that unless the 
 workman is quite familiar with them, or on the alert and 
 wary, he may encounter a failure when least expected. After 
 much unpleasant experience in this direction it has been 
 learned that when working on sheet brass of an unknown quality 
 which it is required to join and solder together, before the work 
 is begun, it is best to take a small corner and try its merits with such 
 spelter as may be at hand ; if it can be made to run with ease on the 
 scrap being tested, there will be no further trouble, but if it will not 
 run on it, then it is desirable and necessary that some should be pro- 
 cured that will. After the work is cut out there are usually some 
 scraps that cannot be used for anything to advantage ; take a portion 
 of these scraps, if there are any (if not, take a part of the sheet) say 1 
 pound, and having provided a small crucible, melt the scraps with 
 some borax, and in the mean time have 1 ounce of zinc melted in a 
 ladle ; when tbey are both in a liquid state, mix in the zinc and stir 
 with a stick, then pour it out, and when cool enough to only char a 
 hazel rod, break it up in an iron mortar and try its merits on another 
 scrap of the brass. If this new composition, now to be used as spelter, 
 is found to require too much heat, melt it again and add a 
 little more zinc, so it will run with safety to the work in hand — 
 that is, without fear of burning the parts adjacent to the joint 
 
ART OF COPPERSM1THING. 
 
 ?4 9 
 
 Fig. 404. — Brazing Seam-in Sheet Brass. 
 
250 ART OF COPPERSMITHING. 
 
 or having the cramps fall off from excessive heat. Brass made to 
 have a silvery hue when polished is always difficult to work, and 
 requires the utmost vigilance while being brazed, as well as in the 
 preparation for that operation. In some instances it is necessary to 
 add a little silver to the spelter in addition to the zinc, which will 
 reduce the heat necessary to run it, and add to its malleability ; the 
 quantity required, however, will necessarily depend on the kind of 
 brass, and must be left to the scrutiny of the operator. Having 
 procured a spelter suited to the brass, we will suppose the work 
 requires a strip of brass 12 inches wide to be joired and brazed 
 together ; then trim the edges of both ends and thin them, and cramp 
 one. The next step is to prepare a frame from a piece of ^-inch boiler 
 plate, Fig. 404, in the shape of a horseshoe, some 4 or 5 inches wide, 
 and about 15 inches long, also two screw clamps C, and two pieces of 
 bar iron D, strong enough to hold the brass fast on the horseshoe 
 plate when the screw clamps are applied. Bend the sheet in the form 
 shown, so that when the joint is brought together within the horse- 
 shoe frame it will hang in a curve or bag between the legs of the 
 frame. Now bring them together, open the cramps and let them 
 receive the end of the other piece, and screw it fast to the plate with 
 the clamps. Put an iron rod through the screw clamps and sling it to the 
 chain. Remove it to an anvil and close down the joints, care being 
 taken that all the spring is taken out of the parts about the joint 
 before going to the fire. When at the forge, jar some liquid borax 
 through the joint, charge it, and sling it so that it will balance and 
 hang level ; then with a slow fire heat the parts within the frame 
 gradually until the solder is all down ; then with a gentle fire the 
 joint may be easily and successfully run down. 
 
 The strongest spelter used by coppersmiths for heavy work is 
 composed of three parts copper to one of zinc. Another is made of 
 eight parts of old tubes or Bristol brass and one of zinc. Another, 
 for copper of medium strength, is composed of 16 parts copper and 
 12 of zinc ; for the better kinds of brass, 16 ounces of copper and the 
 same amount of zinc. It may be well to notice here some of the 
 many alloys called brass. The following have been collected in a 
 promiscuous way, as opportunity has offered, and are presented for the 
 benefit of those interested : 
 
ART OF COPPERSMITHING. 
 
 251 
 
 Bristol brass 
 
 Muntz metal 
 
 Pale yellow brass. 
 Muntz sheathing. . 
 Mosaic gold 
 
 Copper. 
 Ounces. 
 
 16 
 16 
 16 
 16 
 16 
 
 Zinc. 
 Ounces. 
 
 12 
 
 16 
 17 
 
 Brass, reddish yellow . 
 
 Princess metal 
 
 Rolled brass , 
 
 English brass 
 
 German brass 
 
 Watchmakers' brass . . . 
 
 Pinchbeck 
 
 Tombec 
 
 Mannheim gold 
 
 Button brass (white) 
 Bath metal 
 
 Copper. 
 
 Zinc. 
 
 Parts. 
 
 Parts. 
 
 86.6 
 
 11 4 
 
 83 
 
 17.0 
 
 79 6 
 
 20.4 
 
 74.6 
 
 25.4 
 
 66.2 
 
 33.8 
 
 49.5 
 
 50.5 
 
 88.0 
 
 11.0 
 
 44.5 
 
 15.5 
 
 70.0 
 
 30.0 
 
 30.4 
 
 69.6 
 
 32.0 
 
 9.0 
 
 Cymbal metal, 80 copper, 20 tin. 
 
 Gilding bronze, 82.3 copper, 17.5 zinc, 0.24 tin. 0.02 lead. 
 
 Button metal, 32 brass, 4 zinc, 2 tin. 
 
 Tutenag, 45.7 copper, 36.9 zinc, 17 4 nickel. 
 
 Chinese white copper, 40.4 copper, 25.4 zinc, 31.6 nickel, 2 6 iron. 
 
 It will be seen that the workman who is ignorant of the many- 
 alloys commonly called brass, and incapable of forming an opinion as to 
 their quality or the spelter necessary for the particular kind he may 
 have to work up, can very easily and innocently fall into an error 
 and be placed in a very unpleasant position. I have found but little 
 charity shown toward workingmen, or by them, when innocent fail- 
 ures of this kind have happened, and I have had my share. It is 
 hoped the tables above given maybe the means of assisting the young 
 workmen, and old ones who are willing to learn, to avoid the chances 
 of failure likely to occur in the working of any of the poorer kinds 
 of brass, if called on to do so. 
 
252 • ART OF COPPERSMITHING. 
 
 LOCOMOTIVE BRASS WORK. 
 
 Among the various kinds of metals and their alloys which have 
 been brought into use and wrought from the sheet into many forms 
 of ornamental work, there is none excepting the two precious metals 
 that has or can give to the zealous workman as great delight and 
 satisfaction for the lab^r bestowed as sheet brass ; it matters little 
 what hue or tint may be the most prominent, there is always a pleas- 
 ant satisfaction after the work is finished, cleaned and polished. 
 Especially is this the case when the work is finished complete from 
 the hammer. The thought ever present in the mind of the careful 
 workman, that the result of his efforts is destined to be brought under 
 the scrutiny of the public eye, as well as of his fellow workmen, is 
 an incentive to greater caution and care on his part, that the work 
 shall be carefully and well performed. ""While there is work executed 
 in copper which requires much greater skill on the average than is 
 called for ordinarily in working sheet brass, it is almost always from 
 the nature of things carried out of sight and covered up. Most work- 
 men like to work brass after they have become familiar with its 
 properties, and have learned by experience the best method of treat- 
 ing it during the operation of shaping to the form desired ^In this 
 article, closing the description of a coppersmith's shop adapted to 
 marine and locomotive work, I will describe three pieces of orna- 
 mental brass work for a locomotive, at the same time showing the 
 necessary appliances and their application, so that the young me- 
 chanic may, by using ordinary intelligence, successfully perform that 
 which has been and is now under some conditions regarded as a lead- 
 ing or first-class piece of work in the coppersmith's art, and which 
 will serve as a guide to others of a similar nature, although they may be 
 required for an entirely different purpose. The best brass — that is, 
 the safest for the beginner — is Bristol brass (see tables in a previous 
 chapter), which, being composed of 8 parts of copper to 3 of zinc, leaves 
 a good margin for the spelter, which is of equal parts copper and 
 zinc, and will run readily on brass as low as 6 of copper and 3 of zinc 
 with safety. 
 
ART OF COPPERSMITHING. 
 
 253 
 
 Now, it would seem there are fashions in dress even among- loco- 
 motives, for at one time they were covered with ornamental brass 
 work and were very attractive. Among these ornaments was a chim- 
 ney to take steam from the safety valve, while another was a cover for 
 the regulator dome. These were of many different kinds and shapes, 
 and as the three I shall now consider will answer as a guide to all the 
 
 1 tst, I will try to give the details as fully as'possible, so that they may 
 be easily understood by those interested and seeking such information. 
 Let Fig. 405 represent the covering for a safety valve, and also to 
 answer the purpose of a chimney to convey the steam escaping from 
 the valve, above the head of the engineer. These chimneys were about 
 
 2 feet 6 inches in hight, and some 18 inches in diameter at the base, 
 the foot of which was razed out and given an easy graceful flow over 
 the boiler. The chimney p-oper, as will be seen by a b c of Fig. 406, 
 was made in three pieces, which with the base, or foot d, made four. 
 Thus the cover at the outset was in four pieces, three of which, a b c, 
 were brazed together after being formed into shape, and the fourth, 
 which was the base or foot, slipped into a bead formed on the lower 
 end of the chimney and soft-soldered in place. I will now give 
 directions for forming it, and for the different stages through which 
 it will pass until finished, together with the tools used. Let it be 
 required that the bell a, Fig. 406, at the top, measures 12 inches, the 
 straight part b measures 7 inches at the top and 8 inches c^t the bot- 
 tom, and the bell c 18 inches at the bottom. First prepare the top, the 
 outer edge of which must be enough larger than 12 inches to cover a 
 % inch wire, say, about ^2 inch each side ; then the bell at the top 
 
 before wiring would be 13 inches in diameter. The curve or flow of 
 the bell is most pleasing to the eye when it is an elliptic curve, as 
 shown in Fig. 407, all the lines of which are given as a guide. Let ay 
 db of Fig. 408 represent the top bell of Fig. 407 before wiring — that 
 is, with the edge flat and measuring 13 inches in diameter, the 
 bottom next the pipe or straight part being 7 inches. Draw the 
 lire a b of Fig. 408 from the point a y-z inch from the outer edge 
 through the points a and b, and divide the versed sine of the arc or 
 curve into three equal parts. From the point b on the line b d mark 
 off a distance equal to one-third the length of the versed sine, and 
 from the point a on the line ay ma r k off a distance equal to two- 
 thirds of the length of the versed sine. Draw the line m c and con- 
 
2 54 
 
 ART OF COPPERSMITH I NO. 
 
 Fig. 405. — Valve Chimney. 
 
 Fig. 406. — I^arts of Valve Chimney. 
 
 
 
 1 
 
 18" 
 
 \ 
 
 / 
 
 
 
 \~ 
 
 1 
 
 
 
 
 / 
 / 
 
 1 
 
 / \ > 
 
 
 
 / 
 
 \ 
 
 
 \ 
 
 J . 
 
 ^ 
 
 
 1 
 t 
 
 1 
 
 1 
 
 ~~1 
 
 18 
 
 V 
 
 1 
 
 \ 
 
 1_ _ 
 
 
 j 
 
 
 
 
 
 
 
 / 
 
 r .Fz^-. 408. — Manner of Obtaining Pat 
 tern for Bell. 
 
 Fig. 407. — Manner of Obtaining Curves 
 for Valve Chimney. 
 
ART OF COPPERSMITHING. 
 
 255 
 
 Fig. 409. — Bell Folded and Sus- 
 pended by Chain Ready for Brazing, 
 
 Fig. 411. — Mandrel for Planishing Bell. 
 
 Fig. 410. — Saddle Head for 
 Planishing Bell." 
 
 Fig. 412. — Bell and Straight Part 
 Cramped Together. 
 
256 ART OF COPPERSMITHING. 
 
 tinue it to x. Draw x y. From the points c and d on the lines x and 
 x y, lay off the length of the curved line of the bell; then, with the 
 radius xy thus obtained, describe the axo, g ay k, and with the radius 
 x s describe the arc reds. Then the surface ot the truncated cone 
 cd my will equal approximately the surface of the bell of which g a 
 y h s r is the pattern. The pattern for the bottom bell may be ob- 
 tained in a similar manner. File up round the outside and inside 
 sdges, after which thin the two ends and anneal and cramp them. 
 Then fold it up as shown in Fig„ 409, being careful that the two 
 edges lie snugly together, and that all the spring is taken 
 out after the joint is laid and ready for the fire. To assist in this, 
 let the pattern be held together by four dogs, two on each side, 
 as shown. Jar a little borax and water through the joint, and charge 
 it. Now sling, and with a clean fire slowly heat it, first on one side 
 and then the other, until the borax is all down; then with a gentle 
 fire the joint may be easily run down. When cool, the joint can be 
 cleaned, care being taken to see that all cramps are well filled. If any 
 are deficient, open the cramp and carefully clean it on the under or 
 inside, then close it down and lay a little fresh spelter on the outside 
 and inside, and run it afresh, keeping the solder outside from oxidiz- 
 ing by applying powdered borax. After the seam has been cleaned 
 off outside and inside it may be rounded up into shape. A hammer 
 should be used as little as possible in dressing the joint. If an oven 
 of a proper heat is at hand, the annealing can be better performed 
 in it than in any other way. If there be none, place it 
 over a clean coke fire, and gradually make it blood red. 
 When cool take it to a suitable sized mandrel, and with 
 a ball-faced mallet work out from the inside a light course at 
 the small end, then turn it up and work out a course at the large end, 
 also from the inside. Now hang it on the mandrel and work in a 
 course each way from the outside, being careful that the blows are 
 regular, so that all parts receive an equal amount of working strain. 
 If this is not properly attended to it may crack when the annealing 
 begins, as brass is very brittle when hot, hence itisnecessaiy that the 
 work should be performed regularly and uniformly all around in each 
 course. When by continued courses, first inside and then outside, the 
 desired curve is obtained, the edges at the small ends of bell and pipe 
 may be thinned and annealed and the pieces planished, leaving 
 
ART OF COPPF.RSMITHING. 
 
 2.57 
 
 enough of the outer eds?e of the bell soft to cover the wire at the top 
 end and to form the bead to receive the foot at the bottom. The plan- 
 ishing- is best performed on a saddle head, Fig. 410, if one is at hand ; 
 if not a mandrel, Fig. 411, may be cast to suit the curve and slide on a 
 bar fastened in the mandrel block or in a loop in the bench. When 
 the planishing of the two bells and the straight piece is completed and 
 all the edges are thinned, annealed and scraped or filed clean, cramp 
 the straight part and bring the bell to it, as indicated in Fig. 412, and 
 with a bolt and two pieces of stiff iron draw them together, passing 
 the rod through them and pulling them together, as shown. Smooth 
 down the cramps, and the work is ready for the fire.* 
 
 * W hen the writer first began making these chimneys a number of failures resulted, partly 
 from ignorance of the laws of expansion by heat, but mainly from the fear that if the irons and 
 rod were taken off the joint would separate; but one day, by accident, the joints not being in 
 line, the bolt was taken out to adjust them, when it was found to be quite a job to pull the 
 joint apart ; so after the adjustment an attempt was made to braze the joint without the bolt 
 to hold it together, with complete success. The work was much better than ever it had been 
 done before. 
 
258 ART OF COPPERSMITHING. 
 
 BRAZING THE JOINT. 
 
 Now take the straight saddle forge, Fig. 413, place in position and 
 make a clean fire in it ; jar some borax through the joint and 
 charge it slowly all around on the inside, and sling it in an endless 
 chain running over a pulley. Hook it to the chain overhead, holding 
 the end with a suitable pair of tongs. Now heat it slowly ; then tack 
 it by running the spelter in two opposite places, slowly making it hot 
 enough to bring the borax down, then with a gentle fire run it around, 
 one cramp at a time, always having command of the blast slide so as to 
 stop it immediately if necessary. The lower bell may be brazed on in 
 the same way When both joints are cleaned off and the parts plan- 
 ished about them, it is then ready for polishing, which is usually done 
 on a lathe. The foot, by reason of its size, is usually made in halves 
 in order to economize the sheet. After the pattern is cut (which will 
 be described further on), the seams made and the foot rounded up, an 
 iron band or hoop, Fig. 414, about 1 inch wide and % inch thick is put 
 on the level end, and the brass partly turned over in some six or seven 
 places. This is to keep the foot in proper shape while working out 
 the flow — which is done after the same fashion as the bell — in light 
 courses with a mallet. The valve cover, Fig. 415, has no straight part. 
 The two bells <?/of Fig 416 are put together at the small ends ; the 
 top or upper end of the foot g of Fig 416 and A of Fig. 417 being razed 
 over enough so that the lower bell may be cramped in with ease and 
 readily brazed on the narrow fire, being slung as in Fig 418. After 
 the joint is brazed and cleaned off and the planishing is completed, it 
 is put in a lathe and polished. 
 
 We will now turn to Fig. 414 and cut out the pattern for this foot. 
 I^et the crown of the firebox ABC, Fig. 414(2, upon which the foot is 
 to stand, have a radius of 2 feet, and the foot of our valve cover D e/G 
 have a diameter of 18 inches at the top ef, and a flow of 4 inches, 
 over the crown on each side, as shown at e D and fG, and the flow an 
 elliptic curve, as indicated by the ellipse on each side. Divide one-half 
 the conjugate axis of the two ellipses which form the curves into four 
 equal parts, and through the points of division n and m draw the 
 line D n and P m parallel to the two transverse axis E b 
 and G a, cutting the crown A B C in D and P, making the line D P 
 24 inches. Draw HBO. Through P / and D e draw P / O 
 
ART OF COPPERSMITH INC. 
 
 •59 
 
 and D c O, and let them meet in O. Describe the arc Z Y X with the 
 radius O D and make it three times D P ; now divide the arc Z Y X 
 into eight equal parts as shown. On the lines Z O, Y O and X O, from 
 the points Z, Y, X, lay off the distances Z I, Y N, X J equal to D E. 
 Through the points N g and N h draw the lines N V, N U, and through 
 the points I d and J / draw the lines I V, J U, letting them meet in V 
 and U. Now, with N Y as radius, and from the points I, N and J, de- 
 scribe the arcs Z R, T Y R', and T' X. Then, with UR'orVTas radius, 
 from the points U and V, describe the arcs R T and R' T' From the 
 point S, on O K, lay off S r, the length of the curve flow f G, and with 
 O r as radius from the point O, describe the arc x y z ; then Z Y X xy z 
 is the pattern for the foot which is represented in Fig. 414. 
 
 Fig. 414a. — Pattern for Valve Cover Foot. 
 
260 
 
 ART OF COPPERSMITHING. 
 
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ART OF COPPERSMITHING. 
 
 26 P 
 
 Fig. 419. — Cover for Regulator Dome. 
 
 Fig. 420. — Parts of Dome. 
 
262 ART OF COPPERSMITHING. 
 
 BRASS COVER FOR REGULATOR DOME. 
 
 The cover for a regular dome, Fig. 419, is about 2 feet 3 inches in di- 
 ameter and 3 feet high, made from brass of No. 12 wire gauge in thick- 
 ness. To mark out the curve which will fit the boiler when the sheet 
 is turned round, as in Fig. 420, proceed as follows : Let a b of Fig. 421 
 equal the diameter of the boiler, and c d equal the diameter of the 
 dome cover. With the radius e d describe the circle c b dg, and 
 divide the circle into sixteen equal parts; then on the line h i lay off 
 a distance equal to the circumference of the circle c b d g and divide 
 h i into sixteen equal parts. Draw the lines parallel with h k to * n, 
 then from the points 1 2 3 4 of the circle a b draw the lines 1 1, 2 2, 
 3 3, and 4 4, parallel to h i. Through the points of intersection draw 
 the curved line h opt, which will fit the boiler when formed into a 
 cylinder. Round up the edges and thin the ends; cramp them and 
 double the sheet, being careful, as before directed, that all spring 
 caused by doubling is taken out before going to the fire* then sling it; 
 jar some borax through the joint, and with a reed, charge it, laying 
 the spelter in a zigzag line, following the edge of the cramps, which 
 should not exceed an inch in length. Now, be patient, and slowly 
 heat the sheet, each side, on a clean fire, being careful that there is no 
 lead, salt, or any foreign matter in it (the coke should be clean and 
 about an inch square). When the borax is all down, with a gentle 
 blast slowly run the joint down, and when cool, clean off and round up 
 on a suitable mandrel. In working out the foot, as previously ob- 
 served, the most pleasing curve is that of the ellipse, which may be 
 made of any length desired. 
 
 Having the pattern of the curve, which will be one-fourth of an 
 ellipse, commence razing out the foot or flow by a light course with a 
 ball faced mallet, represented by F in Fig. 422, using a thick wooden 
 block E hollowed out to nearly fit the circle of the cylinder, and 
 sloped off at one end, being rounded nearly to the curve it is desired 
 the foot should be. The block is dogged to the bench G as shown. 
 Let each course taken to raze the foot out be light and the blows reg- 
 ular, annealing at the conclusion of each course. The top, or crown, 
 of Fig. 420 may be worked with the foot in alternate spells as they 
 
ART OF COI'PIIRSMITHING. 
 
 263 
 
 
 
 
 
264 
 
 ART OF COPPERSMITHING. 
 
 ^ 
 
 S 
 
 
 '-0 
 
 % 
 
 
ART OF COPPERSMITHING. 265 
 
 are cooling, and thus economize time. When the writer first began 
 to make these covers the crown was made an exact half-sphere, but 
 while in the act of drawing the outlines it was noticed much time 
 could be saved by taking a wider sheet and tucking in the top end, 
 making the crown smaller, which method was adopted, the work being 
 much easier performed with less time spent at the fire. The difference 
 is illustrated at C in Fig. 419, where it is shown that two-sixths of the 
 circle is taken for the crown and the other sixth left on the cylinder, 
 which lessened the labor and made the work required much easier 
 than when the crown was one-half a sphere. 
 
 I will now form the top or crown, first cutting the pattern and 
 forming it, and then complete the job. Let age, Fig. 423, represent 
 the crown for the dome-cover, which is two-thirds of one-half of a hol- 
 low sphere whose diameter is the same as the cylindric part of the 
 dome-cover. Draw the line g c from the edge of the hole g to c ; then 
 draw the versed sine x and divide it in the center; through the center 
 of x draw the line b e parallel to g c and meeting a c at e. With the 
 radius b e describe the arc e a of and measure off on its circumference 
 six times the radius n e, and draw bf. With d b as radius, describe the 
 arc d k k, then e a of d k h will be the pattern for the segment of the 
 hollow sphere age, or the crown of the dome-cover. Now make the 
 joint and braze it ; round up into shape and anneal, when it is ready 
 for the first course. Crimp the edge at the bottom and take it to the 
 mandrel block, Fig. 424. With a mallet, on the head take in a course, 
 beginning one-third the distance up the side ; then the same at the 
 top, and anneal. The next course should be enough to bring in the 
 edge at the bottom and also at the top; then take a course in the mid- 
 dle from the inside, which should complete the curve. It may now 
 be smoothed up true, after which the crown is ready to be put in. 
 Before proceeding to do this, see that the edges are true across their 
 diameter, then thin them with a paned hammer, after which anneal 
 and clean either by scraping or filing. Cramp the base part, then 
 open the outside cramps, bringing the crown to it, and with a cross- 
 piece, or two pieces laid across each other, pass a rod through them 
 and through the crown, upon which lay another short piece, the bolt 
 passing through it also. Now screw it up tight, tapping the joint 
 occasionally all around to assist the bolt in bringing the joint up 
 close. Turn it with the foot up, and at four opposite places close 
 down four cramps and drill four holes, putting in four small brass 
 
266 
 
 ART OF COPPERSMITHING. 
 
 c 
 
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 ^ 
 
ART OF COPPERSMITHING. 
 
 267 
 
 3 
 
 Si 
 
268 ART OF COPPERSMITHING. 
 
 rivet-, enough to hold it while the joint is being closed down smooth — 
 which may be done by a helper holding a" head inside or by putting 
 it on the head as in Fig. 425 and balancing it with a weight, as shown. 
 When the joint is ready, take to the fire and sling it in aa end 
 less chain with pulley wheel, Fig. 426, hooking it to the traveler over 
 head. Jar some liquid borax through the joint, and sprinkle some 
 powdered borax outside ; then charge it with spelter all around, 
 warming it gradually, and then tack it in four places between the 
 rivets. By this time it will be fairly hot. Go once more around 
 slowly, and when at the place of starting begin to run the joint with 
 a gentle fire, one cramp at a time. A little help is now necessary to 
 attend to the blast and sprinkle borax on the joint as required. As a 
 hand-hold to use while at the fire, two screw-clamps are fastened to 
 the points of the foot, as shown. "When the joint is run and has had 
 time to cool, it may be cleaned if found to be perfect. The whole job 
 is now trued to shape and planished ; first the body, as in Fig. 427, the 
 mandrel curve being rather smaller than that of the dome cover ; 
 and then the crown, as in Fig. 425. The cleaning and polishing can be 
 done in a lathe. 
 
[A268] 
 
 Fig. 428. — Interior Vieio of Coppersmith Shop, Showing Pipe Coils and Brewery Fittings 
 
ART OF COPPERSMITHING. 269 
 
 HEAVY PIPES FOR BREWERY WORK. 
 
 The earlier pages were principally devoted to a description of the 
 working of light sheet copper in the manufacture of cooking utensils or 
 small articles generally, and known better as the braziers' art. This 
 was followed by the work for the locomotive and marine engine, which, 
 it will have been seen, in the main comprises the making of copper 
 pipes, large and small, bending and twisting them into any shape to 
 suit the position desired or exigent circumstances, and is known as 
 light coppersmithing. From this point an endeavor will be made to 
 interest the reader with some examples of heavy work, such as he may 
 occasionally encounter in his way (as has happened with the writer) 
 while moving from shop to shop, either from choice or necessity. To 
 keep as nearly in a progressive line as possible, the subject of pipes will 
 be resumed and considered in their various forms in large and heavy 
 work for application in breweries, sugar and still houses. 
 
 In breweries the principal uses for pipes are for refrigerators and 
 attemperators, and these consist of coils of pipe of various forms which 
 are made to fit the coolers or fermenting vats for the purpose of raising 
 or lowering the temperature of the liquor by the aid of a current of 
 water or steam passing through the pipes. 
 
 In Fig. 428 is presented a view of the interior of a shop engaged in 
 this kind of work, which gives the reader a good idea of the conven- 
 iences that are necessary to perform it successfully. The photograph 
 from which the cut was made was kindly furnished by G. Hendry & Co. 
 of London, England, especially for this work, with a view of giving the 
 reader a more faithful illustration than can be done by a pen descrip- 
 tion. The picture is so complete that it would seem to need no further 
 explanation. 
 
 In Fig. 429 is represented a cooler having a group of pipes made to 
 fit it, and so arranged that the pipes may be raised or lowered in a con- 
 venient way when necessary to do so for cleaning. This grouping of 
 the pipes is perhaps among the oldest contrivances used for cooling 
 purposes in the manufacture of beer. It consists of a number of pipes 
 of equal length, grouped together with horseshoe bends to form a con- 
 
270 
 
 ART OF COPPERSMITHING. 
 
 Fig. 429. — Cooler with Movable Pipes. 
 
 ' Fig. 430. — Horseshoe Bend. 
 
 Fig. 431. — Set of Pipes for Small Cooler. 
 
ART OF COPPERSMITHING. 
 
 271 
 
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272 ART OF COPPERSMITHING. 
 
 tinuous run of piping sufficient to fill up the space on the bottom of a 
 cooler, as shown. The horseshoe bend is shown in Fig. 430, and is 
 made of brass or gun metal. The pipes are separated from each other 
 by boards called channel boards. The two end pipes are left open and 
 are provided with hose unions for connection with the water supply, 
 which is made to run along inside the pipes in the opposite direction to 
 the wort in the cooler. Fig. 431 shows a set of pipes for a small cooler 
 without the lifting appliance shown in Fig. 429. For large coolers two 
 and three sets of pipes may be and often are connected together, each 
 working independently of the other, but all bolted on the same frame 
 by means of the lugs on the bend. By this arrangement smaller pipes 
 can be used and the cooling surtace increased, while the consumption 
 of water is proportionately diminished. The pipes are usually soft 
 soldered into the bends. The foregoing apparatus is designed and 
 used for cooling purposes, but the conditions are sometimes changed, 
 and similar pipes are used for warming, which are called attemperators, 
 and others are used for boiling coils. In Fig. 432 is represented a boil- 
 ing round— that is, a round vat or tub, supplied with a coil of copper 
 pipe lying on the bottom, which is set with a gradual fall toward the 
 center so that the condensed steam or water is drained off through the 
 bottom, the condensed steam keeping the live steam at the full press- 
 ure, thus making the liquor boil quicker, and preventing a waste of 
 steam, which must occur if it was allowed to blow off into the air. The 
 steam is turned into the coil by a valve fastened to the side of the round, 
 as shown at X, Fig. 432. Fig. 433 is the same in principle, but made to 
 suit an oblong vessel. This vessel is called a back, on account of its 
 shape, so that it may be easily distinguished from a round vat. Another 
 form of liquor back is shown in Fig. 434. The set of pipes is furnished 
 with either ball joints or gland and stuffing box, so that it can be raised 
 or lowered at will for cleaning, or to get it out of the way when neces- 
 sary to do so. It is therefore much better and more convenient than 
 the kind with fixed coil. Vats and backs are also fitted with spiral coils, 
 as shown in Fig. 435 and Fig. 436. When they are fitted with coils in 
 this way they are used principally for fermentation, thus distributing 
 the temperature evenly through the mass of liquor. 
 
 Let us make one of these coils, and let the pipe of which it is made 
 be 3 inches in diameter and the coil consist of four rings, Fig. 437, the 
 outside ring being 6 feet in diameter from center to center, and the in- 
 
ART OF COPPERSMITHING. 273 
 
 side ring 2 feet. The first thing is to find the length of the coil, which 
 we do by marking out the coil in Fig. 437, as follows : Draw the line 
 Z Y, making it 6 feet, and bisect it in V, and with V as center and V X 
 as radius, equal to 1 foot, describe the semicircle X U W; then divide X Z 
 and W Y into three equal spaces, X a, a b, bZ; W c,c d, dY, and from V on 
 V Z lay off V e, equal to one of the spaces X a, and divide V e at T ; then 
 from the point T as center, with T W as radius, describe the semicircle W 
 S a, changing the centers V and T for each semicircle in succession until 
 the coil is complete. Now, we have seven semicircles, the center one, 
 X U W, 2 feet in diameter, the next, W S #, 2^3, the third, a R c, 3^, 
 the fourth, c Q b, 4 feet ; the fifth, b P d, 4^3, the sixth, d O Z, 5^, and 
 the seventh, Z N Y, 6 feet. Now adding these all together and divid- 
 
 ing by 2 we have — — — '* A/ ^ -r <t/j -1- 3/J -r ^ Qr a Clr 
 
 2 
 cle of 14 feet equal to coil ; and multiplying this by 3.1416 we get 
 14 x 3.1416 = 43.9824, the length of the coil. Hence we want 44 feet 
 of pipe (exclusive of that required to make the joints) to make the coil. 
 The pipes may be made, fitted and bent and joined together with 
 socket joints. 
 
 Copper pipe used in the making of coils of various kinds has usually 
 been made in lengths varying from 10 to 14 feet, therefore all coils of 
 any considerable size must be made in sections and joined or brazed 
 together. To do this brazing in the most convenient and expeditious 
 way it is necessary to provide a wheel and axle, as shown in Fig. 438, 
 upon which the coil may be fastened with a strap, A, and held in posi- 
 tion for manipulation as each section of pipe is added to the coil and 
 the process of brazing together is being executed. The wheel and axle 
 are fastened to a suitable post and over a pit, the axle being placed 
 about 3 feet from the floor, so that the socket when level will be on a 
 line with the center of the axle, and can easily be attended to when 
 the coil exceeds 6 feet in diameter. The accompanying illustration, 
 Fig, 438, sufficiently explains itself. 
 
 The method given above for describing a flat coil is perhaps the 
 simplest that can be used. For those who desire to make a coil nearer 
 the truth, it is necessary to resort to what is called an eye — that is, a group 
 of points situated in regular polygon form for centers, which may be- 
 gin with a triangle, as in Fig. 439, or with any other number of points, 
 as in Fig. 440. I will explain these two methods, and leave the learner 
 
274 
 
 ART OF COPPERSMITHING, 
 
 Fig. 436. — Attemperator Suitable for Fermenting 
 Back. 
 
 Fig. 437. — Diagram for Coil. 
 
ART OF COPPERSMITHING. 
 
 2 75. 
 
 Fig. 438. — Wheel and Axle for Brazing Pipe. 
 
3J6 
 
 ART OF COPPERSMITH I NG. 
 
 ■Big. 439. — Laying Out Coil with Triangle for Center, 
 
 Fig. 440. — Laying Out Coil with Hexagon for Center. 
 
ART OF COPPERSMITHING. 277 
 
 to pursue the further study of the subject as he may desire. In Fig. 
 
 439, the eye of the coil which governs the distance between the rings is 
 an equilateral triano-le. Now let it be required to make a coil 6 inches 
 apart from cer_. to center of the rings, then we divide the 6 inches 
 into three and erect a triangle, ABC, making the sides equal to'2 
 inches ; then with B as center and B a as radius, describe the arc a b ; 
 and with C as center and C b as radius, describe the arc b c, and with A 
 as center and A c as radius, describe the arc c d, and repeat the process 
 until the size of the coil is reached. In Fig. 440 the eye of the coil is 
 a hexagon. Now let the distance apart be the same as in the last ex- 
 ample. Then 6 inches divided into six parts gives us 1 inch for one 
 side of a polygon of six sides. Draw a hexagon, A B C D E F, Fig. 
 
 440, and make the sides equal to 1 inch ; then from A as center and A b 
 as radius, describe the arc b c, and with B as center and B c as radius, 
 decribe the arc c d, and repeat the process around the polygon, taking 
 each corner in succession, until the coil has been completed the required 
 size. 
 
 The length of these coils may be obtained in a similar way to that 
 already given — that is, by adding together the diameters of all the 
 circles which compose the coil and multiplying by 3.1416 and dividing 
 the product by the number of points in the eye of the coil. 
 
 Fig. 441 shows a portable coil a d the manner of using. The three 
 supporting stays are iron, bolted together and provided with eye bolts 
 for suspending rods by which the coil may be hung in a vat or tun at 
 any hight desired. The ends of the coil are supplied with unions for 
 connecting leather or rubber hose. These portable coils are quite 
 handy, as they may be removed readily with pulley blocks out of a tun 
 when not required. Portable coils may be made any other shape de- 
 sired. 
 
 It sometimes happens that it is better and more convenient to have 
 the two ends of an attemperator — that is, the outlet and inlet — lying 
 side by side or close together in preference to having one end cross the 
 coil, as in Fig. 441. In this case we resort to another plan, which is 
 shown in Fig. 442. When it happens that the workman does not pos- 
 sess the skill necessary to perform the operation of brazing the sec- 
 tional joints of the coil, flanges may be employed for joining the sec- 
 tions together, as shown in Fig. 443, the flanges being made just wide 
 enough to get b Its in, and of sufficient strength to make the joint se- 
 
278 
 
 ART OF COPPERSMITHING. 
 
 Fig. 441. — Portable Coil. 
 
ART OF COPPERSMITHING. 
 
 279 
 
 ■Fig. 442. — Coil with Openings Together. 
 
 ■Fig. 443. — Coil with Flanged Joints. 
 
280 ART OF COPPERSMITHING. 
 
 cure. It may sometimes be better to put them together in this way, SO' 
 that any section may be taken out for repairing when necessary. 
 
 To find the length of a spiral coil, as in Fig. 435, whose diameter is 6 
 feet from center to center of pipe and having three rings, with a rise of 
 1 foot to each ring, it will be seen that as each ring rises 1 foot the 
 length of pipe required for the three rings of the coil would be the 
 hypotenuse of a right-angled triangle whose base is equal to the circum- 
 ference of three flat rings as the base and the foot rise of each of the 
 three rings of the coil as a perpendicular. Then the length of the coil is 
 2 
 
 V( 
 
 [6 X 3. 1416 x s) 2 + (1 X 3) 2 = 56.619 or 56 feet 7.42 inches; 
 therefore to make a spiral coil, as in Fig. 435, we require 56 feet 7 
 inches of pipe, which is made of convenient lengths and put together 
 with socket joints as before directed. 
 
ART OF COPPERSMITH INC. 28l 
 
 BREWING COPPERS OR KETTLES. 
 
 Large brewing coppers are made in several different ways ; the 
 accompanying illustrations give three of the styles most in use, and 
 will, I think, be sufficient for our purpose. 
 
 Fig. 444 is an open copper with a light course ; that is, an addition 
 to the copper proper, to enlarge its capacity and lessen the cost, the 
 light course being made of lighter material than the copper proper, 
 and yet of sufficient strength, as it is usually supported by brick work 
 built around the course nearly or up to the brim. Let us build one of 
 these large coppers with a light course, and let it hold, say, 50 barrels 
 in each course ; that is, the copper proper to hold 50 and the light 
 course to hold 50 barrels also. The coppers may be made in any pro- 
 portions to suit the place they are to occupy ; that is, they can be tall 
 or squat, as the room can be spared, because the copper, in consequence 
 of its bulk, together with the brick work necessary for the furnace, 
 takes up considerable room, and therefore is usually placed in some 
 convenient position, as much out of the way as possible. 
 
 In an early chapter it was shown that the usual proportion for a 
 copper to hQld 106 gallons is, top 38, bottom 33^ and depth 28, so we 
 will make our proposed 50-barrel kettle in the same proportion, and 
 then add the light course to it. Now, all vessels of capacity are in the 
 triplicate ratio ; that is, comprise length, breadth and thickness, or 
 their capacity is found by multiplying these three dimensions together. 
 
 Therefore we will take the diameter at the top as the basis by which 
 to obtain the dimensions required for the sides and bottom. Then the 
 
 top diameter of a 106-gallon kettle measures 38 inches, and — = 54,872 
 
 inches, and as a barrel (English) contains 36 gallons, therefore 50 bar- 
 rels contain 1800 gallons, and 1800 •*■ 106 = 16.981, or the number of 
 times 106 gallons is contained in 50 barrels. We how multiply the cube 
 of 38, or 54,872, by 16.981, the number of times 1800 gallons contain 106 
 gallons, which gives us 930,781.432, and then extracting the cube root of 
 this last result we get 97.63, or the top diameter of a copper to hold 50 
 barrels, which, in practice, we should call 8 feet 2 inches. Here then we 
 
282 
 
 ART OF COPPERSMITH I NG. 
 
 Si a -». e a e » *> 
 
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 I 
 
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 ••SUBBB*' *.\»- o~ «'\jy 
 
 
 ttg. ^\.—Open Copper, with Light Course. 
 
ART OF COPPERSMITHING. 
 
 283 
 
 
 
 L , mm 
 
 a 
 
 
 
 
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 K -^1 
 
 
 
 
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 <^ 1 
 
 
 
 Fig. 445. — Sketch Illustrating Shape of Coppers. 
 
 Fig. 446. — Diagram Used in Calculating Patterns. 
 
284 ART 0F COPPERSMITHING. 
 
 have the first dimension of our proposed copper, 8 feet 2 inches. We 
 
 will now proceed to obtain the other two dimensions by proportion, 
 
 thus : Taking the dimensions of our 106-gallon vessel, as stated, top 
 
 38, bottom 33 5, and depth 28 inches ; then 38 : 33.5 :: 97.63 : 86. Again, 
 
 38 : 28 :: 97.63 : 71.938 From this, then, we find the three dimensions 
 
 of a 50-barrel copper to be : Top, 97.63 ; bottom, 86.068, and depth, 
 
 71.938, which we should call 8 feet 2 inches top, 7 feet 2 inches bottom 
 
 and 6 feet deep. We must now have the pattern for the sides, which we 
 
 will proceed to get. By referring to Fig. 445, it will be seen that a 
 
 copper is a part of the middle zone of a circular spindle ; that is to say, 
 
 the body of which it is a part is generated by the revolution 
 
 of the segment of a circle, and the versed sine of the segment is one 
 
 half the diameter of the copper at the brim. Without a knowledge of 
 
 the properties of the circular spindle, we can at best only make a good 
 
 guess at what the pattern should be. 
 
 The illustration here given shows two coppers with their brims 
 
 placed together, and then the outline of the spindle completed. This 
 
 when carefully and intelligently performed gives the key for cutting 
 
 the sides of all bellied vessels which are built up of a number of pieces, 
 
 as in the case of large coppers. Then as stated : The depth of the 
 
 copper is one-half the chord of the arc A B, and is 71.938 inches, and 
 
 the versed sine of the arc A B is one-half the difference between the 
 
 11.57 
 diameter of the top and bottom, which is — ; — or 5.785. 
 
 7I-938 
 
 T785 + 5 ' 785 
 
 = 450.176, the radius E I, Fig. 446, of the circle of which 
 
 the curve of the spindle (that is, the sides of the coppers from top to 
 
 bottom, or from A to B) E A B F is a part. The diameter G H at the 
 
 07.63 
 center of the spindle is 97.63 ; then one-half G H, or = 48.815, or 
 
 the versed sine G J of the arc E G F, Fig. 446, and 45°- I 7 6 x 2 — 
 48.815 = 851.538; then f/851.538 x 48.815 = 203.611, or E J, which is 
 
 one-half the length of the spindle, and V 851.538 x 48.815 + 48.815 
 = 209.586, or G F. 
 
ART OF COPPERSMITHlfrG. 
 
 285 
 
 
 ^ 
 
 OS* 
 
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 <■ 
 
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 t«i 
 
 
 t> 
 
 S- 
 
 S 
 
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 § 
 
 > 
 
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 ^ 
 
 
 Js. 
 
 fe 
 
 5> 
 
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 t-i 
 
 <s 
 
 
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 s*. 
 
 
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 ^: 
 
 
 
 
 
 3 
 
 
 & 
 
 H" 
 
 i 
 
 & 
 
286 ART OF COPPERSMITHING. 
 
 But G F = G K, therefore { 851.538 x 48-815 + 48-815 = ^ Qr 
 
 2 
 K N, the radius of the circle M G K ; whence K M is 144-9 1 x 2 > or 
 289.82 ; that is, 24.15 feet is the radius of the curve at the brim edge of 
 the pattern, and 289.82 — 71.93 = 217.89, or 18.157 feet, is the radius 
 
 for the arc S T at the bottom edge. Again : 97 ' 3 * 3 " 141 =■ 51.1424," 
 
 6 
 
 or the versed sine of the arc of the circle of which curve the side edges 
 
 must be cut before hollowing in the hollowing tub, Fig. 447, ready for 
 
 placing in position for riveting — that is, when the sides are in three 
 
 pieces. Then - ° 3 ' TI + 51.1424= 812.78, or the diameter in inches of 
 51.1424 
 
 the circle of which the curve of the two edges are a part or must be cut 
 
 before hollowing. 
 
 Therefore 7 - = 406.39, or 33.8658 feet, for the radius of the two 
 
 2 
 
 side edges of the pattern. Here, then, we have three pieces or sides in 
 
 the small sketch, Fig. 446, 102.2383 from O to P, 71.93 from M' to R, 
 
 and 90.059 from S to T, with a radius of 33.8658 feet for the curve of 
 
 the side seam edges, and a radius of 24.15 feet for the curve at brim, 
 
 and 18.157 the radius of the curve at the bottom. 
 
 These dimensions are, of course, all bare — that is, nothing allowed 
 
 for ; the seams or the brim, which must be left on to suit the rivets 
 
 which are to be used in the side seams and the width of the brim 
 
 required for the light course, a part of which would be taken from 
 
 the depth, as the side would not reach the lag of the bottom by some 
 
 2 or 3 inches, for which allowance must also be made We now come 
 
 to the bottom. To-day they may be had already milled up in one 
 
 piece of any size or strength up to 15 feet in diameter. But when 
 
 I was a boy there was no machinery then in existence of such capac- 
 
 ) ity ; hence it was necessary to make large bottoms by hand in four, five 
 
 ' and sometimes more pieces, Figs. 448 and 449. But we will suppose 
 
 that we have the bottom supplied to use in one piece, and let it be 7 
 
 inches deep. Now, the first thing is to put the bottom in shape for 
 
 planishing — that is, form the crown, as shown in Fig. 450, by hollowing 
 
 in the hollowing tub. This hollowing tub, Fig. 447, as we call it, is a 
 
ART OF COPPERSMITHING. 
 
 287 
 
 Fig. 451. — Crowning Bottom in Holloiving Tub. 
 
 Fig. 452. — Planishing Bottom. 
 
288 
 
 ART OF COPPERSMITH ING. 
 
 Fig. 453- — Copper on Trestles, Ready for Working. 
 
ART OF COPPERSMITHING. 
 
 289 
 
 Fig. 454. — Side Ready for Riveting. 
 
290 ART OF COPPERS M [THING. 
 
 wooden ring like a washtub without a bottom, made of oak staves about 
 2^ inches thick, about 2 feet high and from 3 to 4 feet in diameter, 
 taper, and supported by three stout hoops, which are bolted to their 
 places after the wood has shrunk sufficiently. The bottom is laid over 
 the tub bottom side up, Fig. 451, and two men with large mauls or ham- 
 mers sink the bottom in the tub, while another man gu ; des the bottom 
 on the tub with the iron dog D, shown in Fig. 452. W;ien the bottom 
 fits the template it is turned the right side up and the planishing is be- 
 gun, which is done as sh jvi n in Fig. 452. A suitable *arge head is placed 
 in a block and the bottom is then smeared all over on the outside with 
 wet plumbago, also the surface of the block on which the bottom rests, 
 so that the bottom will slide about with ease while the planishing is go- 
 ing on. The inside is rubbed all over with either wet or dry Spanish 
 brown, so that the blows may be plainly seen. VVhen the planishing has 
 been completed, the bottom is placed on two or more suitable trestles, 
 Fig. 453, and after marking the holes the proper distance apart, the 
 rivet holes are punched in the bottom with a punch placed in a chisel 
 rod and the hammer b, while a man holds a bolster, a, on the outside 
 (the bolster a explains itself). Then all three sides, which have been 
 previously prepared — that is. bellied or hollowed and planished, Fig. 
 454 — ar • placed in position and secured with bolts. Then the head is 
 taken out of the block and put into a sling, d, Fig. 453, and one man 
 holds the head in position inside while two others, opposite each other 
 outside, work in the rivets, first with long-handled cross-peined ham- 
 mers, c, and finishing with hammer b. The light course is now prepared, 
 the sides of which may be brazed or riveted together, as desired, when, 
 after planishing, the holes are punched in the bottom edge, and then 
 the course is set in its place on the copper brim and the rivet holes 
 punched through the riveting edge into a small bolster and the rivets 
 worked in with short-handle hand hammers. The pipe or outlet is next 
 worked in and all finished up complete. 
 
 The same methods which are here described may be used for build- 
 ing a vessel of any number of pieces in the side or of any shape. In 
 Fig. 455 is shown a large open copper, with a light course, completed 
 ready for use, and about to be set in its future resting place. This 
 vessel was built in 1891 by Messrs. Shears & Co. of Bank-side, Lon- 
 don, and is said to be the largest copper ever built in England. It 
 has a capacity of 36,000 English gallons. This large vessel was built 
 
ART OF COPPERSMITHING. 
 
 291 
 
 Fig. 455. — Large Open Copper with Light Course. 
 
292 ART OF COPPERSMITHING. 
 
 for Ind, Coope & Co. The reader can get an excellent idea of its 
 construction, as well as its immense size. The size of the rivets 
 should be noticed, the proportion of the copper proper to the light 
 course, and then the three iron bands placed around the light course to 
 strengthen it ; also that the wall at the end of the building has been 
 taken down to let it into its place. This is a very interesting and in- 
 structive illustration for these engaged in this kind of work. 
 
ART OF COPPERSMITH [NG. 293 
 
 DOME COPPERS. 
 
 Dome coppers, as will be seen, Fig 456, are made similar to open 
 ones, the dome being substituted for the light course. Let us suppose 
 we have a copper ready for a dome, and it is required to make a dome 
 and work it on to the copper. As I have said before, a dome may now 
 be had in one piece, but were this not the case, as in years gone by, 
 then it must be made in pieces, and these must conform to the size of the 
 sheets at hand. Now, let the size at the brim be as in the last example, 
 namely: 97.63 inches in diameter, and the brim or dome seat 3^ 
 inches wide, with a riveting edge turned up 2 inches deep, and the dome 
 a half sphere, made in four pieces. To obtain the pattern for this we 
 proceed as follows : The diameter inside the turned-up dome seat or 
 riveting edge A B, Fig. 457, will be 97.63 + 3.5 x 2 or 104.63. Then 
 
 ° 4 ' 3 = 52.31, and y 52.31 x 2 = 73.97 or C B ; that is to say, it 
 
 equals the side of the inscribed square of a circle A B, whose diameter 
 is 104.63 inches, or the diameter inside the riveting edge, representing 
 
 the circle D C A N B. Now 1^1 = 36.98 or one-half the cord C B 
 
 2 
 
 of the arc C D B, or F B, and one-half the diameter DE — FE = DF; 
 
 that is to say, 51.31 —36.98 = 15.33, and FB + DF = DB, or 36.98 + 
 
 J 5-33 = 40-30 ; that is, it equals the cord D B of half the arc CDB; 
 
 2 2 
 
 but D G equals D B and D B — one-half of D F (that is, D H) equals 
 
 HG 
 
 H G, or D G — D H = H G, which is 40.30 — 7.66 = 39.29. Then ^^ 
 
 -+-DH = DNx 2, or 39 ' 29 + 7.66 = 209. 20, or the diameter of a circle of 
 7.66 
 
 which the curve of each side of the pattern is a part. Now construct the 
 triangle on K G (that is, on O P, Fig. 458. which is equal to K G), and with 
 
 D N or 104.60 or 2 ° 9 ' 2 ° (that is, the diameter of the dome seat) as a radius 
 
294 
 
 ART OF COPPERSMITH I NG. 
 
 
 ^ 
 ^ 
 
 
 ki 
 ^ 
 
 «5 
 
 a- 
 
 q 
 
 •& 
 
 S 
 
ART OF COPPERSMITHING. 
 
 295 
 
 X 
 
 Fig. 458. — Pattern for Quarter of Dome. 
 
 Fig. 459. — Illustrated Lesson by an Orange. 
 
296 ART OF COPPERSMITHING. 
 
 describe the arcs about the triangle O P Q, as shown in Fig. 458. Then 
 at one corner, O, of the pattern, with a radius, O R, equal to one-half the 
 diameter of the crown pipe, mark out the hole for it, making the 
 hole so that when complete it will be about 20 inches in diameter, 
 which will then complete the pattern required of one of the four 
 sections of the dome. Now, having the pattern and the four pieces 
 cut out by it, bend an iron template to the curve of a radius of 48.81 
 inches, and take the sections to the hollowing tub and hollow them 
 until they fit the template every way, after which planish them 
 in a promiscuous way on a suitable head placed in a solid block. 
 Then punch them and place them in position in the seat, remem- 
 bering to have the crown pipe also in position before the last quarter of 
 the dome is put finally into its place. Next bolt them together 
 in succession. The manhole may be prepared and fixed to the last 
 quarter before placing, or it may be worked on after, at the discretion 
 of the workman or employer. Put three or four temporary rivets in 
 each seam of the dome and in the seat at each seam, and one or two 
 between. We are now ready to work in the rivets, which may be done 
 in a similar manner to that described and illustrated for an open cop- 
 per with a light course. 
 
 I wish here to make a suggestion for the benefit of the boy who may 
 have occasion to peruse these pages in the hope of finding the assist- 
 ance he is in search of, because I think this is one of the most appro- 
 priate places which has suggested itself, where we can take a practical 
 lesson from nature. Fig. 459 is the picture of an orange with the rind 
 peeled off from three-fourths of the upper half of it, one-fourth being 
 left on to illustrate a part of our lesson. Lying apart from the orange 
 are the three-fourths of the rind which have been taken off. One piece 
 is lying with the concave or flesh side of the skin upward and one with 
 the concave side down and one lying perfectly flat. Now let us care- 
 fully consider these three pieces of rind in relation to the lesson under 
 consideration. Let the upper half of the rind of this orange represent 
 the dome of the copper in the next example, and let the dome be 
 made in four pieces, as before. It will be readily seen that the four 
 pieces of orange rind, after being removed from the orange, show in 
 miniature : 1, the exact shape of the pattern ; 2, the exact shape it 
 should be when hollowed and planished, and, 3, the position of the first 
 piece when it is placed in the riveting edge on the copper brim. Now, 
 
ART OF COPPERSMITHING. 297 
 
 if we conceive the edges for riveting to have been left on at two sides 
 of the pattern, then the rivet holes of the seam would come down the 
 line of division where the rind of the orange has been cut. With a 
 little study this should be plainly understood. We will now proceed 
 to find the shape and size of this pattern, as suggested to us by the 
 orange rind. Let the diameter C M of a spherical dome or an orange, 
 Fig. 457, be 88 inches in the present example. Describe the circle A 
 C B M to some easy scale that would represent a large-sized orange, 
 say ^ inch to a foot, and divide its circumference into four equal 
 parts, A C, C B, B M and M A ; then the diameter of the circle C M 
 is |f inch, or 5^ inches. Now draw the diameters A B and C M, and 
 join C B ; then the arc C D B represents the bend of either side of the 
 section when hollowed to fit the surface of the orange. Draw D B, which 
 represents the chord of half the arc C D B. Now divide D F in two 
 equal parts at H, and through H draw K H G, parallel to C F B ; then 
 with D B as radius and D as center describe the arcs B G and C K, cut- 
 ting K H G in K and G ; then K G represents the true length of the 
 side of a triangle, O P, Fig. 460 ; that is, from point to point, when the 
 section is lying flat the same as the orange rind in the picture, the line 
 D B having remained the same as it was before the section was flat- 
 tened and made a plane by being pressed down level. Here, then, we 
 have the length K G of one side of a triangle lying within the pattern 
 O P, Fig. 460, and we find by actual measurement that the line K G is 
 full 4}i inches, which, being multiplied by 16, is 66 inches (or more 
 correctly, 66.1). Now bisect P Q in S, and through S draw O S and 
 continue it to T, making S T equal to D H, Fig. 457, or one-half of D 
 F ; and draw the lines, or chords, T P and T Q ; and bisect these chords 
 perpendicularly with lines meeting in U. Then from the point of in- 
 tersection of these lines at U, with the distance U Q, U TorUP 
 (which is 5.5 inches, and this multiplied by 16 gives 88 ; the first, the 
 diameter of the orange, and the second, that of the dome), describe the 
 arcs O P, P Q, Q O. Now, with O R as radius, describe the arc W V 
 for the crown pipe hole, and W P Q V is the pattern of one section of 
 the dome, as before, but without riveting edge, which must be left on 
 the two sides W P and Q V. 
 
 There are very many useful lessons that may be learned in a similar 
 way to that suggested here by the rind of an orange, if the student is 
 apt and is of an inquiring turn of mind. 
 
298 
 
 ART OF COPPERSMITIIINC 
 
 Fig. 460. — Second Method of Obtaining Pattern. 
 
ART OF COPPERSMITHING. 
 
 299 
 
 DOME AND PAN COPPERS. 
 
 Dome and pan coppers are a combination of the other two coppers 
 we have been treating of, combined in one apparatus, with some few 
 additions, such as the valves at the top of the chimney and the two side 
 pipes to convey the overflow into the pan should the liquor in the cop- 
 per tend to boil over; also to convey the steam generated in the copper 
 into the liquor which may have been placed in the pan to be heated. It 
 will be seen that the pan bottom is made separate, and when formed 
 ready the inner edge is fitted to the sides, with the edge of the dome 
 crown (except when the dome is in one piece, when the pan would be 
 worked on the dome, as shown in Fig. 461), and then all three are riv- 
 eted secure, and the rivets scrubbed up so that the heads are all smooth 
 and even with the inner side. The inlet pipes are made of a suitable 
 size, as in N, and connected by flanges with the pan bottom and the 
 side of the copper. At the upper end of the inlet pipes and on the in- 
 side of the pan bottom is bolted a screw valve, Fig. -462, which is secured 
 to its place by the same bolts that hold the pipe flange to the pan bot- 
 tom. When the pan bottom and crown (if the dome is made in pieces) have 
 been worked in the manhole H, Fig. 461, and the inlet pipes also com- 
 pleted, then the sides of the pan may be put up into position and the 
 rivets worked in. The screw valves are now applied with a rod and T- 
 handle with which to open and close them, the rod being held in po- 
 sition by a bracket, B, bolted to the side of the pan. Any good work- 
 man who has made a large open or d me copper should be competent, 
 after studying the preceding pages and the accompanying illustrations, 
 to build a dome and pan successfully. I shall therefore let the direc- 
 tions given for the building of the other two styles suffice for that of a 
 dome and pan, and thus avoid repetition as much as possible. 
 
3°° 
 
 ART OF COPPERSMITH1NG. 
 
 Fig. fa.— Dome and Pan Copper. 
 
 £i%. 462. — Screw Valve. 
 
ART OF COPPERSMITHING. ^OI 
 
 TALLOW COPPERS. 
 
 In Fig. 463 is shown a tallow copper. These vessels were made for 
 and used by tallow chandlers, whose principal use for them at one time 
 was in manufacturing tallow candles. Tallow coppers are an extra 
 good job, because of the greater care necessary to make them sound — 
 that is to say, perfectly tight and not liable to leak. These coppers 
 were at one time in great demand, when all England burned candles 
 much more so than now. But there is yet an occasional demand for 
 one, because tallow is still used for many other purposes besides that of 
 making candles, and the shape of this copper is better adapted for the 
 use of rendering out tallow than any other, as the curve or spherical 
 shape of the sides tends to throw the fat that boils up the sides toward 
 the enter, which partially accounts for its peculiar shape, as compared 
 with coppers for some other purposes. This copper has a wide brim, so 
 that any slopping or drainings may be conveyed back into the copper 
 
 Note.— In this connection some piece work prices for coppersmith's work paid in London 
 will be of interest : 
 
 Brewing- coppers, 3J^ cents per pound for men ; one-half the price for boys. 
 
 Tieches for planishing- general, 2 cents for men ; one-half the price for boys, 
 
 Four-inch worms, 4 cents per pound for man and boy. 
 
 Retorts, 6 cents per pound for man and boy. 
 
 Stills, 3}4 cents per pound, metal as well. 
 
 Middle pieces, 4 cents per pound for brazed seams. 
 
 Four-inch tee-piec;s, $1 each for men ; 50 cents for boys. 
 
 Thiee-inch tee-pieces, 75 cents each for men ; 37^ cents for boys. 
 
 Four-inch bend complete, 83 cents each for men ; 41}^ cents for boys. 
 
 Three and one-half-inch bend complete, 64 cents each for men ; 33 cents for boys. 
 
 Three-inch bend complete, 50 cents each for men, 25 cents for boys. 
 
 Two-inch bend complete, 37^ cents each for men ; 18 cents for boys. 
 
 W6rms, when two men work at them, 8 cents ; when a man and boy work at them, 6 cents. 
 
 The time usually consumed putting- up sides into bottom of a 300-barrel copper by 1 wo men 
 inside and three outside, two and one-half days. Punching holes, in bout, three men inside and 
 two outside, one and one-half days each. 
 
 Setting-to 105 holes, two men one day. Setting-to 20 holes in seam and working in 20 No. 2 
 nails, with one man inside and two outside, three hours. 
 
 Working one seam of 20 nails, three men, one day. Working one bout of 15 nails, No. 1, 
 three men, one day. 
 
 Time consumed taking off old bottom from a dyer's copper and putting on new one, the 
 new bottom weighing 140 pounds, 38 inches in diameter and 9 inches deep. Cutting out old 
 bottom and annealing sides and planishing, ten hours. Planishing new bottom, seven hours. 
 Putting up block, punching boles, bolting together and working in 40 No. 4 nails, nine hours. 
 Scrubbing up new bottom, eight hours. Total time for job, three days four hours. 
 
302 
 
 ART OF COPPERSMITHING. 
 
 Big. 463. — Broad-Brim Tallow Copper. 
 
 Big. 464. — Section Through Broad-Brim Tallow Copper. 
 
ART OF COPPERSMITHING. 303 
 
 by it. They are made sometimes with narrow brims, in which case the 
 broad brim is substituted by one made of lead, covering the whole of 
 the brick work on its top surface about the brim, and turning down 
 over it on the inside of the copper from 2 to 3 inches, which, in some 
 cases, is preferable, because, then, none of the tallow can penetrate the 
 brick work from the top. 
 
 Let us make one of these broad-brimmed tallow coppers, and Jet the 
 sides be made from a sheet of, say, 35-pound plate, or about 1-16 inch 
 in thickness, to hold 200 gallons, and let its sides be in three pieces and 
 the bottom in one. It will be noticed that this vessel, Fig. 463, is 
 spherical in form, the body being made up of the middle zone and the 
 bottom segment, the other or top segment being absent to form the 
 brim or copper mouth. Now, the first thing we must do is to find the 
 size of a vessel of this shape that will hold 200 gallons, which we will 
 now proceed to do as follows : It is well known that a spherical inch is 
 represented by 0.5236, but the copper is a sphere with a segment cut off 
 equal in hight to one quarter of the diameter of the sphere (see Fig. 464), 
 and the value of this segment cut off is 0.08181 ; therefore, 0.5236 — 
 0.08181 = 0.4417. Now, there are 277.274 inches in a gallon (English 
 measure), therefore, 277.274 x 200 = 55,454.80 cubic inches, and 
 
 55>454- — _ I2 5,548; when, extracting the cube root of 125,548, we get 50 
 0.4417 
 
 inches as the diameter A B of the middle zone of the copper when ready 
 
 for the bottom. If Fig. 464 be drawn to a scale of ^ inch to a foot, it 
 
 will be found that from C to B is 47 inches, from D to E is 25, from F 
 
 to E is 4 inches, and from D to G 3 inches. Adding these last three 
 
 dimensions together, we have 25 + 4 + 3 = 32 inches for the depth 
 
 of the sides before working, and the diameter C B 47 inches, when 47 
 
 x 3.1416 = 147.6552, and 147.6552 divided by 3, the number of sides to 
 
 be used, we have 49.2184, or 49^ inches. To this we add 2 inches to 
 
 each piece for seams, when we get 51^ inches for the length of each 
 
 side, including edges, and 32 inches deep, including brim and lap for the 
 
 bottom seam. Now we find the size the disk should be for the bottom 
 
 before hollowing, as follows : It was stated in a former chapter that the 
 
 surface of a sphere is equal to its circumscribed cylinder, and therefore 
 
 the surface of any segment of a sphere is equal to the diameter of the 
 
 sphere multiplied by the hight of the segment, multiplied by 3.1416 ; or 
 
 the surface of a sphere is equal to four disks whose diameter is equal to 
 
304 ART OF COPPERSMITHING. 
 
 the diameter of the sphere. From which we get 50 x 12.5 x 4 — 2500? 
 and extracting the square root we get 50 inchts for the diameter of the 
 disk to form the bottom before hollowing, or \/ c x 12.5 x 4- Now 
 we have the sides and bottom, and require the broad brim, which is 
 obtained as follows : The brim when completed with a ^-inch wire in 
 the outer edge should measure 10 inches or thereabouts from E to K, 
 Fig. 464. Now the wiring edge at K will take 1% inches, and will 
 reach and lap at N 2 inches, which, will make the brim before working 
 10)^ inches wide. Then the diameter of the brim from K to M when 
 complete before wiring is 66 inches, and forms a frustum of a cone, the 
 slant hight of which is H M, or 34.5 ; that is, x y, Fig. 465. With the 
 radius y x fromjy as center describe the circle x w v u s, making the dis- 
 tance around it from x to s equal to the circumference of a circle whose 
 diameter is K M, or 66 inches. Now 66 x 3. 1416 = 207.345 an( ^ 69 X 
 3. 141 6 = 216.77 an d 216.77— 2 °7-345 = 9-4 2 > or 9/^ inches nearly; that is 
 to say, the segment s y x from s to x, which would be taken out, is equal 
 to gj4 inches nearly. The brim maybe put on in any number of pieces. 
 In this case let there be four ; then s u a b is one section of the brim bare. 
 Adding 2 inches on for riveting edge, the pattern is complete and will 
 measure from 21 to d 53.83, and from a to c 38.06, and from c tod 10.5 
 inches. Here we have all the patterns and will now begin to put them in 
 shape : First, the bottom, by taking it to a hollowing tub, and with suit- 
 able mauls sink it in the tub until it is hollowed enough ; that is, until it 
 measures across it 46 inches. Then mark the rivet holes for about No. 
 1 or No. 2 wrought copper rivets, and space the holes so that the edges 
 of the rivet heads are about ^ inch apart. The sides are next in order. 
 These will be put together with No. 3 or No. 4 rivets, and the heads about 
 Y% inch apart and reaching to within ^ inch of the lap edge. When 
 the sides have been punched bend them into shape and put in a few 
 temporary rivets ; take a racer and divide the depth into three spaces 
 and proceed to raze in both ends ; the bottom end right out to the end, 
 the top end to within 4 inches, making the lower end fit into the bot- 
 tom about 3^ inches, and drawing the top end out until it measures 43 
 inches at 4 inches from the end, when the brim is thrown back for the 
 additional wide brim. While the two ends are being worked in the 
 sides are put on the tub at the end of each course, and hollowed out 
 to complete the spherical curve of the body. Now we form the brim by 
 putting the four pieces together and wiring the edges with a ^-inch 
 
ART OF COPPERSMITHING. 
 
 305 
 
 Fig. 465. — Pattern of Brim. 
 
306 art of coppersmithing. 
 
 iron ring. The workmen may now select which is more convenient to 
 him, and first put on the brim or the bottom. If the brim is first put 
 on, carefully scrub the rivets and make the surface smooth about the 
 rivet heads, and work the seam edge carefully down close, then the 
 same with the bottom. It is usual to rub the seam well with white lead 
 and oil on the inside after the job is finished. 
 
ART OF COPPliUSMI L I1ING. 307 
 
 DYERS' COPPERS. 
 
 Dyers' coppers, as compared with some others, are not a difficult 
 job, which will be readily seen by referring to Fig. 466. A dyers' cop- 
 per is made with a cylindrical body and a segment of a sphere for a 
 bottom. The sides are usually made in two pieces, and the bottom in 
 one. These coppers may be made with a broad or narrow brim, similar 
 to that of a tallow copper ; or they may be supplied with a lead apron 
 to catch and convey the drip and slopping, which is always a contingent 
 circumstance in the dyers' art. Let us make a dyers' copper to hold 150 
 gallons American standard. Now, we have learned by experience that 
 the easiest way to build this vessel is to make the bottom one-fourth 
 the depth and the sides three-fourths, without the brim, although this, 
 like all others, may be made any style or shape to suit the taste or con- 
 venience of the purchaser. But we will suppose the sides needed are 
 three-fourths the depth and the bottom one-fourth. An American gal- 
 lon equals 231 cubic inches, and 231 x 150 = 34,650, or the number of 
 inches in 150 gallons, and we have 0.7854, which represents a cylindri- 
 cal inch ; then x 3 = 0.58905, or y± cylindrical inch. The valne 
 
 4 
 of a segment of a sphere whose hight is one-fourth its diameter is 
 
 0.08181, and adding this to the value of ^ cylindric inch we have 0.58905 
 + 0.0S181 = 0.67086, the value of the figure which represents a dyers' 
 copper. Then 34.650 -r- 0.67068 = 51.663.982, and extracting the cube 
 
 root of this last result we have 37.2 as the diameter, or 4/ 34-Q5° _ . 
 
 r 0.67068 ■*'' ' 
 
 37 2 
 that is to say, 37 T 2 y inches is the diameter of the sides, and ^-^~' x 3 = 
 
 4 
 
 27.9, or 28 inches nearly, is the depth, without seams, and 
 
 — ^— - — = 58.4337, the length of one side. Add to each side 
 
 about 2j4 for seams and we have the full length represented by 
 58.4337 + 2.5, or 60.9337, which we should call in practice 61 inches. 
 Now we must add 3 inches for the brim, and we have 27.9 + 3 = 30.9, 
 
3 o8 
 
 ART OF COPPERSMITHING. 
 
 S 
 
 o 
 
 ft? 
 
 to 
 
 *<3 
 
 
ART OF COPPERSMITHING. 
 
 309 
 
 ■^ 
 ^ 
 
 
 •& 
 
 ^ 
 
310 ART OF COPPERSMITHING. 
 
 or 31 inches nearly. I^et the sides be 60 inches long and 31 inches 
 deep. The bottom is obtained as follows: y 6.975 + 3 x 4 x 37.2 
 
 = 38.52 ; that is to say, one-fourth of the hight of the copper, or 6.975, 
 with 3 inches added for bottom seam, making 9.975, multiplied by 4, 
 and then by 37.2, the diameter of the copper, and the square root of 
 this last result is 38.52, or 38^ inches, which is the diameter of the 
 bottom before hollowing. 
 
 We are now ready to hollow the bottom, mark and punch it, 
 also to prepare the sides for putting together in the same way. In 
 the building of this copper we may use cast or wrought rivets ; let 
 us use cast. I should here state that the sizes of cast rivets are des- 
 ignated the opposite way to that of wrought — that is, No. o is the 
 largest size in wrought rivets, which run from o to 8, while 8 is the 
 largest cast rivet, which run from 8 to o. Fig. 467 shows the shape and 
 sizes of both wrought and cast. (We usually call the wrought ones 
 nails to distinguish them from cast rivets.) Take the bottom and wrin- 
 kle it regularly around the edge ; then sink it in the hollowing tub, 
 and work out the wrinkles carefully until the diameter is the size re- 
 quired ; smooth up and planish. Now work and punch the sides and 
 bend them to shape, and put three temporary rivets into each seam ; 
 then with a racer mark off the depth of the brim and run around 
 it with a hammer, Fig. 468, to harden it at the turn, and then lay 
 off the brim. Draw in the other end at the sides to fit the bottom, 
 Fig. 469, and planish the sides on the horse as shown in Fig. 470, and 
 work in the seam rivets. Scrub and finish the seam, making the surface 
 of the seam inside smooth. Mark and punch the holes for the bottom 
 seam, after which set the sides into the bottom evenly all round, and 
 mark the holes in the bottom by the sides, and punch the bottom. Put 
 the sides back in the same place, and put into the bottom seam a few 
 temporary rivets. Now work them in all round the bottom seam, per- 
 forming the work on the horse. When they are all in, scrub them up tight 
 until the inside is smooth, after which head up the rivets outside and 
 finish. 
 
ART OF COPPEKSMITI1INO. 
 
 3 11 
 
 TIECHES. 
 
 Sugar tieches were made the same as a tallow copper, excepting 
 chat heavier material was used, and the brim usually made narrow, as 
 shown in Fig. 471. They can now be made in one piece, but where this 
 is not possible the same rules and directions given for tallow coppers 
 may be used, and will be found as useful for tieches and all other ves- 
 sels of this shape as for tallow coppers, due allowance always bein£ 
 made for seams, as suggested in the directions given. 
 
 Fig. 471. — Sugar Tiech. 
 
312 
 
 ART OF COPPERSMITHING. 
 
 STILLS. 
 
 Copper stills are and have been in continual demand for many years 
 and are likly to be, seeing that there are so many uses to which they 
 may be put in the manufacture of the many commercial commodities 
 which depend upon the process of distillation. Stills are made from 
 iooo to 5000 gallons capacity, according to the uses for which they are 
 required. The largest, however, are used for the purpose of distilling 
 spirits, such as gin, rum and brandy. These large stills will occupy our 
 attention. In Fig. 472 is shown a squat or fire still with head and 
 worm. This apparatus is usually made in three sections — that is to say, 
 the still boiler, the head, and then the worm, which together complete 
 the still proper. But they are often supplemented with retorts of vari- 
 ous designs, the most common of which is shown in Fig. 472. These 
 retorts are used for rectifying purposes, and there are sometimes several 
 interposed between the still and the worm, according to the degree of 
 rectification required. As all large stills are made nearly the same pat- 
 tern, we will make one as an example or guide for ascertaining the di- 
 mensions and pattern of those most in use and then consider their con- 
 struction. Let our example be required to hold 500 gallons. It will be 
 seen by reference to Fig. 472 that the outline or design of the body of 
 the still boiler is that of an oblate spheroid — that is, down to 
 the lag of the bottom, when the bottom is reversed or pressed up- 
 ward to form the bottom crown, in the same way as that of a brewing 
 copper. Here, in the case of a still, as in a brewing copper, the quan- 
 tity displaced by the crown of the bottom is quite an item in the capac- 
 ity and must, therefore, be taken into account, although it was ignored 
 in the case of large brewing coppers. Our body, then (that is, the 
 boiler), is to hold 500 English gallons. Now, we find the solid contents 
 of a spheroid by multiplying the square of the revolving axis by the 
 fixed axis and this product by 0.5236. Here, then, we have the key to 
 the solution of the various problems involved in the sizes or dimen- 
 sions we should make the still boiler, and we will proceed to find the 
 diameter and hight of a still boiler to hold 500 gallons (English meas- 
 
ART OF COPPERSMITHING. 
 
 313 
 
 0, 
 
3 T 4 
 
 ART OF COPPERSMITHING. 
 
 O 
 
 
 
 Qq 
 ^ 
 
 ^ 
 
 
ART OF COPPERSMITHING. 315 
 
 ure), to be used as a rule to find any or all others. An English gallon 
 contains 277. 274cubic inches, therefore 500 x 277.274=138,637. Again, 
 in an oblate spheroid whose dimensions are fixed in the proportions 
 shown in Fig. 473 — namely, two and a half diameters of the focal circles 
 A and B as the measure of the transverse axis of the ellipse which forms 
 the outline for or boundaries of the spheroid, and whose axis is C D, or 
 is 1 — the value of its solidity is found by the rule given to be 0.29362. 
 The spheroid, however, is made concave on the under side to form the lag 
 and crown of the boiler bottom, therefore this value must be reduced by 
 the value of the spherical segment E G F, Fig. 474, which vanishes, 
 together with the segment E H F, which forms the bottom crown. Now, 
 
 EKxj+GKxGKx 0.5236 = 9.02758, the solid content of the seg- 
 
 a a 
 
 ment H E F, and EK x 3 + HK x H K x 0.5236 = 0.02128, the solid 
 content of the segement E H F, or the segment which forms 
 the crown of the boiler bottom ; then subtracting the value of these 
 two segments from the whole spheroid we have 0.29362 — (0.02758 
 + 0.02128) = 0.24476, or the value of solid figures whose dimensions are 
 similar to or like that of a still boiler. To proceed : the solid content 
 of 500 English gallons is shown to be 138.637 cubic inches; then 
 138.637 -4- 0.24476 = 566,420.168 boiler inches, and extracting the cube 
 root of this last result we have 82.73 as the diameter C D of a still 
 boiler to hold 500 gallons. Now, we want the depth, H N, Fig. 474, 
 which we find by multiplying the transverse axis C D, or 82.73, the 
 diameter of the boiler, by 0.3701; that is to say, C D by H N, or 
 82.73 x °-37 01 = 30.618. We thus have the diameter of the boiler 
 82.73 i ncnes , or 6 feet iofi inches, and the depth from the bot- 
 tom crown to the head collar 30.618 inches, or 2 feet 6^6 inches 
 nearly. For the pattern proceed as follows : Through S F and 
 T E, Fig. 474, draw the lines S P and T P, and with P F as 
 radius describe the arc F M, and with P S as radius describe the 
 arc S O, making the distance from F to S equal to 26.028; that 
 is, 82.85 multiplied by one-fourth of the circumference of the focal 
 circle. The length of each one of the sides from F to M may be any 
 convenient length, according to the size of the sheet ; but for the sym- 
 metry and beauty of the work the sides should be all alike ; that is to 
 say, either three, or four, or any other suitable number, so long as they 
 
316 ART OF COPPERSMITHING. 
 
 are all alike or can be got out of the sheets at hand without waste. 
 Now take sides enough so that when they are put together they will 
 measure 83 inches in diameter at the points C and D after the top and 
 bottom have been tucked in to form the bulge or curves of the sides, 
 and let the sides, when ready for the bottom, go into the raise of the 
 bottom within about 2^ inches of the bottom lag The first section of 
 the crown from S to B, Fig. 475, may be made in the same number of 
 pieces as the sides if it cannot be supplied in one piece with the bottom, 
 but the crown pieces are usually supplied. Having then the sides, bot- 
 tom and crown, the workman may proceed to put them together in a 
 similar manner to that described for the building of large brewing cop- 
 pers. I should here say, it is sometimes better to cover the trestles 
 with boards of a suitable thickness (if at hand), which will add firmness 
 to the trestles and make the stage more complete. The illustration, 
 Fig. 472, fully explains itself as to the construction of the still head and 
 worm, while the processes or methods used to make them have been 
 explained in a former chapter and need not be repeated. 
 
INDEX. 
 
 Page. 
 
 American Copper Mines 4 
 
 Ancient Light Coppersmithing :.. 6 
 
 An Old-Fashioned Shop 7, 13 
 
 An Ancient Frying-Pan ... . 44 
 
 Attaching Outlets : 200, 201 
 
 Apparatus for Brazing Brass Seams 249 
 
 Attemperator, Round, with Coil 271 
 
 Attemperator For Fermenting Back 274 
 
 Braziers' Art Treasures 6 
 
 Bellied Saucepan ± 18 
 
 Benches with Forming Bars in Position 10, 25 
 
 Boss for Outlet Pipe and Bock of Copper 32 
 
 Bottom Prepared for Putting into Hand Bowl 38 
 
 Blanks Fastened Together for Raising 46 
 
 Brazing Barrels to Straps for Handles • 59 
 
 Bossing Covers 66 
 
 Bullet Hammer 67 
 
 Beer Mullers . - 71 
 
 Brazing Pans 104 
 
 Boiler Hook and Rack 108 
 
 Boat Coal Scoop 124 
 
 Barge Pump.. 156 
 
 Bending Block and Lever 184 
 
 Block and Stake for Working Bends 187 
 
 Bend Making 186 to 193 
 
 Balloon Firepot in Position for Use 201 
 
 Burring Pin, and How to Use It 201, 202, 232 
 
 Broken View of Expansion Joint . 205 
 
 Bent Expansion Joint . 208 
 
 Bringing Halves of Pipe Together 186, 225 
 
 Bend Wired and Slung for Fire 225, 226 
 
 Bends, S . 228 
 
 Bends, S, to Stand at Right Angles 228 
 
 Bends Placed in Position for Brazing 228 
 
 Brazing on Flanges 230 
 
 Bends, Shortest, How to Make Them 232 
 
318 INDEX. 
 
 Brazing Sheet Brass 248 
 
 Brass Covers for Safety Valves 254 
 
 Brazing Round Joints 258 
 
 Brass Dome Covers ..... 261 
 
 Brazing in Dome Crown 267 
 
 Boiling, Round (Vat) and Coil . 272 
 
 Brewing Coppers 281 to 300 
 
 Copper and Its Uses 2 
 
 Copper Mines 3 
 
 Copper Stove Pipe, How to Make It 22 to 25 
 
 Coal Scoop Handle 51 
 
 Coffee Pot Handle 52 
 
 Collar Pitched on Spout 56 
 
 Clamp for Tinning Tea-Kettles 64 
 
 Charger or Solder Spoon ! 64 
 
 Cup for Bossing Covers 64 
 
 Collar Set . 66 
 
 Creasing Hammer - 73 
 
 Covered Muller . 77 
 
 Coffee Pots 83 
 
 Coffee Pot Spout . 85 
 
 Coal Hod 123 
 
 Coal Scoop, Plain 123 
 
 Coal Scoops . 124 
 
 Coal Scoop Making 128 to 150 
 
 Coppersmiths' Appliances 162 
 
 Cutting Cramps 171, 172 
 
 Clamps to Hold Fire Pots in Position 179 
 
 Cod and Its Uses 189 
 
 Cross Pieces 213, 214 
 
 Chain, Hook, and Dogs Applied 236 
 
 Copper with Tight Course 282 
 
 Crowning a Copper Bottom 287 
 
 Copper Sides in Position for Building 288 
 
 Dimensions of Hand Bowls 35 
 
 Duckbill Tongs 39 
 
 Die for Making Tea-Kettle Rings 59 
 
 Dimensions and Weight of Copper Tea-Kettles 69 
 
 Dripping Pan and Ladle 118 
 
 Diagram of Bend 188 
 
 Describing Pattern for a Bend 190 
 
 Double Expansion Joint ._ : : 206 
 
 Double Bends , 227 
 
 Dogs for Securing Sheet 236 
 
INDEX. 3 J 9 
 
 Diagram for a Flat Coil - 274 
 
 Diagram for Calculating Curve of Sides 283 
 
 Dome Coppers 294 
 
 Dome and Pan Coppers 300 
 
 Dyers' Coppers ." 307 
 
 Drawing in Sides to Fit Copper Bottom 308 
 
 East Side of an Old Shop 10 
 
 Ears for Coal Scoop Handles - 51 
 
 Expansion Joints 204 
 
 Expansion Joint with Round Edge 206 
 
 End View of Large Tee --- 210 
 
 Enlarging Hole with Burring Bar. -- 233 
 
 Elevation of Still Boiler 314 
 
 First Year's Experience 14 
 
 Folding Edges L 23 
 
 Filing and Finishing Spouts and Handles 57, 58 
 
 Forming Beer Muller Body - 73 
 
 Forming Lips of Mullers 75 
 
 Funnels - 80 
 
 Forming Funnel Body 81 
 
 Finishing a Square Lag 96, 97 
 
 Fish Kettles 102 
 
 Fish Plates 103 
 
 Forming Breast of Tea Boilers 109 
 
 Flat Bottom Coal Scoop 123 
 
 Florence Coal Scoop 124 
 
 Flange Broken Off, How to Put It On 193, 194 
 
 Four Types of Tee Pieces 209, 210 
 
 Fire Pots 177, 179, 181, 201, 226, 229 
 
 Glue Pot Making 61 
 
 Glue Pot and Cup Finished 66 
 
 Grommet for Bending Pipe 184, 185 
 
 Gauge for Marking 205 
 
 Gusseting Tee Pieces - 210 
 
 Gusseting Britch Piece „_.-.. 212 
 
 Historical Sketch of Copper '.— 1 
 
 How to Arrange the Planishing Blows 24, 26 
 
 Hammers, Cross Piened 29 
 
 Hand Bowl Making 35 
 
 Hammers, Riveting 36 
 
 Hammers, Razing - 36 
 
 Hand Bowl, Finished 39 
 
 Hollowing Hammer 43 
 
 How Wrinkles Are Razed Down 44 
 
320 INDEX. 
 
 Hand Swage for Water-Balls . 49 
 
 Hammers, Bullet 67 
 
 Hammers, Creasing 73 
 
 Hammers, Spring Faced .. 73 
 
 Handle for Large and Small Mullers 76, 77 
 
 Head and Shank for Planishing 82 
 
 Hammers, Piening 85 
 
 Hammers, Coffee Pot 96 
 
 Head for Working Round Lag 96 
 
 How to Raise Preserving Pans 117 
 
 How to Mend a Fracture or Split 194 
 
 How to Prepare Patches ^ 197 
 
 How to Sling Large Bends 225 
 
 Hammers and Rack 239 
 
 Hollow Spheres 241 to 247 
 
 Heavy Pipes for Breweries 269 to 280 
 
 Horse-Shoe Bend 270 
 
 Hollowing Tub 285 
 
 Horse for Planishing Coppers ... 309 
 
 Interior View of Front End of Railway Shop _. 164 
 
 Interior View of Back End of Railway Shop _._ 166 
 
 Interior Views of New Shop 1 168, 169 
 
 Interior Views of Marine Shop 221, 222 
 
 Interior View of Shop for Still and Brewery Work A268 
 
 Instructive Lesson with an Orange 295, 296 
 
 Joining Spout to Coffee Pot ... 84 
 
 Joint for Warming Pan Cover 116 
 
 Jigger Pumps _ _ 1 60 
 
 Joining Pipes 173, 175, 228, 276 
 
 Kettle (Tea) Handles 51 
 
 Kettle Spouts 53 to 56 
 
 Kettle Rings or Cover Seat 59 
 
 Kettles, Oval, Top Seamed On 67 
 
 Kettles, Oval, Top Razed Down 67 
 
 Kettle, Dimensions and Weight of Copper 70 
 
 Kettles, Fish . 102 
 
 Kettles, Turbot 103 
 
 Kettles, Brewing 281 
 
 Light Coppersmithing 6 
 
 Lipped Mullers . 75 
 
 Lipped Muller, Old Style 77 
 
 Lipped Saucepans 89 
 
 Ladle and Dripping Pan 119 
 
 Lift Pump and Fittings 155' 
 
INDEX. 321 
 
 Liquor Backs with Attemperator Pipes 271 
 
 Laying Out Coils 276 
 
 Laying Off Brim of Copper 27, 308, 310 
 
 Measuring Tinning and Retinning 19 
 
 Making Stove Pipe 22 
 
 Making Washing Coppers 26 
 
 Making Copper Sides True 28 
 
 Making Brewery Coppers (Small) 31, 33 
 
 Making Hand Bowls 35 
 
 Making Socket Handles 38 
 
 Making Frying Pans 42 to 45 
 
 Making Closet Pans 46 
 
 Making Water-Balls 47, 49 
 
 Making Mounting for Copper Goods 50 
 
 Making Tea-Kettle Spouts 53 to 58 
 
 Making Rings for Cover Seat ,58, 59 
 
 Making Glue Pots 61 
 
 Making Tea-Kettles 62, 67 
 
 Making Beer Mullers 71 to 79 
 
 Making Funnels ,. 80 
 
 Making Coffee Pots 83 to 85 
 
 Making Saucepans 87 
 
 Making Round and Oval Pudding Pots 88 to 92 
 
 Making Stewpans 93 to 98 
 
 Making Stockpots 99 
 
 Making Fish Kettles 102 
 
 Making Fish Plates 103 
 
 Making Brazing Pans 104 
 
 Making Tea Boilers 107 to 111 
 
 Making Warming Pans 112 to 116 
 
 Making Preserving Pans 117 
 
 Making Dripping Pans 118, 121 
 
 Making Coal Hods - 122, 123 
 
 Making Scoopets 125, 126 
 
 Making Coal Scoops - — -..128 to 147 
 
 Making Cranes or Syphons 151, 153 
 
 Making Lift Pump 155 
 
 Making Barge Pump 156 
 
 Making Oil Pump 1 159 
 
 Making Jigger Pumps 160, 161 
 
 Making Copper Pipe 171, 172 
 
 Making Templates 183 
 
 Making Bends 186 to 190 
 
 Making Outlets 199, 201 
 
32 2 INDEX. 
 
 Making Expansion Joints 204 to 207 
 
 Making Tee Pieces ... 209 
 
 Making Three-Way Pieces i -.. 211 
 
 Making Cross or Four-Way Pieces : 213, 214 
 
 Making Large Bends 224 
 
 Making Double Bends 227, 228 
 
 Making Shortest Bends .;, 232, 233 
 
 Making Air Pipes 234, 237 
 
 Making Hollow Spheres 241 to 247 
 
 Making Valve Chimneys 254, 255 
 
 Making Valve Covers 260 
 
 Making Dome Covers 262 to 267 
 
 Making Square and Round Coils 269 to 280 
 
 Making Large Open Brewing Coppers 281 to 292 
 
 Making Dome Coppers 293 
 
 Making Dome and Pan Coppers . 299, 300 
 
 Making Tallow Coppers 301 
 
 Making Dyers' Coppers 307 
 
 Making Sugar Tieches 311 
 
 Making Stills - 312 to 316 
 
 North Side of Old Shop 9 
 
 Nautilus Scoop,, Brazed and Wrinkled 143 
 
 New Locomotive Coppersmiths' Shop 167 
 
 New Way of Making Bends 189 
 
 Old-Fashioned Whale Oil Lamp i 15 
 
 Oval Tea-Kettle, Top Seamed On 67 
 
 Oval Tea-Kettle, Top Razed Down 67 
 
 Oval Tea-Kettle, Dimensions 69 
 
 Old-Style Muller 77 
 
 Oval Pudding Pot 89, 92 
 
 Old-Fashioned Stewpan , 94 
 
 Oil Pumps 159 
 
 Outlets 199 
 
 Piece Doubled for Mending Split 18 
 
 Piece Put Through from Inside of Pan 18 
 
 Piece Put In from Outside 1 18 
 
 Piece Riveted In 19 
 
 Piece Cramped and Brazed In 19 
 
 Pieces Dogged Together for Planishing 23 
 
 Planishing at the Block 24 
 
 Punching Holes in Sides 28, 288 
 
 Punching Holes in Bottom 29, 288 
 
 Pipe Pattern 32 
 
 Pattern for Socket Handle 38 
 
INDEX. 323 
 
 Pattern for Frying Pan 43 
 
 Pattern for Half Ball 49 
 
 Pattern for Tea-Kettle Spout.. 53 
 
 Pitching Spout Collars 56, 58 
 
 Position to Sit While Planishing 64 
 
 Pattern for Oval Tea-Kettle Bottom 67 
 
 Pattern for Muller. 72 
 
 Pattern for Old-Style Muller 77 
 
 Pattern for Funnel 81 
 
 Pattern Coffee-Pot Spout 85 
 
 Pattern for Warming-Pan Body 114 
 
 Pattern for Dripping Pan 120 
 
 Pattern for Coal Hod 126 
 
 Pattern for Coal Scoop Bridge and Body _> 129 
 
 Pattern for Back and Foot of Coal Scoop 131 
 
 Pattern for Flat-Bottom Scoop 136 
 
 Pattern for Back. of Tudor Scoop 138 
 
 Pattern for Raised Nautilus Scoop 138 
 
 Pattern for Nautilus Scoop Bridge 142 
 
 Pattern for Nautilus Scoop, Cut and Brazed 143 
 
 Pattern for Royal Scoop 145 
 
 Pattern for Bottom of Boat Scoop 146 
 
 Pattern for a Made Bend -._:_ 190 
 
 Pattern for Expansion Joint 205 
 
 Pattern for Tee Piece . 210 
 
 Pattern for Three-Way Piece 212 
 
 Pattern for Cross or Four-Way Piece 214 
 
 Pattern for Shortest Bends 233 
 
 Pattern for Air Pipe or Ship Ventilator 236 
 
 Pattern for Half Ball or Hollow Sphere 246 
 
 Pattern for Valve Chimney Bell ... 254 
 
 Pattern for Valve Chimney Foot 259 
 
 Pattern for Dome Cover Foot 263 
 
 Pattern for Dome Crown : 264 
 
 Pattern for Quarter of Copper Side 283, 284 
 
 Pattern for Quarter of Copper Dome 295, 296 
 
 Pattern for Tallow Copper Brim . 305 
 
 Pattern for Still Boiler , 314 
 
 Putting in Muller Bottom 75 
 
 Pitched Cover for Muller 77 
 
 Planishing Muller Cover 79 
 
 Piening Hammer 85 
 
 Pudding Pot and Cover 88 
 
 Pattern Wrinkled for Raising 114 
 
324 INDEX. 
 
 Preserving Pans, How to Raise Them 117 
 
 Planishing and Smoothing 148 
 
 Planishing Hammers 149 
 
 Photographs of Railway Shop Inside 168, 169 
 
 Planishing Bends 188, 227 
 
 Patching Pipes 196, 197 
 
 Photographs of Maudsley, Sons & Fields' Coppersmiths' Shop in London, 
 
 England - 221, 222 
 
 Portable Fire and Its Uses 1 226 
 
 Planishing Pipe ___ 237, 239 
 
 Photograph of Hendry & Co.'s Shop in London 269 
 
 Planishing Copper Bottom 287 
 
 Preparing to Turn Brim of Dyers' Copper 308 
 
 Repairing and Tinning 17 
 
 Riveting Together Sides of Copper 28, 288 
 
 Raising Hammer 36 
 
 Riveting Hammer . 36 
 
 Raising Up Side of Frying Pans on Shank 43 
 
 Razing Down Wrinkles 44, 45 
 
 Raising Up Water-Balls.. 48, 49 
 
 Razing Down Tea-Kettle Tops 62 
 
 Razing Down Pudding-Pot Bodies 88 
 
 Raising Up Warming-Pan Bodies 114 
 
 Raising Up Preserving Pans 117 
 
 Raising Up Back and Bridge of Scoop 140 
 
 Rope Grommet for Bending 184, 185 
 
 Raising Up Half of Cross Piece 213, 215 
 
 Raising Hammer 215 
 
 Raising Up Hollow Spheres 242, 244 
 
 Razing Out Bell Tops for Valve Covers and Chimneys 256 
 
 Razing Out Valve Cover Foot 258 
 
 Razing Out Dome Cover Foot 264 
 
 Rivet Card Complete 308 
 
 Smelting Copper 4 
 
 South Side of Old Shop . *. 10 
 
 Stewpan Repairing . 18 
 
 Shell Pieces, Making of 19 
 
 Sal Ammoniac Wad _ 19 
 
 Shell Piece Riveted In 19 
 
 Shell Piece Brazed In 19 
 
 Sides of Copper Formed 28, 288, 289 
 
 Sides with Holes Punched for Rivets 28, 288, 289 
 
 Spotting Coppers 29 
 
 Scrubbing Rivets 29 
 
INDEX. 325 
 
 Showing How Bottom of Brewing Copper is Crowned 32 
 
 Side Stake] 36 
 
 Side of Hand Bowl 36 
 
 Sides of Bowl Working to Shape ... - 37 
 
 Socket Made Ready for Flap 39 
 
 Stock-Pot Handle 51 
 
 Spout Tools 54 
 
 Spout Making 53, 54 
 
 Spout Filling and Bending . 55 
 
 Spout Bending, Old Way 57 
 
 Spout Bending, New Way 57 
 
 Solid Copper Tea-Kettle Ring 60 
 
 Showing Kettle Cover in Seat of Ring 66 
 
 Spring Faced Planishing Hammer 73 
 
 Spring Face Detached from Hammer 73 
 
 Spirit Measure 82 
 
 Spout Pattern for Coffee Pot 85 
 
 Saucepan Cover 88 
 
 Saucepan Handles 1 88, 89 
 
 Stewpans 93 
 
 Stewpan Handles 94 
 
 Stockpots, Way to Get Sizes 99 
 
 Stockpot, Showing Strainer and How Putin 100 
 
 Section of Brazing Pan Cover 105 
 
 Separate Parts of Tea Boilers 111 
 
 Socket Handle for Warming Pan 116 
 
 Spring Hammer for Planishing 134 
 
 Syphons 151 
 
 Solder Reed for Charging Seams 155 
 
 Swaging and Smoothing Pipe 159 
 
 Single and Double Jigger Pumps 160 
 
 Standards for Holding Up Pipe 172 
 
 Soft Soldering Large Joints 180 
 
 Skimming Rod 181 
 
 Seaming Bends in Throat and Back 189 
 
 Single and Double Template Boards 191 to 194 
 
 Shaping Expansion Joints 206 
 
 Saddle Forges 218, 259 
 
 Slinging Bends for Brazing 225 
 
 Solder, Black (Never Use It) 231 
 
 Showing First Form of Half Ball 242, 244 
 
 Sides of Copper Ready for Riveting 28, 289 
 
 Screw Valve for Dome and Pan Copper 300 
 
 Sectional View of Tallow Copper 302 
 
326 INDEX. 
 
 Still with Head and Worm Complete.. 315 
 
 Tinning Kitchen Utensils 20 
 
 Truing Up Sides of Copper 28 
 
 Table of Dimensions, Capacity and Weight of Coppers 34 
 
 Tea-Kettle Handles 51 
 
 Tinning Stewpan Rims Outside 98 
 
 Trough and Bar for Turning Pipe 155 
 
 Tanners' Pump 156 
 
 Taking Templates 183 
 
 Tee Pieces 209 
 
 Three-Way Pieces 211 
 
 Three-Section Firepot 229^ 
 
 Trestle and Mandrel for Planishing 237 
 
 Tools for Raising Up Half Balls 244 
 
 Thousand Barrel Copper 291 
 
 Tallow Coppers 301 
 
 Time Consumed Repairing Some Copper Jobs 301 
 
 Tieches (Sugar) 311 
 
 Uses of Copper.. 2 
 
 Valve Chimneys 254 
 
 Valve Covers... 260 
 
 Valve Cover in Parts 260 
 
 Valve Cover Slung at Fire for Brazing Seam 260 
 
 Washing Coppers 26 
 
 Way to Fit in Pipe and Cock 32 
 
 Way to Put Flaps on Handles 38 
 
 Way to Hold Socket to Fire 39 
 
 Water Balls 47 
 
 Working Throat of Tea-Kettle Spout 53 
 
 Wisp Used for Tinning 64 
 
 Wiring Funnels . 82 
 
 Working Cover of Brazing Pan 105 
 
 Well, Strainer and Cover of Dripping Pan .119 
 
 Wooden Former 134 
 
 Working Up Back and Bridge of Scoop 140 
 
 Way to Prepare Patches for Pipe Splits 197 
 
 Wiring Bend Together for Brazing 225 
 
 Working Out Dome Foot 264 
 
 Working Up Dome Crown 265, 266 
 
 Wheel and Axle for Brazing Coil Joints 275 
 
 Working Rivets and Time Consumed 288, 301, 310- 
 
235 90 
 

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