iixii; : 
 
 
 ■.;;'■■ 
 
 '■:■'■'•■ ' ; 
 
 , 
 
 • : ' : 
 
 
 ItBh 
 
 
 . : ;■' 
 
 
HA 
 
 CORNELL 
 UNIVERSITY 
 
 COLLEGE OF 
 ARCHITECTURE 
 LIBRARY . 
 
Cornell University Library 
 NA8201.B74 
 
 Farm buildings; a compilation of plans f o 
 
 3 1924 015 223 765 
 
 DATE DUE 
 
 
 «***&*, 
 
 ■ ia f t-- . ^ 
 
 J> fVV) 
 
 
 MIMrCOlNU-S.A 
 
Cornell University 
 Library 
 
 The original of this book is in 
 the Cornell University Library. 
 
 There are no known copyright restrictions in 
 the United States on the use of the text. 
 
 http://www.archive.org/details/cu31924015223765 
 
I" 
 
 < 
 
 a 
 
 s 
 W 
 
 B 
 
 o 
 
 w 
 
 OS 
 H 
 K 
 
 OS 
 
 O 
 
 W m 
 
 W 
 
 
 
 K 
 
 W 
 
 J 
 ►J 
 <J 
 
 w 
 
 PS 
 
 o 
 
 Q 
 Z 
 < 
 PQ 
 4 
 
FARM 
 BUILDINGS 
 
 , * < , , , A COMPILATION OF ,,,,,, 
 PLANS FOR GENERAL FARM BARNS, 
 CATTLE BARNS, HORSE BARNS, SHEEP 
 FOLDS, SWINE PENS, POULTRY 
 HOUSES, SILOS, FEEDING RACKS, ETC. 
 
 ALL REPRESENTING CONSTRUCTION IN ACTUAL USE. 
 
 CHICAGO: 
 
 SANDERS PUBLISHING CO. 
 
 1905. 
 
tjto^leej 
 
 COPYRIGHT, 1904. 
 SANDERS PUBIJSHING COMPANY, 
 
 ALL RIGHTS RESERVED. 
 
PUBLISHER'S NOTE. 
 
 1 ■ 'HIS is not a book of proposed plans for farm buildings, but for the most part is 
 * a presentation of actual construction by practical men. It is in the main a com- 
 pilation of the best plans contributed to The Breeder's Gazette by the farmers and 
 stockmen of the United States in recent years. Many different types are illustrated. 
 Different farms, different latitudes and different methods of management demand an 
 infinite variation in the style, dimensions and detail of American farm buildings. 
 
 In barn building as in the planning of the farm home, nearly every individual 
 has his own peculiar ideas and tastes. It is rarely that one is entirely satisfied with 
 what a neighbor has done in such matters. At the same time it is clear that many 
 general propositions and many matters of detail possessing real value to a prospective 
 builder may be gleaned from a study of what successful farmers in different parts of 
 the country have already carried out. 
 
 In the belief that many helpful hints will be found in these pages and to fill a 
 persistent demand for information upon the subject treated the publishers present this 
 compilation with full confidence that it will meet with general appreciation. 
 
TABLE OF CONTENTS. 
 
 PAGE 
 
 Location and General Arrangement . . . 11-14 
 
 The Modern Barn 15-19 
 
 Wing's Joist Frame 17 
 
 General Farm Barns 19-38 
 
 Bank Barn, A.. 33 
 
 Barn for Small Farm 38 
 
 Barn of Round Poles 38 
 
 Basement Barn and Carriage House ... 33 
 
 Circular Barn, New Type of 23 
 
 Farm Barn, Good Type of 37 
 
 Hay Barn, A Joist Frame 36 
 
 Horses and Range Cattle, Barn for. ... 38 
 
 Indiana Farm Barn 29 
 
 Iowa Experiment Station Barn 25 
 
 Kentucky Farm Barn 30 
 
 Kentucky Stock Barn 35 
 
 Lovejoy's Farm Barn 21 
 
 Minnesota Farm Barn 19 
 
 Ohio Farm Barn 33 
 
 Small Barn. Plan for 37 
 
 Stock and Hay Barn 25 
 
 Stock Barn, A Small 36 
 
 Umbrella Barn, The Glide 39 
 
 Whitehall Cattle and Horse Barn 29 
 
 Wisconsin Farm Barn 29 
 
 Cattle Barns 39-56 
 
 Breeding Cattle, Barn for 50 
 
 Corn-Belt Barn 48 
 
 Feeding Barn, A Cattle 53 
 
 Feeding Cattle Loose, A Barn for 54 
 
 Hawkeye Cattle Barn 42 
 
 Hoosier Cattle Barn 47 
 
 Illinois Cattle Barn 50 
 
 Indiana Cattle Barn 43 
 
 Iowa Cattle Barn 41 
 
 Kansas Cattle Barn 40, 43 
 
 Missouri Barn Plan 53 
 
 Modern Type of Cattle Barn 49 
 
 Morgan Cow Barn 41 
 
 Octagonal Cattle Barn 47 
 
 Steer Barn, An Iowa 54 
 
 Open-Centre Cattle Barn 51 
 
 Sale Barns 55, 56 
 
 Horse Barns and Stables 57-76 
 
 Bank Stable TO 
 
 Barn for Forty Horses 70 
 
 Colt Stables, Convenient 74 
 
 Horse Barn Without Cross Ties 
 
 Illinois Stallion Barn 
 
 Iowa Stallion Barn 
 
 Kentucky Barn for Speed Horses 
 
 Kentucky Coach and Stallion Barn 
 
 Light Horses, Barn for 
 
 McMillan's Horse Barn 
 
 Montana Horse Barn 
 
 Mule Barn 
 
 Nebraska Horse Barn 
 
 Oaklawn, Stabling at 
 
 Plan for Horse Barn 
 
 Plymouth Hackney Stud Stables 
 
 Stallion Barn, A Modern 
 
 Three-Story Farm and Horse Barn 
 
 Dairy Barns 
 
 Cow Barn 
 
 Hygienic Dairy Barn 
 
 Illinois Dairy Barn 
 
 Nebraska Dairy Barn 
 
 Pennsylvania Dairy Barn 
 
 Round Barn 
 
 Wisconsin Dairy Barn 
 
 Swine Barns and Houses 
 
 Farrowing Pens, Lovejoy 
 
 Farrowing Pen for Early Litters 
 
 Feeding Floor and Pig Houses 
 
 Hog House for Sows and Pigs 
 
 Illinois Hog House 
 
 Maryland Hog House 
 
 Morgan Hog Barn 
 
 Movable Hog House 
 
 Nebraska Hog House 
 
 Portable Pig Pen 
 
 Twenty Sows, House for 
 
 Sheep Barns and Sheds 
 
 Baby Mutton Factory 
 
 Barn with Glass-Covered Lamb Shed. 
 
 Experiment Station Sheep Barn 
 
 Feeding Barn for Sheep 
 
 Feeding Shed for Sheep 
 
 Interior Arrangement of Sheep Barn . 
 
 Lambing Barn for the South 
 
 Lambing Shed 
 
 Morgan Sheep Barn 
 
 Nebraska Sheep Barn 
 
 Small Sheep Barn 
 
 Utah Sheep Shed 
 
 page 
 63 
 73 
 68 
 71 
 61 
 60 
 71 
 62 
 76 
 65 
 58 
 64 
 70 
 63 
 67 
 
 77-85 
 81 
 82 
 77 
 83 
 84 
 77 
 85 
 
 86-97 
 94 
 92 
 95 
 90 
 
 87 
 
 95 
 
 87 
 
 94 
 
 90 
 
 97-110 
 
 102 
 
 105 
 
 99 
 
 107 
 
 107 
 
 105 
 
 108 
 
 109 
 
 98 
 106 
 102 
 
10 
 
 TABLE OF CONTENTS. 
 
 Poultry Houses 111-120 
 
 Convenient Poultry House 114 
 
 Design for Poultry House 116 
 
 Farm Hen House 115 
 
 Farm Poultry House 119 
 
 General Remarks Ill 
 
 Hen House, A Convenient Small 120 
 
 Hen House, Good Type of 117 
 
 House for One Hundred and Fifty Hens . 117 
 
 House for Two Hundred and Fifty Hens. 118 
 
 Illinois Poultry House 116 
 
 Simple and Practical Ben House 118 
 
 Summer Hen House 115 
 
 Miscellaneous 120-177 
 
 Anchoring a Barn 158 
 
 Breeding Box for Swine 158 
 
 Bull Stocks 160 
 
 Cement and Concrete Work 129-133 
 
 Cistern Making, A Hint on 173 
 
 Covering Stacks, Device for 162 
 
 Cribs, Granaries and Workshops 127-129 
 
 Dehorning and Hog-Ringing Device. . . 159 
 Dipping Tanks 166-172 
 
 Drainage System, A Farm 173 
 
 Drinking Fountain 161 
 
 Feed Racks and Troughs 133-138 
 
 Fences 138-146 
 
 Fence-Breaking Bulls, Device for 162 
 
 Gates 146-156 
 
 Hay Barracks, Joist Frame 129 
 
 Holding Hogs, Device for 160 
 
 Hog Loader, A Portable 163 
 
 Hog Pen Front 157 
 
 Ice Houses. . , 163-165 
 
 Roofs and Roofing 174 
 
 Self-Sucking Cows, Devices for 158 
 
 Shipping Crate for Hogs 162 
 
 Silos 120-127 
 
 Stalls for Cattle 175-177 
 
 Ventilation of Stables 165 
 
 "Wagon Rack and Stanchion 156 
 
 Water Closets 174 
 
 Water in the Cow Stable 174 
 
 Whitewash Formula 174 
 
 Water Supply, The Farm 172 
 
 Water Tank of Earth 173 
 
 Appendix 177-185 
 
FARM BUILDINGS. 
 
 LOCATION AND GENERAL ARRANGEMENT. 
 
 The planning and construction of farm build- 
 ings should be done with regard to the surround- 
 ing outside features as much, as to the interior 
 arrangement and convenience of the rooms. It 
 is a common error to see little forethought taken 
 in the placing of the buildings, in their relation 
 to each other or to the surrounding conditions; 
 the total disregard of a fine outlook that may 
 have been had from the windows that are most 
 frequented; many errors in the proper way to 
 approach the house from the highway, and many 
 times the utter absence of any attempt at orna- 
 mentation in the way of tree planting — nothing 
 save bare sides and sharp angles of buildings 
 open to all winds, storms and sun heat, or the 
 opposite extreme, burying the house in a dense 
 shade of loneliness. 
 
 Now this should not be so. When the advan- 
 tages and increased value of the property as a 
 whole are considered it is at once apparent. Any 
 one can distinguish between a nice farm, a place 
 where it would be a pleasure to live, and on the 
 other hand one that is bare and uninviting. The 
 cost is a matter of forethought on the part of 
 the individual at the beginning in the planning 
 of the work, and the actual material to be used 
 
 y in beautifying the grounds almost always can 
 be had for the gathering. One may easily find 
 the time to do the work when once he has 
 tasted of the pleasures there are in surroundings 
 that are made attractive with trees and plants 
 arranged to make a landscape that is ever 
 improving and changing in scene. 
 
 When a beginning is made toward embellish- 
 ment of the home surroundings then there is 
 a new birth given, the feeling of attachment 
 that reflects back into pleasant and longing 
 recollections of the happy lives passed there, 
 and the far-reaching influence of cheerful home 
 surroundings on the character and future life 
 
 y of the growing generation toward the good and 
 high of ideal life is above any estimation, besides 
 being a source of interest and everlasting joy 
 and pleasure alike to the owner and to all who 
 enter here. 
 
 Farming is not all corn. There are many fine 
 farms that are -only such from the fact that_ 
 there is a quiet natural park-like effect resting 
 
 over the home place and if favored with a fertile 
 soil and a kind climate how much more blest we 
 could be if we would bring about us more of the 
 natural beauties so abundant everywhere. This 
 need not detract an instant from the economical 
 ■ operation of the farm but if practically planned 
 should add many fold thereto. 
 
 We can assume that the residence and other 
 buildings are already placed, or that building is 
 to be done at some future time. With respect 
 to the all-important question of choosing the 
 house site, the custom in the city seems to be the 
 law without recourse in the country, in that the 
 house must stand facing square, with the best 
 rooms toward the public road. If a better expo- 
 sure or a fine scene lies in another direction, 
 reverse the order regardless of the highway. 
 Again, houses are dropped in a hollow, carried 
 to the top of a bare hill, or placed too near dusty 
 roads or stables, making things more disagree-, 
 able than convenience would compensate. The 
 house should not be put on a poor or waste piece 
 of ground just to gain a little extra tillable land>" 
 
 Personal preferences should of course be taken 
 into consideration, but as a rule many desirable 
 locations are ignored. Among the specific direc- 
 tions to apply in selecting the home site are good 
 sanitary conditions. These demand air and 
 quick drainage of water. All this is secured on 
 a dryish soil, slightly elevated if possible and 
 fairly open to admit a free circulation of air. 
 Any protection against prevailing north and west 
 winds in the winter season, such as hills, trees 
 or any other natural objects in the track of regu- 
 lar storms, should be made use of, but cool and 
 refreshing winds should not be hindered in their 
 direction during the heated season. 
 
 The distance from the highway is hardly a 
 matter of importance. If the best place is 400' 
 from the road it ought to be chosen over another 
 less desirable, though 200' nearer. Besides this 
 an entrance approach of reasonable length, if 
 properly laid out among a > grove of trees, will 
 add much to the dignity and bearing of the 
 place. The relation of the house and barn should 
 be such that they do not appear as a part of 
 each other and in driving to the house one is not 
 led first through yards and past gaping barn 
 
12 
 
 FARM BUILDINGS. 
 
 doors. The barn should occupy a position so 
 that the prevailing winds will carry the stable 
 odors in a direction away from the house and 
 not toward it, as is often the case. The exact 
 position and arrangement of the out-buildings 
 and enclosures will be according to their use, 
 and to be convenient should be few and com- 
 
 • pact and not scattered over a whole area. Pens, 
 sheds and stacks should not be conspicuous in a 
 general front view. 
 
 In country houses broad simple design is much 
 
 ^to be preferred. All about a house of this order 
 there is a quiet dignity and homelike restfulness 
 that, is in pleasing harmony with every rural 
 landscape. The rooms should be few and large. 
 The veranda is right if one step up from the 
 ground and at least 10' wide, and a porte- 
 cochere or carriage porch should be a part of 
 every country house, as it surely is a comfort 
 when rainy or windy to drive up to the door 
 
 ^ under a roof. Especially is the excessive use 
 of all "ginger-bread" mill work in gable orna- 
 ments, railings, brackets and the like to be dis- 
 couraged, as such detail soon falls into decay and 
 is a constant item of repairing and the greater 
 part of it is vulgar and meaningless. Likewise 
 the use of many discordant colors in outside 
 paintin? is not in keeping with surroundings; a 
 modest neutral shade that blends with the fields 
 ■ and trees is the correct- one. Eed is a good and 
 cheap color for barns and possibly for houses 
 also, but it should be shaded down and the glare 
 and flash taken off. 
 
 ' Features of the natural landscape should 
 receive great consideration, as it is these that 
 give character to the farmstead. A grove of 
 noble trees on a slight eminence would at once 
 suggest the future home site. In the choice of 
 views here is a suggestion as to the points ,of 
 interest: first would come the immediate sur- 
 roundings made beautiful with lawn, trees and 
 shrubs, and farther out the adjacent fields of 
 growing crops or pasturing animals are con- 
 stantly in mind. The neighboring farm houses, 
 the travel on the highway, or a speeding rail- 
 road train are all of every-day attraction. The 
 landscape that is characteristic of the particular 
 country, a broad far prairie scene that holds 
 hands with the horizon beyond; hills or wood- 
 lands bounding the view with their picturesque 
 sky line, a river or winding stream with wooded 
 shores and spanning bridge or a lake of broad 
 expanse and quiet surface— all these are everlast- 
 ing scenes of delight and inspiration. 
 
 Now as a practical demonstration of how a 
 farm can be developed in a complete and intelli- 
 gent manner, reference to the example shown by 
 the plan will serve to clinch the essential points 
 mentioned. The plan represents a general 
 
 scheme for the layout of a 160-acre prairie farm. 
 There are no trees on the tract of any import- 
 ance ; the surface is slightly rolling with no 
 prominent elevations anywhere — in all a typical 
 grain and stock farm; corn, oats, some wheat, 
 hay and pasturage, almost all sold off in the 
 finished products of beef and pork. It is believed 
 that this scheme comes very near an economical 
 use of all of the land combined with a beautifi- 
 cation of the home surroundings, a park-like 
 entrance and approach drive, a commanding 
 position for the house and the farm buildings 
 centrally located and accessible from all parts 
 of the premises. 
 
 The house is placed in a ten-acre piece, which 
 ,/may be properly called the home plot. Here are 
 collected all the buildings (except the barn and 
 feeding lot), orchard, vegetable and fruit garden, 
 shaded lawn, flowers and all that goes into daily 
 life. This plan leaves no waste ground; every- 
 thing is compactly arranged and yet in such a 
 manner as to allow the extension of any particu- 
 lar part without interfering with another. 
 
 The residence is about 700' from the high- 
 way and stands in the southwest corner of the 
 home plot, the ground sloping off gently to the 
 south. All the main rooms have a south and east 
 exposure. It is approached from the public high- 
 way on a curve which is in the direction of the 
 most traffic (the city in this case). This is a 
 much better way than entering at right angles 
 and adds greatly to the appearance of the 
 entrance and does not allow a direct view up the 
 drive from the road. The drive slants over 
 until within about 20' of the fence; it then 
 parallels the fence in a straight line to the barn. 
 A short distance from the house a branch road 
 leads over on a gradual curve to the carriage 
 porch, passing underneath it; the curve then 
 continues and joins the main road to the barn. 
 By placing the house about 70' or so from the 
 main drive all clatter and noise of teaming is 
 to a large degree shut away from contact with 
 the rooms and a nice lawn space comes up to 
 the house on that side. This entrance road is 
 ten feet wide, the branch nine feet, graded with 
 gravel from a near-by pit and smoothly surfaced 
 off with a crown just sufficient to turn the water. 
 
 The barn is 250' from the house and is set 
 40' into the ten-acre pasture to the west, 
 with a silo on the north side convenient alike to 
 the barn and feeding lot. Another building is 
 put up 80' directly east for general storage 
 purposes of machinery, wagons, supplies and 
 repair shop. The space between the barn and 
 storage house should be drained and bedded with 
 gravel to serve as a general movement yard and 
 entrance for both buildings; a place to set up 
 the shredding outfit, grinding, unloading and 
 
LOCATION AND GENERAL ABHANQEMENT. 
 
 13 
 
 the like. Water is piped into this yard and to 
 the house from the tank and well just back of the 
 storage house. A poultry shed is at the north of 
 this building. 
 
 A good big orchard contains about 125 trees, 
 including apples, pears, plums and cherries, 
 
 manent than the raspberries and blackberries, 
 which can be moved bade and forth into the 
 nursery ground when they get old and worn out 
 'in one place; currants and gooseberries are also 
 planted. The strip for nursery purposes does 
 good service in growing trees and bushes to set 
 
 m^sm^^^ 
 
 JTO. 1— PLAN FOB LAYING OUT A 160-ACRE FARM AND I\ARM HOME. 
 
 which will give plenty of fruit for home use and 
 much to sell. A fence is run along the lower side 
 of the orchard ; then the pigs can be turned in any 
 time to consume the fallen fruit, although the 
 trees will be cared for the same as a crop of corn. 
 One acre is given to small fruits. The grapes are 
 put next the orchard because they are more per- 
 
 out in the future. A row of hot-beds and frames 
 is useful in many ways; it is protected along 
 the north with evergreen trees. The vegetable 
 garden of one and one-quarter acres will give 
 abundance of good things and all that is left over 
 the pigs will take as dessert. The strawberry 
 patch is moved about the garden every year or 
 
14 
 
 FARM BUILDINGS. 
 
 two. Asparagus and rhubarb are along the fence. 
 
 A lawn space bounds the house on all sides, 
 varying in width from 150' to 200'. It is not 
 necessary, however, to keep it closely mown. In 
 the rear the grass covers the clothes-drying 
 space; further back are the beehives and a place 
 for the wood pile. The grounds about the house 
 are planted with trees for shade and beauty; a 
 place for children to play and climb and a source 
 of recreation and ease for the older members of 
 the family. As to the kinds used for this p'Ur- 
 pose : in making the ground work or foundation 
 of the scene use such native trees as are found 
 ''growing in the immediate locality ; elms, maples, 
 lindens and. ash are in greater abundance. All 
 these trees are reasonably quick in growth, bear 
 transplanting well and will therefore prove a 
 success from the start. Hawthorns, wild cher- 
 ries, plums and crab apples, juneberry, dogwood 
 and redbud are planted in the places to thicken 
 up and mass with the other trees; occasionally 
 they appear in detached groups or specimens by 
 themselves. They will lend variety and charm 
 to the surroundings in the springtime with their 
 white, pink and red flowers, and in the autumn 
 many of them close the growing season with a 
 contrast of scarlet fruits and golden-hued foliage. 
 
 Along the entrance road the work is done in 
 a like manner. Evergreen trees — pines and 
 spruce — are planted in clumps; at the left hand 
 side of the entrance gate is one group,- farther 
 up on the other side another. On the west and 
 northwest sides of the house are thick groups 
 'to lessen the prominence of the barn, to check 
 cold winds and vary the effect with the deciduous 
 trees. Trees are placed along those sides of the 
 barn ; seen from the highway they will soften the 
 blank barn side and give a proper setting to the 
 building as a whole. The gable and tower 
 appearing among the tree tops will mark a dis- 
 tinctly rural scene. To protect the buildings and 
 feeding lots somewhat against the direct force of 
 cold northwest winds groups of Norway spruce 
 are planted in alternate groups with deciduous 
 trees, as shown in the plan, north of the barn 
 and act as a wind check. 
 
 The entrance gate should be set in at least 
 thirty feet from the fence line, leaving an open 
 space of 60' to 70' on each side of the drive, as 
 shown in the plan. This space is planted with 
 trees, and if an elm is planted on each side of the 
 gate a beautiful arching effect will be had over 
 the formal entrance to the place. 
 
 A tree to appear in all its natural beauty 
 should spread its branches out and down to the 
 ground on all sides. Never trim all the branches 
 off and expose a bare stem, nor hack off the ends 
 of branches and make a stubby, broom-shaped 
 thing. If a good set of roots is dug with the 
 
 tree no pruning is required. Pruning of orna- 
 mental trees is properly a thinning out in the 
 center of minor twigs and branches. Let the 
 tree develop into its own natural form. Cutting 
 can never accomplish this. 
 
 Shrubs should be massed in a border along the 
 entrance drive next to the fence, to add variety 
 with their foliage and flowers at different times. 
 An irregular massing of shrubbery forms a boun- 
 dary belt along the east and south sides of the 
 house. The lawn extends out on those sides to 
 this border; along the edges next the grass is the 
 place for hardy flowers, native perennials and 
 any other favorites that are desired; here they 
 will be in charming contrast with the lawn and 
 bushes. The kinds of shrubs used are wild native 
 species found growing in the neighborhood, such 
 as dogwoods (the red^branched and others), 
 sumach, elderberry, wild rose, Indian currant, 
 snowballs, spiraea, lilacs, mock-orane and 
 honeysuckles. Japan quince and forsythia are 
 nice in places where they are seen from the win- 
 dows, because of their early blossoms. So are 
 those early flowering trees, such as juneberry, 
 wild goose plum, Judas tree and dogwood. Such 
 early spring flower scenes of color are delightful 
 to children or invalids who are confined to the 
 house until the weather becomes, milder. Vines 
 ramble all over the porch columns and up 
 the fireplace chimney on the west side of the 
 living room. 
 
 The views from the house are indicated by the 
 converging lines-. (Fig- 1-) Three different 
 scenes are open from the living room: We have 
 the veranda along the south and east sides of 
 this room. To the west the sight is across open 
 fields to the lowering sunset. Different openings 
 through the trees give glimpses of the life on the 
 highway. Out of the dining room the pic- 
 ture is one of sunlight and shadow, over the open 
 lawn, under the trees to the color of flowers. 
 The kitchen and rear porch are shaded in the 
 summer; a walk connects them with the drive; 
 storage room is ample; the office is handy to the 
 drive and an outlook to the west; the carriage 
 porch and entrance hall face west. 
 
 In conclusion we may say that the farm home 
 stands as the central feature, with the barns in 
 a subordinate position. They are then brought 
 into harmonious relation with each other 
 through the artistic planting of native trees. 
 Orchard and gardens are grouped as nearby 
 accessories and the grounds about the house are 
 further enriched with shrubs and flowers. The 
 drive and walks allow convenient and easy access 
 to all places and lead in a natural manner to the 
 highway. Along the highway and in groups 
 about the boundaries and cross fences trees are 
 planted as per introduction and outline. 
 
THE MODERN BARN. 
 
 Do you want a barn? Have you any definite 
 idea of what it is that you want? Have you 
 carefully considered first your means, then your 
 needs, then the needs of years to come? Is it 
 your idea to build a small, cheap barn that will 
 hold a few tons of hay, the grain, a few cows, 
 the working horses, a colt or two, the farm 
 machinery, the chickens and ducks? If that is 
 your idea think whether it is economy to shelter 
 farming tools on the barn-floor, which means 
 that they are endlessly, in the way and that 
 they have a shed costing ten times what one 
 would cost designed especially for such a pur- 
 pose. No farmer can afford to build a barn with 
 such a small storage capacity for forage that he 
 will be compelled to fill it in summer and then 
 re-fill it again and again during the winter and 
 spring, drawing hay from the stacks, damaged 
 in quality and at double the expense of putting 
 it directly where it is to be used. 
 
 Is it not cheaper to make shingles shelter a 
 depth of 20' or 25' of hay than a depth of 5' 
 to 15' ? Consider whether it is real economy to 
 combine into one barn all the shelter and stor- 
 age room needed on the farm. There is fire to 
 be considered and convenience in handling stock. 
 Do you wish the colts or cows to run in the yard 
 with the pregnant ewes? Do you wish to mix 
 breeding sows and small lambs? 
 
 The barn must fit the farm and the needs of 
 the farmer. It is folly to insist that any one 
 type of building is of universal suitability. There 
 ^ is this thought to consider when building a barn : 
 Building is one of the great events that come 
 far apart. After a new barn is built it is not 
 likely that one can afford to add to it or build 
 another for many years. Build, then, of suffi- 
 cient size and capacity to allow for a reasonable 
 growth and expansion of not merely the farm 
 crops but the farm animals. Especially pro- 
 vide ample room for the storage of forage. Sheds 
 may be cheaply constructed to surround the barn 
 and these sheds will shelter the stock, and may 
 be added at any time,, but the storage room of 
 the mow is a fixed quantity when the rafters are 
 put on. 
 
 Notwithstanding the fact that barns must 
 always vary in shape, size and arrangement, it is 
 true that they will have certain things in com- 
 mon if they are modern and up-to-date. 
 
 Beginning at the foundation the modern barn 
 has no sills under it. The basement posts rest 
 directly upon stones, which are bedded well in 
 
 v: 
 
 the ground and should reach below the frost 
 line. Sills near the ground are not merely un- 
 necessary but a nuisance from every standpoint. 
 They decay, harbor rats and obstruct. The 
 modern barn has an earthen floor, preferably 
 hard clay, or cement where necessary. The lat- 
 ter is cheaper than the wooden floor and has 
 very many points of advantage. It conserves 
 warmth, no cold drafts come under it, does 
 not shelter rats, manures do not leach through 
 it and it does not decay. Yet where sheep are to 
 be sheltered or calves or cattle run loose no 1 other 
 floor is needed than the natural earth well bed- 
 ded. Even horses prefer to stand on the ground 
 and many of the most successful horsemen in- 
 sist that their horses shall have earthen floors 
 in their stalls. 
 
 The modern barn has a basement or lower 
 story beneath its entire area used for sheltering' 
 farm animals. The reason for this is that it is 
 in the line of economy; moreover, it is a great 
 convenience to be able to drive through to clean 
 out manure or for other purposes. There is also 
 a free circulation of air through the basement 
 when the windows are opened on opposite sides, 
 there being no wall or mow of hay to oppose the 
 air currents. Modern hay-lifting machinery 
 makes it as easy to lift the hay above the base- 
 ment as to drop it on the ground level. 
 
 In calling this lower story a basement it is 
 not meant that it should be under ground. 
 Where the ground is inclined and level positions 
 are not easy to be had, the old-fashioned bank 
 barn may be considered, yet in adopting this 
 type it should be constantly borne in mind that 
 stone walls are apt to be productive of disease 
 germs, especially of tuberculosis, which thrive 
 in a dark and poorly ventilated barn basement. 
 However, the advantages of a bank barn may be 
 had without sacrificing light or ventilation. Let 
 the earth be heaped against the wall not 
 more than 4' or 5' and above this provide 
 numerous windows, all arranged to open wide. 
 The ventilation of the basement must be care- 
 fully thought out according to climatic condi- 
 tions and the kind of stock to be sheltered. This 
 is a point against sheltering all sorts of animals 
 together. Ventilation that is desirable for the 
 sheep barn is very undesirable for the dairy cows. 
 
 The lighting of the basement is an important 
 matter. Sunlight is the great purifier and de- 
 stroyer of microbes and germs. It adds to the 
 comfort of calves, lambs, and pigs as it conies 
 
16 
 
 FABM BUILDINGS 
 
 through the generous south windows during cold 
 winter days. Glass is fortunately almost as 
 cheap as siding. It will pay for itself many 
 times over if used to let the sun in the barn 
 basement. This also is true of the poultry-house. 
 It is a commentary on the ignorance of a man 
 that so often the farm animals will go almost 
 anywhere rather than into the quarters he has 
 provided for them. If the barn is built right 
 and managed right the animals will need to be 
 shut away from it rather than driven into it. 
 
 An important consideration is that the barn 
 shall store an abundance of provender that may 
 be easily and cheaply put in it. To this end the 
 building must have depth of hay mow without 
 cross-ties through the middle to obstruct the free 
 working of the hay-carrier and fork or the use 
 of slings. For the ordinary barn of about 40' 
 length the height from the level of the mow 
 floor to eaves should be 20' and the best width 
 is between 30' and 50'. The chief consideration 
 is carrying the hay back from the center to the 
 sides when filling the mow. The track on which 
 the carrier runs should be directly in the center 
 of the roof and the hay dropping below it will not 
 easily be carried back more than 25' and on the 
 whole a width of 40' or 45' is preferable. 
 
 The roof should be what is termed "a half- 
 pitch; that is, the rafters inclined at an 'angle 
 of 45 degrees, or the curb roof of two angles. 
 The roofing material should be slate, good shin- 
 gles or galvanized iron. Painted iron roofing is 
 not very satisfactory. 
 
 Almost all manufacturers make carriers that 
 hold the load and run it in at any desired height 
 just to clear the floor or the level of the hay in 
 the mow or up to the peak of the roof, according 
 to the needs of the occasion. The use of such a 
 carrier effects economy in time and power, and 
 results in making better hay, for there is less 
 mow-burning when hay is not dropped from a 
 height. 
 
 It should be borne in mind that most barns 
 are too small, too low, too inconvenient in 
 arrangement, too uncomfortable to the animals, 
 while some are too large (this is rare), and too 
 ornate and expensive. 
 
 The day of ihe barn sill has gone. Instead 
 the posts set directly on stone or piers of con- 
 crete made of cement. Between the post and 
 the pier it is well to lay a block 2" thick 
 which will effectually prevent the absorption of 
 moisture by the bottom of the post. Should this 
 block decay it is readily" replaced. 
 
 Posts should not come clear down to the floor 
 level; the stones or piers should rise 12" to 16 " 
 to throw the post above moisture or manure, 
 which may accumulate in cattle or sheep barns. 
 Box-3talls in horse stables may also be permitted 
 
 to accumulate manure, being kept well littered, 
 and the result is better dryness, and no heating 
 of the well-tramped manure, beside the total 
 saving of all liquids. 
 
 Concrete blocks to set posts on are cheap and 
 satisfactory. They are made right in place. 
 Excavate to solid ground, usually 18" will 
 suffice, a hole 24" square. Make wooden moulds 
 shaped like truncated pyramids 8" square at the 
 top, 18" at bottom or larger, depending on the size 
 and weight of the building. These moulds may 
 hinge together and. fasten with bolts that may be 
 loosened so that they may be easily removed from 
 the blocks. It should be leveled so that the top 
 comes to the right place, then filled with con- 
 crete in which may well be imbedded a good 
 many cobble stones. A %" pin projected upward 
 from center of block and post set down on it 4" is 
 useful, if the building is not very heavy, to keep 
 wagons from butting the posts off the stones. 
 After a few hours of setting the mould may be 
 taken carefully away and another block made. 
 The moulds should be filled full enough to make 
 them of the same level. A surveyor's level at 
 hand. when setting the blocks is most convenient 
 and saves much time and trouble. 
 
 Hard earth is a very satisfactory floor for 
 sheep barns and cattle barns where animals run 
 loose. Earth is desirable for box stalls where 
 they are kept littered, as they should be. Cement 
 should be used for cow stalls and horse stalls. 
 
 Vertical siding is best. Matched siding is sel- 
 dom dry enough so that the tongues stay in the 
 grooves. It is better to use plain unmatched 
 barn boards 12" wide, battened with 3" strips 
 after seasoning. In any event put siding on ver- 
 tically; it is stronger, more durable and cheaper 
 to erect in this way. If you wish to whitewash 
 the building either inside or out use unplaned 
 lumber and the whitewash will adhere better. 
 
 Only' the best shingles should be used. Cedar 
 is said to be durable but the cedar shingles com- 
 monly sold are very thin. Steep roofs last double 
 the time of flat roofs if of wood. Soaking 
 wooden shingles for a moment in boiling linseed 
 oil adds to their durability. A trifle of red color 
 added to the oil adds to the beauty of the roof. 
 The color should not be of sufficient quantity 
 to more than stain. Dip the shingles in large 
 handfuls to the tips, lay them on a piece of sheet 
 iron and let them drain into the kettle. This 
 is said to make inferior shingles last 40 years. 
 They will not crack badly nor curl when so 
 treated. Painting shingles is not recommended. 
 Shingle nails as now made of steel wire will rust 
 off in 10 years or less. They may be had gal- 
 vanized and should be so for either shingles or 
 slate. 
 
 There is no roofing more durable or more 
 
THE MODEBN BABN. 
 
 17 
 
 satisfactory than slate. It is heavier than 
 shingles and requires strong rafters. For barns 
 single-lap slate is coming much into favor; it is 
 lighter and much cheaper than double-lap and, 
 save that storms sometimes blow in a very little, 
 it is as good. 
 
 Perhaps no form of roofing has caused more 
 disappointment and vexation than metal, which 
 rusts rapidly and requires frequent paintings. 
 Galvanized steel seems durable and when well 
 galvanized it has .endured for many years un- 
 injured. Metal roofs are hot in summer. 
 
 _ Kubber, papeT, felt . and asphalt and other 
 kinds of roofing will serve if given proper atten- 
 tion. Barn roofs are usually neglected. 
 
 For eave troughs modern tin rusts through 
 in three seasons. Paint will not prevent rust in 
 a tin eave trough. Galvanized iron is to be pre- 
 ferred. It is well to make eave troughs and 
 spoutings of generous size. 
 
 "Let all hinges be larger than seems neces- 
 sary" is the suggestion of an experienced barn 
 builder. Hinges are cheap; get them strong. 
 Make sliding doors to run on flexible hangers 
 which permit the doors to be raised up at the 
 bottom without twisting the hinges or track. 
 
 Stalls for dairy cows should be 3y 2 ' wide; 
 for beef cattle 4' wide. Three single horse 
 stalls will go in a 16' bent. Four horses 
 may easily occupy the same space in two double 
 stalls and teams accustomed to standing together 
 will do so without injury. Box-stalls should be 
 of .fairly generous size. For cows 7' x 8' is 
 permissible as a minimum; for horses 8' x 10'. 
 Do not make many box-stalls so small. A 
 good horse stall is. 10' x 12'. Horses will eat 
 their hay from the ground in a box-stall with- 
 out waste if not given too much, and many 
 horsemen think it is the best way. Put windows 
 in a stable as high as you can and put in plenty 
 of them. Make doors 4' wide where you 
 can. Make as many of them to slide as you can. 
 A height of 7' in a cow stable is permis- 
 sible if a good system of ventilation is provided. 
 Make the horse stable 8' or higher. Make 
 the sheep barn as well ventilated as possible. A 
 width of 13' between centers of posts works 
 well in the sheep barn. Do not try to put 
 under one roof all classes of stock, tools, hens, 
 and hired men. Do not plan immensely wide 
 hams. They seem economical but greater com- 
 fort and better results come from narrower barns 
 built partly to surround a paved court, sheltered 
 thus from wind and storm. 
 
 • WING'S JOIST FEAME 
 
 Joseph E. Wing thus describes the joist frame : 
 I have for many years studied the question of 
 barn frames and designed a good many types. 
 
 A barn frame should have great strength to up- 
 hold weight, resist wind pressure and withstand 
 the pressure of rafters when weighted with snow. 
 My progress has been a steady evolution towards 
 the simple frame of two stories or more, with 
 curb roof and purlin posts, in which every stick 
 has a purpose and is so placed that it exerts its 
 utmost power in the line of its greatest strength. 
 The frame is an arrangement, an adaptation, 
 and I have not hesitated to adopt other men's 
 ideas. The roof was invented many years ago 
 and used in New York and New England. It 
 has stood the test of 40 years or more in the 
 heavy snows of that region, and I have never 
 seen nor heard of one crushing. Built in the 
 form of an arch it supports itself. The side walls 
 need not be extremely high; from 18' to 20' 
 with this roof gives great storage capacity. 
 They are prevented from spreading by the long 
 
 .</***. 
 
 W W "M 
 
 FIG. 2— WING'S JOIST FRAME. 
 
 brace which will withstand ten times the pull 
 that the thrust of rafters may ever put over it. 
 For very wide barns purlin posts should be used, 
 but up to 50' this roof is safe when rightly 
 framed, with the supplemental truss beneath the 
 angle, and when so framed there is yet a saving 
 in material and convenience over the. old style 
 roof supported by purlin posts. (See Figs. 2, 
 3 and 4.) 
 
 There is no solid timber at all in the frame 
 and few sticks need be of unusual length. There 
 should be full-length posts ; aside from these ties, 
 joist-bearers, plates, nail girts and all may be 
 spliced wherever convenience indicates and by 
 always placing^; piece 2' long behind the splice, 
 and, spiking- well, the whole is made as though 
 of one piece. But one difficulty may confront the 
 builder: the building of hay chutes. It is not 
 desirable to have permanent hay chutes, for with 
 
18 
 
 FARM BUILDINGS. 
 
 the mow unobstructed by cross-ties hay is taken 
 in by sling carriers that grip the rope and hold 
 the draft at any height, thus swinging it in 
 as soon as it clears the level of the hay in the 
 mow or the mow floor, and hay chutes are very 
 often needed in the middle of the barn. To make 
 this come right have the hay chutes made in sec- 
 tions of about 6' high, building them 3%' or 
 4' square, and in this manner build two panels 
 of solid boarding, like doors, say 3%' x 6', and 
 binge together at the edges so that they collapse 
 and lie flat. Provide hooks on one edge and 
 staples on the other. Take two of these pairs 
 and opening them hook together and set over the 
 opening in the floor and you have a section of 
 6' of your hay chute. Fill the mow that high or 
 a little higher and set up another section; thus 
 till the mow is filled. When taking out hay these 
 sections are folded up and hung on pegs in the 
 side of the mow until needed again next season. 
 This hay chute costs no more and is as easy to 
 build as any. A light ladder may be fastened 
 to one side of each section for entrance to the 
 mow. 
 
 A great many of these frames have been 
 erected, some in very windy and some in snowy 
 locations, since the plan was first presented in 
 The Breeder's Gazette and not one has given 
 .trouble to erect or in use, so far as I have learned. 
 Siding on this barn is better put on vertically. 
 If matched siding is desired it works as well 
 vertically as horizontally. The building may, 
 however, be studded and siding put on hori- 
 zontally. 
 
 In building the joist frame barn the following 
 directions may be of value: 
 
 Get one carpenter to superintend the job; three 
 or four men can find employment and the more 
 men the shorter the job. Pile up joists six or 
 eight high and square, mark and cut off with a 
 small crosscut saw; pile each sort out by itself 
 so you can get hold of it quickly and surely. 
 Never make splices without breaking joints and 
 use a block 2' long at the splice. Spike to- 
 gether well at splices and everywhere. Use 
 spikes 6" long and drive in a plenty; they are 
 cheap. Put bents together on the ground, 
 though you may finish spiking together after 
 raising, as spikes should be driven from each side. 
 Eaise the bents and brace up temporarily until 
 you have two standing, then put on box plate, 
 plumb very carefully, then put in long side 
 braces and one or two pieces of nail girts. That 
 will make the frame very rigid. You can now 
 continue to raise the bents one at a time and 
 continue putting on plates and braces as fast as 
 they are raised. • 
 
 It will take four men two days to frame a 
 barn 40' x 60' and if convenient they should have 
 
 four others to help raise, which will take another 
 day. After the frame is up as far as the square, 
 complete that part and put on the siding before 
 erecting the rafters. A scaffold at the level of 
 the plates is convenient, though some have 
 erected the rafters without it. If you wish to 
 change the proportions of timber used, do so, but 
 
 ii //v i a r^ 
 
 
 // \ 
 
 // \ I 
 
 
 
 --/ v 
 
 M \ \ 
 
 -,,,„, 
 
 LZ ~ .- -= 
 
 1 
 
 V \t 
 
 P \1 
 
 -„„ 
 
 
 / 
 
 [ 
 
 II iioi Van ■Jmrr/zra 7rfo3cftrs ft 
 
 
 fcr- - 
 
 i I 
 
 
 FIG. 3— WING'S JOIST FRAME. 
 
 make it heavier rather than lighter. A saving of 
 $10 in material might make you many times that 
 much trouble. The frame as it is saves a great 
 amount of timber. Frame together the rafters 
 and most thoroughly nail them- together before 
 raising. Discard any weak or uncertain sticks. 
 Use good inch boards 5' long. A trifle of expense 
 
 FRAME ROOF THIS FRAME ROOF THIS 
 
 WAV WHEN BUILDING IS WAY WHEN 36' WIDE 
 
 MORE THAN 36' WIDE AND UNDER 
 
 ONL INNER BENT 
 40' WIDE 
 IB' POSTS 
 8' CLEAR BASMT 
 27' " MOW 
 
 FIG. 4— WING'S JOIST FRAME. 
 
 here gives you a rigid roof. Tie together the 
 rafters with l"x4" sheeting across all the 
 angles before raising. Leave this sheeting on 
 until you must have it for laying on the roof. 
 Put two nails in sheeting instead of one at each 
 intersection of rafter. Eaise the first set of 
 rafters at the gable and very carefully stay them 
 
THE MODERN BABN. 
 
 19 
 
 and spike the bases to the plates. Begin raising 
 rafters in the morning so you can get them all 
 safe before night. Select good 2" x 6" long 
 stuff, run diagonal braces under the rafters from 
 the corners of the building clear to the center of 
 the roof, two spikes in each intersecting rafter. 
 This will make the roof very rigid. Get these 
 braces up as soon as three sets of rafters are 
 raised. If hay is to be taken in at the end, throw 
 out two sets of diverging rafters to hold the end 
 of the trade and shelter the hay door. Their 
 feet may be spiked against the outer long rafters 
 and their points thrown out, each pair 2'. 
 
 Brace the gable well. Hay doors should be 
 
 8' to 12' wide. They may be double and their 
 upper ends fold down to admit of swinging 
 under the roof. Turn these doors away from 
 direction of wind. Vertical siding is strongest 
 and best for this frame. Hoof projection should 
 be 2' at gables and generous at eaves. It is best 
 added at eaves by spiking on sides of rafters 
 short pieces of 2" x4", giving the same slope as 
 the top part of the roof. Shingle this clear up. 
 Do not attempt to bend the shingles. Use gal- 
 vanized shingle nails. Do not leave out any 
 braces. Put 2" blocks on stones under end of 
 posts. When they decay they can be replaced 
 and no injury to posts result. 
 
 GENERAL FARM BARNS. 
 
 The farm barn built by W. H. Dunwoody on 
 his farm in Minnesota is 120' long, 90' wide, 48' 
 high and cost complete $20,000. The basement 
 floor is cemented throughout and on it there is 
 a poultry house 10' x 25' with a glass front to 
 south, nesting boxes, with inclines, roosts and 
 runway to outside yard. There also is a storage 
 
 room 12' x 20' in the west end of the basement, 
 together with an old pump room and wash room 
 ] 0' x 25' ; west stairway to main floor ; three box- 
 stalls 12' x 17' for dairy cattle ; six stalls for dairy 
 cows; five horse stalls and two box-stalls 8' x 12' 
 for horses ; two rows of box-stalls 9' x 12' (six 
 stalls to the row) with alleys between; 12 
 
 FIG 5— A MINNESOTA FARM BARN (ELEVATION) 
 
20 
 
 FARM BUILDINGS. 
 
 double tie-up stalls 5' 8" long, mangers 26", 
 width of stall 8' 9", each stall being equipped 
 with iron enamel water bowl, with drop cover, 
 piped to water supply; drain trenches behind or 
 connected with all stalls, 18" wide by Sy 2 " deep; 
 large ventilating flues from basement to attic of 
 barn ; the height of the basement on north side of 
 barn is 4' above outside grade, giving large base- 
 ment windows for admission of fresh air; hand 
 extinguishers throughout barn and fire hose on 
 reels, connected to attic tanks; root boiler room 
 10' x 15', containing large root cooker; masonry 
 on all sides; steel roof; window for fuel; root 
 
 r 
 
 &<, X 
 
 >MJ.£ V'£ v" J-rj*it\j 
 
 QouS*. £ Y /f fy* $**n <& 
 
 Bo t J"r/t 
 
 £ 
 
 o&t*/ * m * 
 
 rtrr*,*j/*G iv**.*. 
 
 FIG. 6— MINNESOTA FARM BARN (GROUND FLOOR). 
 
 cellar 12' x 24', adjoining boiler room ; two silos 
 about 11' x 14' x 30', cement plastered; engine 
 room containing 15-horse power gasoline engine; 
 about 50' line shaft, with pulleys to grinder, con- 
 veyor, elevator, sheller and cutter on floor above, 
 and also connecting pump in pump room, and to 
 circular saw outside; east stairway to main floor; 
 artesian well pump room off engine room. 
 The passageways or alleys between rows of stalls 
 all lead to doors on south side of barn opening 
 into lower cattle yard, which is divided into east 
 and west halves' with sheds on farther side; yards 
 slope to south. (See Pig. 5.) 
 
 The main or first floor is described thus: 
 Machinery shed 18' x 60', containing farm 
 machinery, also separate tool room and work 
 shop. Driveway from east to west through barn 
 120' long; flooring 3" matched plank; 3' on cen- 
 ter floor timbers or joists under driveway, size 
 6" x 12" ; joists elsewhere same size but 6' on cen- 
 ters ; hay and straw bays on south side of drive- 
 way (hay carriers above the hay distributing 
 floor, above part of the driveway — this floor is 
 provided with trap doors and when bays are full 
 this floor can be filled its full length) ; grain and 
 feed bins on north side of driveway, connected to 
 
 
 
 § 
 
 t 
 
 
 
 *+ 
 
 «c* 
 
 m 
 
 fieeoMut. 
 
 T 
 
 ofirrJ /* ret 
 
 UPPfH Wo 
 
 Roar Of 
 Pump /footer 
 
 FIG. 7— MINNESOTA FARM BARN (SECOND FLOOR). 
 
 conveyor and elevator for handling the grain and 
 feed; feed grinder, cutter, sheller, grain cleaner 
 and elevator arranged next to bins on east end of 
 floor and over engine room; office or men's room 
 adjoining with heater, bed and wash-sink; stair- 
 way to second floor in east end. (See Pig. 6.) 
 
 The second floor is explained as follows: 
 Men's room with heater and, -furnishings; large 
 storage platform adjoining; stairs to top of silos, 
 elevator head and water tank's. In the attic there 
 are two water tanks holding about 350 gallons of 
 water. The scale and scale platform are outside 
 
GENEBAL FABM BABNS. 
 
 21 
 
 FIG. 8— LOVEJOY'S FARM BARN (ELEVATION) 
 
 of the barn on the driveway leading to the east 
 end of the barn. (See Fig. 7.) 
 
 LOVEJOY'S FARM BARN. 
 
 The general-purpose barn shown in Figs. 8, 10 
 and 11 was designed by Mt. A. J. Lovejoy and 
 built on his Riverside Farm in Winnebago Co., 
 111., in 1903. It is for horses and cattle, together 
 with machinery, wagons, manure spreader, car- 
 riages, buggies and sleighs. It also has bins for 
 5,000 bushels of small grain, mow room for hay, 
 shredded fodder, a large amount of straw and 
 large tank of water which supplies the barn and 
 adjoining yards. It is 96' x 64' and is built in a 
 first-class manner, having a joist frame made of 
 the best grade of hemlock lumber, with Wisconsin 
 white pine siding and 2" x 6" studding, on which 
 rosin paper is used and the whole sheathed with 
 best kiln-dried dressed yellow pine, making an 
 interior finish equal to many houses. The foun- 
 dation is made of concrete, from screened gravel 
 and Portland cement. Every post in the build- 
 ing rests on solid concrete piers set in the ground 
 3', on a 4' base. The entire floor is of concrete, 
 8" thick on a gravel fill of 15", and was made 
 with a good finish by an expert builder of con- 
 crete sidewalks. The approaches to each door 
 are also concrete and a concrete sidewalk extends 
 along the south side of the building to the door 
 of the engine room. The inside is divided into 
 suitable rooms, as shown in the plan. The engine 
 room is closed so as to exclude dust or dirt from 
 the mill room. A 12-horse power gasoline engine 
 furnishes power enough to run the grinder, feed 
 cutter, sheller, elevator and pump all at the same 
 time. There is a 28' elevator with a swinging ex- 
 tension that stands at the side of the driveway and 
 swings behind a wagon while standing on scales. 
 This elevator will elevate all kinds of grain to 
 the large bins above. These bins have hopper 
 bottoms with pipes leading to the mill room 
 
 below, direct to the grinder, fanning mill and for 
 loading wagons. The barn is lighted by acetylene 
 gas furnished from a plant which also lights the 
 residence and farm office. 
 
 The barn was made for convenience in han- 
 dling feed and preparing it for best results. No 
 hogs are kept in the barn, but all feed is prepared 
 in it except the steaming, which is done at the 
 feed house. All wagons are driven in the barn 
 and all hitching and unhitching done in it. 
 The total cost without any of the machinery, 
 engine and the "L" was about $5,000, which 
 includes painting. The 26' x 100' "L" was 
 
 .00.1 ELEVATION 
 
 FIG. 9— LOVEJOY'S FARM BARN (FRONT ELEVATION). 
 
 joined to the barn for a cattle shed and has 
 arched openings that can be closed by roller doors. 
 Where the diagram is marked "platform grain 
 dump" a set of scales was put in and an elevator 
 installed to carry grain to the granary upstairs. 
 The six large hopper-bottom grain bins are on 
 the second floor. (Fig. 11.) The bay for hay, 
 indicated in the illustration, was changed and 
 floored with cement, the same as all the rest of 
 the barn. The elevator does not require a dump, 
 as the hopper swings round behind the wagon 
 and grain is let out into it from the rear end of 
 the wagon. Plank floor is laid in the horse stalls 
 
22 
 
 FABM BUILDINGS. 
 
 FIG. 10— LOVEJOY'S FABM BARN (GROUND PLAN). 
 
 Jxl — tn?:L rTi 
 
 FIG. 1 1— LOVHJOY'S FARM BARN (SECOND FLOOR) . 
 
GENEBAL FABM BARNS. 
 
 23 
 
 on the cement, as it was thought that horses 
 would be less liable to slip. A drilled well is in 
 the stable with a 100-barrel tank above in the 
 second story. A system of water works from the 
 elevated tank in the barn furnishes a good supply 
 of water in the barn and out in the yards. 
 
 A better system of ventilation is used than the 
 one shown. All posts in the first story are boxed, 
 giving a finished appearance. The barn is almost 
 frost-proof and is very convenient and a comfort 
 to stock housed in it. The front elevation is 
 shown in Fig. 9. A photographic view of the 
 barn is presented in Fig. 8. 
 
 NEW TYPE OF CIRCULAR BARN. 
 
 The illustrations (Figs. 12 and 13) show a 
 circular barn designed by Archiiect Benton Steele 
 of Indiana and erected on a farm in that State. 
 
 
 H f -•^t* ■ 
 
 CBjJfe ^H 
 
 jj^yBHBi 
 
 k '-.'*.-- —«-,....:... . ..yF*'*','. _' 7" '■>■""'> ~S»»K 
 
 
 FIG. 12— NEW TYPE OF CIRCULAR BARN (ELEVATION), 
 
 The barn is 102' in diameter. The system of 
 construction might be termed- balloon framing, as 
 no heavy timbers are employed . in the barn 
 proper.' The system of framing is usually spoken 
 of as the bending system on account of the fact 
 that many of the important features of construc- 
 tion are obtained by bending the timbers into the 
 required shape instead of sawing. 
 
 This barn is designed to accommodate all -the 
 feed and stock that can be produced on a farm 
 of about 250 acres and yet allow for growth and 
 improvement for years to come. In this, ample 
 allowance is made for storing away implements 
 and machinery and for a battery of feed mills 
 and grinders, together with water tanks and 
 plenty of working space in every department. 
 The floor space shows stalls for cows. The 
 departments marked 1, 2, 3 and 4 (Fig. 13) can 
 be used separately or in part, or if need be can 
 be thrown into one continuous department as 
 
 occasions demand, such as when hauling out 
 manure or in' feeding numbers of stock together. 
 The double gates as shown are made and hung 
 in such a manner as to be easily removed, and 
 the walls are provided with a number of sets of 
 "eyes" so that the gates can be hung so as to 
 provide any size space desired. Every depart- 
 ment is directly accessible to the outside doors, 
 which is a great convenience in shifting stock 
 from place to place or in case of fire. The stock 
 is all fed the main rations from the one con- 
 tinuous feed alley, the feed being passed through 
 chutes or trap doors in the second floor. When 
 roughage is fed to loose stock it is passed through 
 chutes at the outer sides of the barn next to the 
 wall into racks as shown, which operate on the 
 plan of self-feeders. 
 
 The bins or cribs below are filled by gravity 
 from above. Portable corn bins may be used in 
 the second floor when needed. A solid concrete 
 wall is placed under the barn as well as the inner 
 rows where supporting timbers rest, and special 
 precautions were observed so as to exclude rats 
 entirely from ever finding a burrowing place. 
 
 The windmill is a power mill with a wheel 
 
 SBiBSUiliBiAil- 
 
 FIG. IS— NEW TYPE OF CIRCULAR BARN (GROUND PLAN). 
 
 1G' in diameter, and rests on a crib or tower in 
 the center of the barn. Several flights of stairs 
 are provided which furnish a means of access to 
 the cupola where one can look after the workings 
 of the windmill, or get a view of the surround- 
 ing country for many miles. The windmill sup- 
 plies power for running machinery and pumping 
 water, and being placed at such an altitude ren- 
 ders it very sensitive to the slightest breeze. 
 The second floor is entirelv free from obstruc- 
 
24 
 
 FABM BUILDINGS. 
 
 IB~J?ErWALif\ 
 
 Alley 
 
 7 tow SVaAls \ 
 
 '/Scales 
 
 BKICK FLOOR m 
 
 ?M 
 
 8 COVJ STA L,L3 1 
 
 &\SSAGE \ 
 
 Closet \ 
 
 X 
 
 Hay 
 Chuti 
 
 \6RAW 
 /> BOXES 
 
 7 FEED 
 
 Room 
 
 Alcev 
 
 T lOR 
 
 Harnis: 
 moM 
 
 Water 
 Trouo 
 
 i> 
 
 
 MAV6B& 
 1_ 
 
 M t^ (- 
 
 / 
 
 3? 
 
 TeedBo* C 
 
 &£ 
 
 V 
 
 < 
 
 ^ 
 
 H* 
 
 
 J 
 
 ALLEY 
 
 jiilEV 
 
 5 
 
 >v 
 
 / 
 
 'RETW/ILL J 1 w.c. 
 
 !j6 
 
 SHOWERBATH- ■ *X 
 
 
 ffAXNSSS 
 ROOM 
 
 Box- 
 
 Stalls 
 
 EORhfOR. ES 
 
 S\ 
 
 Slioiko Door's 
 
 ~& 
 
 -\ 
 
 Office 
 
 FOR 
 HERDSMEN 
 
 ye*' 
 
 *■«•■"" 
 
 
 ff-»- 
 
 -*-£ 
 
 ^- 
 
 V 
 
 -32 -O- 
 
 -/oo-o- 
 
 Covered 
 fig. 14— an experiment station barn (ground plan) 
 
 ARCHOR& 
 
 Second TIoor Plan 
 
 i VriveWay 
 
 i Brick 
 Pavement 
 
 Carriage 
 
 «^ Implement room 
 
 D 
 8 
 
 T=^ 
 
 /= 
 
 Seed room 
 
 I ffi55/R*a»l ny 
 
 Office 
 
 ■^BEDffoon i 
 
 T=T 
 
 ^ M ^ 
 
 ->E 
 
 FIG. 15— AN EXPERIMENT STATION BARN (SECOND FLOOR). 
 
GENERAL FARM BABNS. 
 
 25 
 
 tions with the exception of the crib and mills, 
 as before mentioned. The roof is entirely self- 
 supporting, no trusses being employed, nothing 
 heavier than 2" x 6" rafters. The mow floor has 
 an estimated hay capacity of 350 to 400 tons. 
 The haying outfit consists of a circular track sus- 
 pended about midway up> the span of the roof 
 and operates an ordinary swivel car or carrier, 
 in other ways much the same as in ordinary rec- 
 tangular barns with straight-away track. 
 
 AN EXPERIMENT STATION BARN. 
 
 The Iowa Experiment Station barn at Ames 
 is a very modern affair, roomy and well arranged. 
 It is a brick veneer, three stories high, 50' x 100'. 
 The first or ground floor is for stock, the second 
 for grain, implements, carriages and the like, 
 while the third is the hay mow. The silo is of 
 brick, has a 4" dead air space in the wall and is 
 18' in diameter by 28' deep, giving a capacity of 
 70 tons. The root cellar, which is under the 
 driveway, also has a hollow wall. In the horse 
 stalls a 3" false floor, with wide cracks to allow 
 urine to drain away quickly, is laid over the 
 cement, which is the flooring of the cattle stalls, 
 all passages being brick-paved. Over those parts 
 marked A, which are ceiled up 3', there is a wire 
 network 24" high. That in front of the horse 
 stalls is hinged so that all the feeding may be 
 done from the alley. The box-stalls for horses 
 are sided up 5' with 2" stuff and iron rods run 
 the rest of the way to the ceiling. (See Figs. 
 14 and 15.) 
 
 In the feed-room the hay and straw are brought 
 from the third floor in chutes with doors at the 
 bottom. The grain is also brought down in small 
 chutes with cut-offs, so that all the mixing of 
 feeds may be done on the first floor. A hot water 
 stove in the herdsman's office heats the bathroom 
 and the teamsters' rooms above on the second 
 
 floor and also the seed-corn room. The 18" 
 retaining walls on the southwest corner and north 
 side show the difference in the elevation, the 
 ground on the west being higher than that on the 
 east of these walls. On the second floor are the 
 bedrooms and office of attendants. In the corn- 
 room there are racks all around so the seed corn 
 can be ricked or corded, up in them, giving better 
 ventilation and economizing space. 
 
 The driveway is covered and is roughly paved 
 to give horses a foothold in drawing loads over 
 it. A continuous chute from top of silo permits 
 silage to be thrown from either of the three doors 
 to the feeding floor. The motor-room just off 
 the blanket-room is for a 15-horse power electric 
 motor. A line shaft from here into the feed 
 grinding room allows for belting to feed cutters 
 and other machinery. All the feed-bins have 
 sloping bottoms to facilitate the passage of grain 
 through the chutes to the mixing-room.' Venti- 
 lator courses from the ground floor to the outlets 
 on top give ample ventilation. A stand pipe and 
 fire hose on reels afford partial protection from 
 fire within, while larger hydrants outside have 
 been placed near the building. 
 
 A STOCK AND HAY BARN. 
 
 The illustrations (Figs. 16, 17 and 18) are of 
 one of the most commodious and best arranged 
 stock and hay barns in the West. The building 
 in the main stands 132' east and west by 112' 
 north and south and the wings are 32' wide. The 
 details of the basement are very fully shown (Fig. 
 18) and the conveniences of such an arrange- 
 ment are obvious. In the basement and imme- 
 diately under the wagon floor there are located 
 three bins for grain or ground feed and roots. 
 They are filled through trap-doors from above, 
 the sheller, or grinder, or root-cutter, or corn- 
 crusher being placed over the traps and the power 
 
 FIO 16— A STOCK AND HAY BABN (FRONT ELEVATION). 
 
2fi 
 
 FARM BUILDINGS. 
 
 BTG. 17— A STOCK AND HAY BARN (REAR ELEVATION). 
 
 i r 
 
 1 r 
 
 TJZC i JZE L 
 
 CeltBox. 
 
 I 0ra/h 
 
 1 r 
 
 ^Ji—r 
 
 X, 
 
 o 
 
 Root Cellar. 
 
 
 ffCC 
 
 ^. 
 
 
 /■ 
 
 -WaterTan/c 
 
 jxa 
 
 nn 
 
 
 TT 
 
 J5ca/f 
 
 J26 ineA - / feat, ftia/tf* meaau/vm*&3. 
 
 Softer 
 
 r^ 
 
 i r 
 
 1 r 
 
 Deer 
 
 2) rive Why 
 
 it 
 
 J)nve Way 
 
 
 
 
 
 
 
 Si* 
 
 
 l 
 
 J J 
 
 
 llj 
 
 J__ 1 
 
 iwsJL 
 
 Jl 
 
 
 
 
 
 
 
 
 
 
 ^ 
 
 k 
 
 H' 
 
 
 mmzm 
 
 m 
 
 JSul/yartt 
 
 Cfitt. 
 
 -Ztorife&tdv 
 
 
 I ^u?/yarct i 
 
 FIG. 18— A STOCK AND HAT BARN (BASEMENT PLAN). 
 
 ^Z»«W 
 
 ca 
 
 furnished by the belt from the three-horse tread calf boxes that will conveniently accommodate 
 power shown in the ground plan of second floor, about twenty youngsters each, and the balance 
 Immediately adjoining the feed-rooms are two of the floor is devoted to double stalls 7' deep 
 
GENERAL FARM BARNS. 
 
 27 
 
 except as otherwise indicated on the diagram. 
 The water tank is in the center of the barn and 
 large gates expedite the handling of the cattle 
 back and forth from the tank to the stalls, or 
 to the yards if they 1 are turned out. There are 
 good-sized box-stalls for the service bulls, with 
 
 direction and the manure loaded onto a wagon 
 or spreader and carted to the fields. This base- 
 ment is surrounded by a stone wall and is very 
 warm, though amply lighted and ventilated by 
 numerous windows and doors. The water is 
 piped underground to the trough from well and 
 
 r 1 
 
 
 
 
 ••-•" 1 
 
 k. .. A 
 
 i 
 
 :z 
 
 = 
 
 \ 
 
 
 ■=, 
 
 r ■* 
 
 HUB 
 
 ' ' 
 
 
 ■ _ ,. . 
 
 - -4 
 
 
 
 
 
 . A 
 
 
 
 
 
 
 
 
 aXNM 
 
 
 
 1*011 
 
 
 
 
 
 
 i 
 
 
 
 
 
 " ^~ 
 
 "™ ' 
 
 \ 
 
 
 D 
 
 HAftTCHS CATTLC tAt 
 
 
 
 
 \ 
 
 
 
 
 
 
 
 
 
 
 5 | 
 
 
 .• 
 
 
 5* 
 
 
 „ 9 
 
 
 j « ■ 
 
 
 i 
 
 
 ► "™ " 
 
 
 
 
 
 
 
 
 a ™ ■ ■ 
 
 
 
 
 
 
 
 
 
 
 
 
 FIG. 19— AN INDIANA FARM BARN. 
 
 an exercising yard opening out from each, and 
 in the south wing there are four box-stalls for 
 cows calving in cold weather or for any other use 
 desired. The driveways are 12' wide, so that a 
 team can be driven through the barn from either 
 
 F" 
 
 Mil* 
 
 i 
 
 
 
 
 
 
 
 
 
 
 k_ 
 
 ^ 
 
 >< 
 
 
 
 MOW 
 
 r- 
 
 , 
 
 
 ■ ILO 
 
 
 
 
 mil 
 
 
 
 IIMII 
 
 1 
 
 V 
 
 
 
 
 
 
 
 9NIVC MOO". 
 
 
 h_ 
 
 4 
 
 
 
 
 illinium*™ 
 
 
 
 
 
 3CC0H0 rLOOIl 
 
 
 s 
 
 
 
 
 FIG. 20— AN INDIANA FARM BARN. 
 
 windmill outside and is controlled by a float- 
 valve or by a cut-off rod, as desired. 
 
 On the second or main floor there are grain 
 bins and corn cribs, 8' x 24' and 14' high, and 
 office and store-room, each 14' x 16' ; a space 
 
 FIG. 20a— CATTLE AND HORSE BARN AT WHITEHALL (FRONT ELEVATION). 
 
28 
 
 FARM BUILDINGS. 
 
 C At I/O IKON HOOO 
 
 FIG. 20b— CATTLE AND HORSE BARN AT WHITEHALL (CONSTRUCTION). 
 
 „CATTL, 
 
 I ¥_J 1 
 
 FEED RACK BELOW H HAYRACK QFCCP 
 
 RACKBELQW g 1 
 
 HAYRACK 
 
 HAY |3HUT(: ALLEY 
 
 L J 
 
 >VjTACK TlffEDgACK BELOW 1~1 HAYRACK □ FtEPRACJT 
 
 X 1 JorATTi^t '5'^' II 15^ 
 
 FEEPRACK BELOW 1" 
 
 "CATTLE" 
 
 DftAtrO 
 
 DRAIN 
 
 
 •„CATTLE 
 
 f 
 
 HAVRACK 
 
 H FEEDRACK BELOW 
 
 3 HAYRACK 
 
 ALLEY H^Y CjHUTE 
 ' ' 
 
 I5i>" 
 
 -X l5lB 
 
 CATTLE" 
 
 U. -.-■.I5'0 ■ 
 
 natM 
 
 120 FEET 
 FIG. 20c— CATTLE AND HORSE BARN AT WHITEHALL (GROUND FLOOR). 
 
GENERAL FARM BARNS. 
 
 29 
 
 reserved for feed-cutter and for hay-rake and 
 hay-loader and yet additional room in the three 
 mows for 200 tons of hay. The capacity for 
 grain, including both floors, is from 7,000 to 
 8,000 bushels. The barn will accommodate 125 
 head of cattle, including from 25 to 30 calves. 
 The building is very substantially constructed 
 and with due regard to general symmetry and 
 effect. As it stands it is a very attractive build- 
 ing, well painted and trimmed and cost about 
 $4,000. 
 
 AN INDIANA FARM BAEN. 
 
 Fig. 19 shows the ground plan of a barn in 
 which cattle and calves may be fed, 20 cows kept 
 (in Van Norman stalls) and "baby beef" pro- 
 duced. It is also provided with stalls for horses. 
 The diagram shows how the ground floor is 
 
 basement are of sound native whiteoak. The 
 8" x 12" beams in the drives on the outside are 
 also of whiteoak. All bill stuff and timbers above 
 the basement are first quality longleaf Southern 
 pine; 6" x 10" middle tie beams are set back 4" 
 from face of posts to allow studding, which is 
 2"x4", to pass without cutting. The floor of 
 two outside drives is made of 2" x 12" oak alter- 
 nating with 2" x 3" oak pieces set on edge, all 
 laid on 8" x 12" whiteoak stringers. The entire 
 first floor is floored with iy 2 " dressed and 
 matched yellow pine flooring and the driveways 
 on the first floor have an upper floor of 1" 
 dressed and matched oak. The entire basement 
 is ceiled all around the stalls, passages and alley- 
 ways 4' high with 1" dressed and matched yel- 
 low pine. The stable doors are built in two 
 pieces, upper half 3' and the lower half 4' hi h. 
 
 TIG. 80d— CATTLE AND HORSE BARN AT WHITEHALL (END ELEVATION). 
 
 divided. Fig. 20 shows the arrangement of the 
 second floor. This barn has a cement floor 
 throughout and is conveniently arranged for the 
 uses to which it is put. Two silos are shown in 
 one corner, and the corn silage stored in them 
 is very successfully used in the making of "baby 
 beef." 
 
 CATTLE AND HORSE BAEN AT WHITE- 
 HALL. 
 
 Figs. 20a, 20b, 20c, 20d and 20e show the 
 elevation, floor and other plans of the beef cattle 
 and horse barn which E. S. Kelly recently built 
 on his Whitehall farm in Ohio. Fig. 20c shows 
 the ground floor on which there . are stalls for 
 cattle and horses. All the stone work is of good 
 native limestone, laid up in good lime and sand 
 mortar. The retaining walls around the drives 
 have half cement and half lime in the mortar. 
 All the bill stuff and dimension lumber in the 
 
 The roof of the Whitehall barn and ventilators 
 are covered with the best quality 16" cedar or 
 cypress shingles. The entire barn is framed to 
 secure the greatest strength and permanency of 
 shape with the least weakening of timbers. The 
 windows in the basement are arranged to slide 
 sideways, as directed. The entire outside of the 
 barn is covered with 4" 'drop siding. The cattle 
 floors are made of cement. The barn cost about 
 $7,000. 
 
 A WISCONSIN FAEM BAEN. 
 
 J. W. Martin's Wisconsin barn shown in Figs. 
 21, 22 and 23 has a stone wall foundation 20" 
 high; the first story 8' is double-boarded with 
 paper between and shiplap floor above. Fig. 22 
 shows the arrangement of the interior and Fig. 
 23 the plan of construction. The approaches to 
 the main driveway and end doors are paved with 
 cement. Box-stalls occupy the entire first floor 
 
30 
 
 FARM BUILDINGS. 
 
 of the barn, and one stall is cemented for a rest- 
 less bull. 
 
 The cow barn (Fig. 21) is 30' x 80' with Bid- 
 well stalls and a driveway between the rows of 
 cow stalls on through the middle. This barn 
 would be more convenient if it were 34' wide. 
 
 A KENTUCKY FARM BARN. 
 
 The general description and plan (Figs. 24, 
 25 and 26) herewith given are of a Kentucky 
 
 barn built a decade ago. It is a, bank barn an- 
 stands on high ground where natural drainage it 
 good. The size is 62' x 74', and from basement 
 floor to the 1 wind-engine tower the height is 56', 
 divided into four stories. The basement wall is 
 of limestone, 22" wide and 8' high, and the posts 
 in the basement supporting the frame work are 
 twentv in number and are of oak, 12" x 12". The 
 parts of the frame are 10" x 10", 16' high. The 
 entire framework is of oak, the shingles of poplar 
 
 FIRST FLOOR PIAN 
 
 TIG. We— CATTLE AND HORSE BABN AT WHITEHALL. 
 
GENEBAL FABM BABNS. 
 
 31 
 
 and the siding of Northern pine. There were 
 used in the structure 100,000 feet of lumber and 
 50,000 shingles, and the total cost was about 
 
 with a cross aisle and forty box- 
 stalls for grown animals, and the cross 
 or calf aisle will accommodate fifty calves. 
 The feed descends through a chute from 
 the third story and two cars await to carry it 
 
 FIG. 22— A WISCONSIN FARM BARN (GROUND PLAN) 
 
 $3,900. The diagrams of basement and main 
 floor (Figs. 25 and 26) are quite complete and 
 need but little explanation. There are two feed 
 
 FIG. 24— A KENTUCKY FARM BARN (ELEVATION). 
 
 The floor of this story is double, with pitched 
 felt between, which protects the animals below 
 from the ones above. This floor is inclined each 
 way from the center sufficiently to cause proper 
 drainage. The entrance to this story is through 
 double doors, 14' high (Fig. 24), via an elevated 
 
32 
 
 FABM BUILDINGS. 
 
 macadamized drive extending outward from each, out at the opposite door. A gigantic hay-lift 
 
 . Scales are placed at one door, so that the grain reaches down from above, takes up a load of hay 
 
 is weighed by the wagon load as it is taken from and puts it in any desired part of the third and 
 
 the barn. The wagon passes along the aisle and 
 
 
 
 Enst 
 
 
 
 
 ■ 
 
 
 
 
 D Bull Suit 
 
 HtQ 
 
 Ho 4 so 
 
 &Mng9UU CalvkigStali CaMogSUll 
 1 16kM ' ' 1G-JM ' ' ifi'M 
 
 
 
 
 
 
 
 
 Corn Crfb 
 W'18, 
 
 Water. 
 
 
 
 
 J 
 
 ! HsjCbuic I 
 
 w aid Slnir* |o| 
 | BlaCUlCOt | j 
 
 8-14 
 
 6 Ton 
 
 Fall bi ii kj Seal* 
 
 vx 
 
 ^■° ' ^3 
 
 names* 
 Tovl Stop 
 
 FIG. 25— A KENTUCKY FABM BARN (MAIN FLOOB PLAN). 
 
 If- —».'-- —»l 
 
 FIG. 26— A KENTUCKY FARM BABN (BASEMENT PLAN). 
 
 — xt 
 
 BOX 
 
 24X18 
 
 FEED 
 12X14 
 
 BOX 
 
 12X14 
 
 RttRD 
 
 BOX 
 
 12X14 
 
 RD 
 
 7H0RSE STALLS 
 
 D 
 
 BOX . 
 
 24X28 
 
 84 
 
 
 o 
 
 it 
 
 
 
 
 IO*J \j 
 
 / iox 
 
 / \ 
 
 14 
 
 14 
 
 14 
 
 49. 
 
 FIG. 27— AN OHIO FABM BABN. 
 
GENERAL FARM BARNS. 
 
 33 
 
 fourth stories or hay loft, which loft has a 
 capacity of 500 bales. The second story has 
 fourteen calving stalls, as shown in diagram, 
 which are so arranged that they can readily be 
 converted in case of necessity into four stalls 
 each, making room for 56 cows. In the center or 
 main aisle, 12' wide, there is room for 50 calves.' 
 This gives the barn a capacity of 196 animals, 
 all sizes. There also is an office on the second 
 
 E*R.m bank. 
 
 • •.-• ■•-.-: rr •■•:•■. ~ ;•• . * a'sffSfZ'/fxi' 
 
 i 
 
 j^cissyoMsJj; 
 
 <k 
 
 tirle. 
 
 
 F£E(> ALLS* 
 
 
 "I 
 
 
 lH*fl6CK 
 
 
 <3 
 lu 
 
 
 
 
 
 
 iutt 
 
 It,. 
 
 
 
 Joaa 
 
 DOOfL 
 
 FIG. 88— A BANK BARN (GROUND PLAN). 
 
 floor. Just outside the building a cistern which 
 holds 500 barrels furnishes the water for the 
 entire building through a system of pipes. The 
 third story contains the bran bin, corn boxes and 
 cut-feed room, also the large cutting-box, the 
 corn sheller and the pumping machinery, which 
 are driven by wind power. So complete is the 
 arrangement in every particular that one good 
 man can easily feed, water and care for the stock 
 and keep the barn in order. 
 
 AN OHIO FARM BARN. 
 
 The Ohio farm barn shown in Pig. 27 is 
 42' x 84', 24' to square, with curb roof and pur- 
 lin posts. The rafters are 20' and 12', cut so 
 each covers one-fourth the width of the building; 
 all frame is of plank sided with drop siding, put 
 on up and down. The barn is built on a stone 
 •foundation and is covered with slate, single lap 
 on steep deck and double lap on upper deck. The 
 hay door is 8' wide from the mow floor to the 
 comb; hood 4' wide on each side. The lower 
 story is 8' in the clear, mow 14' to square, 30' 
 to purlin plates. The plank frame is a great 
 improvement, certainly in cheapness and 
 strength. 
 
 A BANK BARN. 
 
 In many locations bank barns may be cheaply 
 constructed. The plan submitted is for a bank 
 barn that will hold twenty-five tons of hay, have 
 
 room in the basement for eight horses and about 
 twenty head of cattle, with room above for about 
 1,000 bushels of corn and 800 bushels of small 
 
 ;grain. In addition space is allotted on this floor 
 
 .for implements, wagon and buggy. 
 
 The basement plan is merely meant to be sug- 
 gestive. Cattle may be turned loose, as sheep 
 would be. The feed alleys should be formed by 
 the mangers, these to be movable so that they 
 can be taken out for cleaning. Fig 29 (first 
 floor) shows a driveway, two corncribs and an 
 oats and wheat bin. These could be decked over 
 and hay put above -except the part under the 
 driveway directly under the comb of the roof. 
 Hay is to be thrown down in chutes about 3)4' 
 square, reaching to the feed alleys, and a hole 
 may be left open in the driveway covered by a 
 trap-door. If this barn was built of joist frame 
 and most of the framing stuff secured on the 
 farm and if the farmer himself is at all dexterous 
 iu the use of a saw and hammer the cost may be 
 within $400. The size of the ground plan is 
 36' x 48' (Fig. 28). 
 
 A BASEMENT BARN AND CARRIAGE 
 HOUSE. 
 
 The barn and carriage house shown in Figs. 
 30, 31 and 32 will accommodate three horses and 
 three cows. The second story is used > for hay 
 and is 24' x 30', with a height of about 10'. The 
 basement is 8' in the clear, 24' x 30', has two 
 windows on the north and two on the south, 
 
 
 
 
 ,/Y\. 
 
 
 
 a 
 
 •V 
 S 
 
 3 
 
 8 
 
 Hoof « 
 
 ! 
 
 i 
 
 t 
 
 i 
 
 , ■ 
 
 v ? 
 
 1 
 
 ■ 
 
 
 \ 
 
 O 
 
 I 1 
 
 £ 
 
 
 
 o 
 
 O 
 
 
 <o 
 
 c 
 
 2; 
 
 1 J 
 
 
 ^ 
 
 
 
 
 \ 
 
 
 
 
 i» 
 
 
 M 
 
 
 
 
 ^ " 
 
 
 *> 
 
 
 
 
 
 
 s 
 
 
 
 
 
 
 £ 
 
 
 
 
 
 
 al 
 
 
 
 
 
 
 ■«. 
 
 
 
 
 
 a i 
 
 1 ~ 
 
 rs 
 
 " 
 
 « 
 
 p 
 
 PIG. 29— A BANK BARN (FIRST FLOOR PLAN). 
 
 hinged at the top and when opened swing upward 
 and are caught by a wooden latch. On the east 
 there is a window 2' x 3', lighting the feed-room 
 between the horses and cows. The wall is range- 
 work stone on three sides and the east side is 
 framed and weather-boarded. The entire floor is 
 pavedwith boulders and tile-drained under the 
 walls, 'so the basement is dry, well lighted, cool 
 in summer and warm in winter. The ventilation 
 
34 
 
 IBM BUILDINGS. 
 
 WIG. 30— A BASEMENT BARN AND CARRIAGE HOUSE (ELEVATION) 
 
 Cor/i 
 
 2^' 
 
 Mi/SJF'eed 
 
 Oate 
 
 % 
 
 Cows 
 
 a'x/4-' 
 
 Sta/rch/o/iS 
 
 /3'x r' 
 
 /0 'X/4 ' 
 
 //owe t>f&6/e 
 
 * 
 
 FIG. 31— A EASEMENT BARN AND CARRIAGE HOUSE (BASE- 
 MENT PLAN). 
 
 V 
 
 \ 
 
 r 
 
 24-' 
 
 24-'X/2'6' 
 
 /V 
 
 /Y 
 
 /V 
 
 Carr/agTes 
 
 24 'X V2' 
 
 v, 
 ^ 
 
 FIG. 32— A BASEMENT BARN AND CARRIAGE HOUSE (MAIN 
 ELOOR PLAN) 
 
GENERAL FARM BARNS. 
 
 35 
 
 is complete by opening^Indows on three sides, 
 in warm weather and the transom over the 
 entrance at head of stairway. In the winter 
 warm air passes up a ventilating shaft to the 
 ventilator on top of the roof. The granary is set 
 up from the floor one foot and out from walls 
 a foot, so it is dry and rat-proof. It and the 
 bedding-room occupy the back part of the base- 
 ment, leaving the front part nearest the light and 
 Sunshine for the horse and cow stalls. The horse 
 stalls are 4' 6" x 12'. The partitions of 1" oak 
 are set into the posts, so there are no nails or 
 bolts to injure horses. 
 
 The hay raxsks are perpendicular, with rounds 
 3' long set 4 apart. The back of the racks is 
 boarded tight, sloping, leaving a space of 6" for 
 hay at the bottom and 18" at the top, being 
 filled from the trap-doors in the hallway on first 
 floor. The stall on the east side is 1' wider than 
 the other two to make more room for passing 
 from the feed way into the stable. The bed- 
 ding-room opens into the stable behind the 
 horses and is filled from trap-door at the right of 
 carriage entrance on first floor. The granary is 
 divided for corn, oats and mill feed and a drop 
 door at the bottom of each, so feed is removed 
 and the doors always closed to keep out rats. 
 
 The cow stable is fitted with stanchions and a 
 drop 6" deep and 4' 6" back. The litter from 
 horse stalls is pressed into the drop to absorb 
 the moisture from cows and in front of the cow 
 stable stands a low-down manure truck, which is 
 removed to the meadows or fields when filled. 
 At the head of the feed-room is a water faucet 
 connecting with a cistern on the bank to which 
 the water from the roof is piped. There is also 
 a trough of spring water in the barn lot. 
 
 The front elevation is shown in Fig. 30. The 
 double doors to the right open into the carriage- 
 room. The double doors on the left open into 
 the shop, which is fitted up with bench, vise, tool- 
 cases, and so on, and lighted by two windows 
 opposite the doors. The central door enters the 
 hall to the hay-mow and the stairway into the 
 basement. Into it hay falls from the mow at the 
 far end and is put into the racks through trap- 
 doors that fall back against the partition. In 
 warm weather these trap-doors are kept open. 
 In cold weather they are closed down. 
 
 The plan of first floor, as well as that of the 
 basement, is drawn to a scale of one-eighth inch 
 to the foot. (See Figs. 31 and 33.) 
 
 A — Double door 8' x 8' 9" to carriage-room ; B 
 —Single door 6' x 3' 3" and transom 3' 3" by 
 14" • c — Double door T x 8' to shop ;D — (Hallway 
 5' 6" by 24' ; E — Trap-door for bedding below; F 
 — Trap-door for feed to granary below; 6 — 
 Stairway to basement ; I — Ladder to hay-mow ; J 
 —Entrance to cow stable ; K — Entrance to horse 
 
 stable; L — Water faucet; N — Trap-doors to hay- 
 racks below. 
 
 The building is covered with best pine shin- 
 gles, weather-boarded with dressed lumber, bat- 
 tened and painted. The corner posts are 14' 
 6" x 6". The floors to shop and carriage-room 
 are 1*4" sycamore and the floor to hay-mow is 
 tongued and grooved pine flooring with no knot- 
 holes. 
 
 A KENTUCKY STOCK BARN. 
 
 The drawings (Figs. 33 and 34) are of a Ken- 
 tucky stock barn 20' wide surrounding a feed- 
 
 FIQ. 33— A KENTUCKY STOCK BARN (MOW PLAN). 
 
 JTG. 34— A KENTUCKY STOCK BARN (CROUP PLAN). 
 
 lot 100' in diameter. The feed-shed with trough 
 and rack next to wall has the south side open to 
 
36 
 
 FABM BUILDINGS. 
 
 the feed-lot. The barn has a sheep department, 
 hay-rack next to the outside wall and small stalls 
 for ewes and young lambs. It also is provided 
 with stalls for milch cows and calves, boxes for 
 bran and crushed corn and box-stalls for horses; 
 there is an 8' unboxed passage outside and a loft 
 over all except the scales and gateway, which are 
 open for hoisting hay with fork on an endless 
 track. In this loft there is room to store shredded 
 corn and different kinds of hay. A crib . should 
 be made separate and rat-proof. 
 
 A SMALL STOCK BARN. 
 
 The barn shown in Figs. 35 and 36 is designed 
 to hold 50 tons of hay, to have six horse stalls, 
 6' wide, three cow stalls, two box-stalls and a 
 
 
 
 vr 
 
 
 vr 
 
 J> 
 
 w 
 
 j> 
 
 
 
 Mr 
 
 S* 
 
 IIS 
 
 
 J L 
 
 lVf.11. 
 
 SIM. li-t-U- 
 
 
 
 
 
 i r 
 
 \ M«.Mf m r 
 
 P. 
 
 "* fcKAjtfjttft' 
 
 
 
 
 
 \ 
 
 J 
 
 i 
 
 J U L 
 
 •4 
 
 1 
 
 t 
 
 
 Shins 
 
 r 
 
 (.' 
 
 r 
 
 n . r 
 
 FIG. 35— A SMALL STOCK BARN (GROUND PLAN). 
 
 FIG. 36— A SMALL STOCK BARN (END ELEVATION) . 
 
 cattle shed. The barn is 36' x 60', with 20' posts, 
 a central feed alley and arrangement of stalls and 
 open shed-room as shown. This affords a con- 
 venient and economical disposition of material 
 and space. There is room for more than 50 tons 
 
 of hay. The barn is of joist construction 
 throughout with open center and self-supporting 
 roof. 
 
 It is an easy matter to put the self-supporting 
 rafters together on the ground. They are then 
 lifted in one piece, being stayed across the angles 
 with 1" x 4" shingle laths. This avoids all neces- 
 sity of scaffold from plate to plate. Hay, accord- 
 ing to the design, is taken in at the end, thus 
 saving the space usually lost in a driveway. 
 Tools, wagons and buggies are best kept in a 
 separate building. 
 
 A JOIST FRAME HAY BARN. 
 
 This barn is intended to shelter hay and' grain 
 until threshing time, after which it may be used 
 in the winter for sheltering , cattle: There is no 
 
 FIG. 37— A JOIST FRAME HAT BARN (CONSTRUCTION). 
 
 FIG. 38-A JOIST FRAME HAY BARN (DETAILS OF FRAME). 
 
 basement to the building and sills and cross-ties 
 are not used. 
 
 Make a cross-tie of the ground and anchor each 
 side of the building firmly to large stones on 
 which the purlin posts would set. Fig. 37 shows 
 how this is accomplished. The %" bolt\ goes 
 down through the foundation stones, the lower 
 one of which is the larger, and fastens firmly to 
 the foot of the post. This makes the building 
 as solid as the ordinary frame. , 
 
 Fig. 38 shows details of the frame viewed from 
 
GENERAL FABM BABNS. 
 
 37 
 
 the side. A A are ends of the tie shown in Fig. 
 37. At the lower piece of plate is shown cut 
 away to show the block, 2" x 8", 3' long, that 
 rests on top of the post and on which the plate 
 splices, as at 8 S. B B are blocks put in to fill 
 the post where the braces come against it. Nail- 
 
 SHEO I6XS3 
 
 MAN PER f l/ff FEEDING CATTLEIN SHED 
 
 — a „ 
 
 HOXSESTALL 
 9 FT WIDE 
 
 OOUBLE 
 HORSESTALL 
 
 feed alley & ft wide 
 
 6 ATE 
 
 COIV 
 
 •s taOls 
 
 OOCaLE 
 
 HORSE 
 3 FT. 
 
 STALLS 
 
 WIDE 
 
 DRIVE WAY 
 
 T 
 
 com 
 
 DOOR 
 
 ILLS 
 
 FEED ALLEY 
 
 PIG. 40— PLAN FOR A SMALL BARN. 
 
 girts are 2" x 8" spiked on 4' apart, not shown 
 in the cut. The tie T splices at S. This tie is 
 double, breaking the joints. Posts are of two 
 pieces 2" x 10". 
 
 The frame is put together with y 2 " carriage 
 bolts and 40-penny spikes. The track for the 
 carrier runs under the peak and the draughts 
 are run in as soon as they clear the level of the 
 hay in the mow. Slings also carry in bound 
 grain. 
 
 PLAN FOE A SMALL BAEN. 
 
 Fig. 40 shows a barn with four double horse 
 stalls, one box-stall and room for 30 cows and 
 20 other cattle. It is seldom satisfactory to 
 
 combine a horse and cow bam, as the latter can 
 be more economically built by making it only 30' 
 wide, but this does not suit so well for the horse 
 stalls. If 1 one could dispense with the driveway 
 it would be better to cut off as much as needed 
 for the horse stable and place the stalls across 
 the building with entry from the outside to each 
 double stall. The oats bin should be placed over- 
 head, so that oats can be drawn down through a 
 spout near the horse stalls. This barn with high 
 curb roof will hold about 60 tons of hay. 
 
 GOOD TYPE OF FABM BAEN. 
 
 The plan illustrated in Fig. 39 shows a cattle 
 barn which is 96' x 48'. It is a pole barn with 
 posts 20' high and a corncrib 80' x 12' runs 
 through the center of the barn ; the lower boards 
 
 TIG. 39— GOOD TYPE OP FARM BARN (BLBVATION). 
 
 of the crib are hinged and feed boxes built on 
 level with the crib bottom so as to make prac- 
 tically a selfrfeeder, especially when feeding 
 shelled corn. Hay-racks on the sides are 80' 
 long. Hay is put in at the ends of the barn. 
 Sliding doors, controlled by weights, are used at 
 
 K 
 
 l r 
 
 1 /x 
 
 % 
 
 
 o 
 
 SL.IQIN6 DOORS 
 
 GRANARIES ON 
 THIS PART 
 
 DRIVE WAY 
 I6'x«*0' 
 la'HlGM 
 
 GRANARIES ON 
 THIS PART 
 
 MOW CLEAR TO GROUND 
 32' X «+o' 
 
 Sliding doors 
 
 FIG. 41— BAEN FOB SMALL FABM. 
 
38 
 
 FARM BUILDINGS. 
 
 the ends of the mow. They are closed when the 
 hay is in the mow. There are doors alongside 
 of the hay mow. When filling the mow a space 
 of 4' between the hay and the sides df the barn 
 may be left so that hay may be thrown into the 
 racks when feeding. The south end is open ; the 
 north end has doors which are closed in bad 
 weather. This barn will easily accommodate 100 
 cattle. 
 
 BARN FOE SMALL FARM. 
 
 A transverse driveway in a barn is rather a 
 waste of space, as. it usually shelters only the 
 farm wagon, yet it is often desired and in this 
 plan (Fig. 41) it is made to do duty as a feed 
 alley. There are stalls for four horses and five 
 cows and a large mow reaching to the 
 ground and granaries over the drive on each 
 side, where they are readily filled by hoisting the 
 grain with a hay-carrier rope. Where roofs are 
 40' wide or more there should be the truss method 
 of framing rafters, using 2" x 4" brace beneath 
 the angle, fastened by short pieces of 1" x 4". 
 This truss must be on both sides of the roof; it 
 is shown on one side only in the diagram. 
 
 BARN FOR HORSES AND RANGE 
 CATTLE. 
 
 This barn (Figs. 46 and 47) was erected in 
 Wyoming to shelter pure-bred and range cattle 
 
 f ]i ii 1 1 1 1 1 1 1 1 i i iHs?Mls>Si 1 1 1 1 1 m'fi 1 1 I'll f i f ' 1 1 
 
 I It H EQO 1 1 1 1 1 KajEtSSssl '** w 1 1 1 li IXQJ rtTii 
 
 PIG. 46— BABN FOR HORSES AND RANGE CATTLE (SIDE 
 ELEVATION). 
 
 and horses. The long shed is open on one side 
 next the yard and forms a good windbreak. The 
 end of this shed is shown to right of cut of the 
 
 ~IL_ 
 
 II III •- 
 
 /*' 
 
 
 : ... -1 
 
 i 
 
 "H 
 
 3 s 
 
 i 
 
 i 
 
 ' 
 
 tttttte; 
 
 elevation instead of the left where it should 
 be located. The framing is of joist construe- 
 
 13.:.' 
 
 TIG. 42— A BABN Or BOUND POLES. 
 
 tion, as illustrated elsewhere ; hay is taken in at 
 the end of the shed and from the driveway of the 
 main barn. 
 
 A BARN OF ROUND POLES. 
 
 There is no cheaper construction where round 
 poles are at hand than that shown in Fig. 42. 
 
 FIG. 43— THE GLIDE UMBBBLLA BABN (END VIEW). 
 
 
 UMBRELLA WHERE CATTLE 
 
 
 
 
 EAT FROM THIS MANQER 
 
 
 
 
 HAY MOW 
 
 
 
 
 
 
 UMBRELLA OVER THIS 
 
 
 FIG. 47— BARN FOB HORSES AND BANGE CATTLE (PLAN). 
 
 FIG. 44— THE GLIDE UMBRELLA BABN (PLAN). 
 
 The poles may be set directly in the ground, 
 though it is better to imbed them in cement, put- 
 ting down %" in the bottom of the hole and ram- 
 ring 3" or 4" more around the sides. This 
 excludes water and adds to the durability of the 
 pole, which, when decayed at the bottom, may 
 be sawed off and filled under with cement or 
 stone. Built as illustrated the rafters form an 
 efficient brace to the central part, in Which there 
 
QENEBAL FABM BABNS. 
 
 39 
 
 is a hay track and where hay comes directly to 
 the earth. Well braced this building will keep 
 its shape for many years. 
 
 THE GLIDE UMBKELLA BAEN. 
 
 In the Sacramento Valley of California there 
 is little cold weather but some rain in winter. A 
 Mr. Glide has there built an immense barn with 
 a roof projecting about 12' on every side, beneath 
 which cattle shelter and eat hay stored within. 
 
 The idea is worth considering in any warm wet 
 country. (See Figs. 43, 44 and 45.) 
 
 FIG. 45 — THE GLIDE UMBRELLA BARN (SIDE VIEW). 
 
 CATTLE BARNS. 
 
 The ideal location for the barn should be as 
 nearly as possible in the center of the farm. The 
 dwelling of course must be near. The advan r 
 tage of having as many pastures and fields 
 directly connecting with the barns is obvious. 
 Time, distance, labor, all are saved, and over- 
 sight, at all seasons, of the stock made more 
 convenient. The character of the site, however, 
 is of still greater importance, and perhaps there 
 is nothing worse than a low, flat, undrained barn- 
 yard and adjacent lots. Strange to say, how- 
 ever, nothing is more common. 
 
 If such a location is unavoidable then it will 
 pay to use all the resources of drainage, tile and 
 stone, till even the longest wet spell loses its 
 terrors and planks and rails no longer are needed 
 as bridges to cross th'e depths and reach the barn 
 door. Wet, and not cold, is the greatest enemy to 
 thrift and flesh, and the floors of all sheds and 
 pens should be high, dry and well drained. The 
 importance of a sufficient number of well fenced, 
 conveniently arranged lots of sizes from a hun- 
 dred or so square feet up to an acre or two should 
 not be overlooked. There are never too many. 
 There is an infinite variety of wants met by an 
 infinite variety of circumstances, mental pecu- 
 liarities and financial conditions, resulting in a- 
 corresponding variety of farm buildings. 
 
 Good air, good light and dryness are foremost 
 in importance; they go together. One of these 
 qualities lacking, the others are almost sure to 
 be absent. The dark, cavernous recesses of very 
 large barns are seldom ventilated or dry. The 
 heavy foundations imply a basement dark, damp 
 and malodorous. The great roof and floors mean 
 heavy timbers, much skilled labor and expense, 
 and last but not least is the chance that some 
 winter night, in red and yellow flame skyward 
 soaring, the huge structure vanishes with all the 
 horrors of agonizing death to helpless animals 
 
 and to the owner loss immeasurable. More desir- 
 able are two or more smaller buildings, all above 
 ground, on light foundations, light timbers with 
 but little framing and far enough apart for some 
 degree of safety from fire and a chance to save 
 life. There should be doors on every side and 
 ample windows. Nothing is so cheap as sunlight 
 and yet nothing is so scarce in the average barn 
 or stable. Another great advantage of somewhat 
 scattered and smaller buildings is the possibility 
 of dividing up the stock and obtaining direct 
 access from different lots and pastures for differ- 
 ent classes of stock. It is not uncommon to see in 
 the middle of the night, in a large barn, a hun- 
 dred cattle aroused and disturbed by one uneasy 
 heifer or lost calf. Avoid all plank flooring as 
 one of the worst temptations of the artful archi- 
 tect. Broken stone (8") with here and there a 
 3" tile running to the outside, with 6" of porous, 
 yellow clay on top, wetted and tamped, harden- 
 ing like a brick, will always be dry, never slip- 
 pery, needs only here and there after the winter 
 is over a little fresh clay and affords no harbor 
 for rats. Many breeders prefer cement floors, 
 which are in common use. Have no narrow, con- 
 tracted passageways in which the larger cattle 
 will crowd and jam together. A favorite arrange- 
 ment seems to be a narrow feeding alley, two 
 rows of cattle, heads in, and two narrow passage- 
 ways behind the cattle. This is a. misuse of space, 
 more expensive and no more convenient. Ear 
 better have one wide space, not less than 10', 
 which is less than the 3' in the center, in which 
 the cattle have ample room to walk quietly to 
 their stalls, Where they stand heads to the wall. 
 A hand-cart may be used to distribute the feed 
 (before the cattle come in at night) and every 
 animal always has the same stall. A noted cattle 
 breeder is quoted as saying that time and again 
 he has seen 70 head of cows walk into such a 
 
40 
 
 FARM BUILDINGS. 
 
 stable from three entrances and -be tied up by 
 two men and munching their feed in 20 minutes, 
 with neither noise, hurry nor confusion. 
 
 Every barn should have a mow sufficient at 
 least to supply its inmates with the winter's hay, 
 bins for bran and prepared feed, but it is the 
 opinion of many farmers that the corncribs 
 should be separate and distinct structures. 
 
 In latitudes where the mercury only now and 
 then falls below zero animals suffer more from 
 the barn being too warm and close than from 
 cold. In fact but for the difficulty of properly 
 apportioning feed, so far as health is concerned, 
 a good, deep shed, say 20' from front to rear, 
 with a hay-rack and plenty of bedding, is better 
 than a barn; the air is pure; there are no 
 draughts and no over-heating and no chilling. 
 Health and vitality are in direct proportion to 
 pure air and well bedded is half fed. 
 
 No matter how perfect the barn may be noth- 
 ing can take the place of abundant bedding, and 
 convenience in getting it in and getting it out 
 (in the shape of manure) easily and rapidly is 
 a thing indispensable. The manure should go 
 direct from the stalls to the pastures and corn- 
 fields. As long as wheat will pay the cost of 
 production the straw is a .sufficient profit to 
 justify the stock raiser in growing it. Sawdust 
 and even dry leaves are useful if straw is lack- 
 ing. Water in the barn is not generally a suc- 
 cess. A large central tank supplying drinking 
 troughs in every lot, fitted with covers to be 
 closed at night in the winter, seems to serve every 
 purpose, and it is a rare day when all kinds of 
 stock should not be turned out for a few hours at 
 least. Thirsty cattle coming suddenly out of an 
 overheated barn may be hurt by drinking ice 
 water but the cold air has the same effect and 
 the 'condition of the cattle is the fault. 
 
 Hinges of course are obsolete. Nothing but 
 the best of rollers should be used, the track of 
 iron, put up as true and solid' as it is possible to 
 have it, and then watch and keep clean the groove 
 in which it runs at the bottom. Box-stalls should 
 be built wherever a roof can be extended along 
 the sides without cutting off the light and air 
 from the main building. A long shed closed in 
 front and divided into box-stalls, on the north 
 side of a lot, is of great utility.- One or two 
 extra warm ones should always be provided a lit- 
 tle to one side for winter-night calving, sick ani- 
 mals and the like. 
 
 Many patent fastenings have been suggested 
 and advertised, but after all nothing in practice 
 has been found more convenient, more speedy or 
 more safe than the old-fashioned German chain 
 cattle tie with about a foot play on a vertical 
 y 2 " iron r °d under the edge of the manger. 
 The cattle have perfect freedom up and down 
 
 and can reach to the center of the manger of an 
 8' or 9' double stall. When taken off the cattle 
 the end ring should be hooked over a nail in the 
 side of the stall just above the animal's neck, 
 where it is just in place for use at night. 
 
 A KANSAS CATTLE BABN. 
 
 , The diagram (Figs. 48 and 49), as will be 
 seen,- <fully carries out the idea that an expensive, 
 elaborate barn is not a necessary adjunct to suc- 
 cessful cattle breeding in the Western States, but 
 that reasonable shelter for the herd from the 
 rigors of winter and some little outlay for the 
 protection of the hay is in keeping with the best 
 principles of economy. This barn was built by 
 Col. W. A. Harris on his Linwood Farm in 
 
 F 
 
 amen \^, guttes *^> * &' ourrca V/ gutter 
 
 FIG. 48— A KANSAS CATTLE BARN (GROUND PLAN). 
 
 Kansas. The unpretentious yet admirably 
 arranged building (briefly described herewith) 
 was built many years ago and has given the 
 best of satisfaction. The materials used in its 
 construction were as follows: 32 telegraph poles, 
 20' long; 32 telegraph poles, 25' long; 6,000' of 
 boards, 16' long; 30,000 shingles; 400 battens, 
 3" x y 2 ", 16' long; 34 sashes, 4 lights, 10" x 12" ; 
 4,500' of flooring; 200 joists, 2" x 8", 16' long; 
 2,500' of rough boards; 250 pieces, 2"x4", 16' 
 long; 1,400' of masonry in underpinning. 
 
 TRONT ELEVATION 
 
 FIG. 49— A KANSAS CATTLE BARN. 
 
 Points in favor of this cattle barn are cheap- 
 ness, light, ventilation and ample room. The 
 wide alleyway permits the ready and uncrowded 
 passage of cattle, and the same is true of the 
 stalls. Wagons go through and take up the 
 manure, which goes direct to the fields. Bedding 
 is distributed in the same way, and hay from the 
 outside is distributed in' this way, holding in 
 reserve that in the mow. The dirt floor is cheap 
 and never slippery. The holes which wear are 
 readily filled by a load or two of dry earth which 
 is at once an absorbent and deodorizer. All the 
 
CATTLE BARNS. 
 
 41 
 
 FIG. 50 — THE MORGAN COW BARN (FRONT ELEVATION). 
 
 windows open on one side or the other (to the 
 leeward) and have no "wheezing" or "coughing." 
 It was built by two carpenters and four laborers 
 in thirty days and cost about $1,100. The mow 
 
 holds nearly 140 tons of hay by filling up after 
 the first has settled. 
 
 THE MORGAN COW BARN. 
 
 The barn shown in Figs. 50 and 51 is T-shaped, 
 413' across the front and extending back 280'. 
 It was recently built by F. W. Morgan on his 
 Wisconsin farm. The entire barn covers about 
 three-quarters of an acre. There are two silos in 
 connection with the barn, the forward one being 
 25' inside diameter with 18" walls and 40' high 
 with 8' in ground. The other silo is 30' inside 
 diameter and 40' high. Both are constructed of 
 grout, a mixture of four parts ordinary gravel, 
 two parts sand and one part Portland cement. 
 These silos have given good satisfaction. The 
 entire floor of the barn is also made of grout A 
 patent roofing is used in covering both the sides 
 and roof. This is composed of layers of felt, 
 burlap and felt, the three coats being cemented 
 
 BOX STALES i 
 HlwiovABi-E sijoes j 
 
 SAMf 
 
 1 
 
 FIG. 51— THE MORGAN COW BARN (GROUND PLAN). 
 
 together with asphalt. The sides are battened. 
 The frame is composed of 2" x 10", 6" x 6" and 
 2" x 6" planks and is of ordinary construction. 
 In the center of the barn is an open space in 
 which is a weighing scale and from which silage 
 can be loaded and carried to feed troughs under 
 cover. The maternity stable has double rows of 
 posts equi-distant apart with grooved sides into 
 which portable gates can be placed, thereby form- 
 ing separate stalls 28' square for each cow and 
 calf. There are eight bull stalls 16' x 25', each 
 one with separate door into yard. 
 
 AN IOWA CATTLE BARN. 
 
 The barn shown in Figs. 52 and 53 is 48' x 68'. 
 It was built in 1893 as a hay, stock and feed 
 barn, with the hay part in the center 24' x 48', 
 with a 14' stock driveway on each side and corn- 
 
42 
 
 FABM BUILDINGS. 
 
 cribs 8' x 48' on each side of stock-way, with 
 troughs in the stock-way next to crib and oat-bin 
 over each stock-way, with chutes leading to 
 troughs below. As thus arranged the barn holds 
 3,000 bushels of corn, 1,500 bushels of oats and 
 
 the barn figures as follows: Hay, 240 tons; 
 grain, 9,000 bushels; cattle, 100 head; horses, 10 
 head. The frame is balloon construction and all 
 of native hard-wood, the lumber being sawed on 
 Mr. Barclay's farm. With the exception of the 
 
 CROUWO PLAN OF CATTLE BARN 41X68 
 
 FIGS. 58 AND 53— AN IOWA CATTLE BARN. 
 
 65 tons of hay, with feeding room for 40 head of 
 cattle. 
 
 In order to increase the stock room and reduce 
 the hay compartment the center part was 
 changed into a cattle-barn, providing room for 
 30 cattle in stalls, with the same stock room 
 outside of this as before. A feed-bin 8' x 6' x 48' 
 was built, with a chute to stalls below. There is 
 room for 60 cattle (20 stalled), 3,000 bushels of 
 ear-corn, 1,500 bushels of oats, 1,000 bushels of 
 shelled corn or ground feed and about 40 tons 
 of hay. The frame is whiteoak poles set in 
 ground every 8' except at cribs, where they are 
 4' apart, with additional foundations set on stone 
 under each crib. 
 
 A HAWKEYB CATTLE BARN. 
 The cattle barn shown in Figs. 54 and 55 was 
 built for C. S. Barclay of Iowa. The capacity of 
 
 4" x 12" sill there is nothing thicker than 2" in 
 the frame, the girders, posts and some other mem- 
 bers being built up. 
 
 This makes a much stronger job and saves 
 time in the framing., The back 45' of the first 
 floor is used as the main mow. The bents which 
 form the frame in this part of the barn are so 
 constructed that no cross-tie beams are required. 
 This arrangement requires less labor and mate- 
 rial and makes a stronger construction, besides 
 doing away with the objectionable tie-beams. The 
 frame is all securely bolted together. 
 
 A dump elevator and grinding machinery are 
 so installed as to save much labor. (See Fig. 57.) 
 The power required to run the machinery is fur- 
 nished by a 12-horse power portable gasoline 
 engine. Chutes are so arranged that all kinds of 
 feed are accessible in the feed room without han- 
 dling. A water supply is also installed. (See 
 Fig. 56.) 
 
 The floor in the driveway of the basement and 
 also in part of the stalls is of paving brick laid 
 
 
 FRONT ELEVATION 
 
 FIG. 54— A HAWKEYH CATTLE BARN. 
 
 LIFT 9101 CLCVATIOH. 
 
 ITIG. 55— HAWKEYE CATTLE BABN. 
 
CATTLE BABNS. 
 
 43 
 
 on a bed of sand, the cracks between the bricks 
 being washed full of thin cement. The remainder 
 of the floor in the basement is of concrete. The 
 floor for the house stable, which is on the first 
 floor, is of concrete. 
 
 Behind the stalk the concrete is covered with 
 2" flooring. The stalls are provided with hard- 
 wood gratings, which can be removed for clean- 
 ing. The cattle mangers and feed-racks are a 
 new departure. The barn cost about $6,000. 
 
 ANOTHER KANSAS CATTLE BARN". 
 
 This barn is built of joist construction, no 
 piece being more than 2" thick. It has ample 
 storage for all the cattle that can get beneath the 
 roof and is so constructed that winds have little 
 effect upon it, the low roof deflecting them harm- 
 lessly upward. 
 
 The dimensions are 60' x 112'. It is so 
 designed, however, that the length may at any 
 
 BASEMENT PLAN 
 
 BG. 56— HAWKIYE CATTLE BARN. 
 
 time be increased by adding more bents. The 
 principle of construction is clearly shown in Pig. 
 58, an end elevation showing a doorway framed 
 to take in hay from the outside. This feature is 
 not in the barn as built. 
 
 This barn has the open-center which admits of 
 hay being unloaded by slings and carriers that do 
 not raise the hay higher. than high enough to 
 
 clear the level of the top of the mow before 
 they swing back. 
 
 The interior arrangement as adapted to the 
 feeding of young beef cattle also is shown in 
 Fig. 58. The exterior is nicely presented in the 
 
 This barn has been extensively copied. It is 
 unique in that it dispenses with siding except at 
 the ends, and for strength, cheapness and general 
 
 1 
 
 
 
 H- 
 
 [ 
 
 X« Mi 
 
 1 
 
 -1) 
 
 
 
 
 - r - : t^y£r 
 
 
 
 S3 
 
 E 
 
 
 -""--I 
 
 1/ 
 
 ------ 
 
 J. •"* 
 
 --.--.- 
 
 
 M.U. 
 
 1 
 
 
 _K»J* Jr.. 
 
 rrr 
 
 ~* 
 
 1 
 
 J 
 
 
 ^M 
 
 P-o" , 
 
 / 
 .,. lv ,,i^. 
 
 / ! 
 
 
 ,au ± 
 
 
 / D J [ 
 
 
 
 1 
 
 r 
 
 
 j □>£* r 
 
 
 
 'JP 
 * 
 
 
 
 
 
 
 
 
 riRST FLOOR PLAN 
 ITG. S7— HAWKBTE CATTLE BARN. 
 
 desirability it has hardly a rival in the class of 
 large barns. 
 
 AN INDIANA CATTLE BARN. 
 
 One of the largest and best cattle barns in the 
 country is that erected by P. A. Nave of Indiana 
 for his Pairview Hereford herd. Its construc- 
 tion is clearly shown in the diagrams from the 
 architect's plans. The dimensions are 120' long, 
 64' wide and 18' to the eaves. It runs east and 
 west and is set into a bank that affords driveways 
 from the level onto the upper floor at the east 
 end and the northwest corner. A heavy stone 
 wall runs along the entire east and north sides, 
 but the ground falls away sufficiently on the north 
 to allow of ample window space. Doors open at 
 frequent intervals on the south side into good- 
 
44 
 
 FABM BUILDINGS. 
 
 i 
 ^ 
 
 i i 
 i i 
 i j 
 i i 
 
 i J ■ i 
 
 L__h 
 
 n 
 
 K 1 
 
 i i 
 
 1 I 
 
 
 
 
 
 
 / 
 
 / 
 
 / 
 
 
 N 
 
 \ 
 
 \ 
 
 
 / 
 
 / 
 
 / 
 
 
 N 
 
 \ 
 
 \ 
 
 / 
 
 / 
 
 / 
 
 
 \ 
 
 \ 
 
 N 
 
 / 
 
 / 
 V 
 
 / 
 \ 
 
 
 v 
 
 
 / 
 
 
 
CATTLE BABN8. 
 
 45 
 
 FIG. 59— AN INDIANA CATTLE BARN (BEAR ELEVATION). 
 
 sized and well-drained paddocks, and the fall is 
 equally good on the west. Fig. 59 shows the rear 
 (west) elevation, and also the engine-house and 
 water tank. A large gasoline engine pumps water 
 and runs corn-sheller, grinder, fodder-shredder 
 and' hay-cutter on the upper floor. While pos- 
 sibly a little power may be lost in transmission, 
 yet the engine is adequate, and this small loss 
 
 The posts are all set on stone foundations. Pig. 
 61 gives an idea of the framing of the barn, show- 
 ing an end and an inside bent. The ends are 
 strongly framed and a very large inside space 
 is clear. The ground plan is indicated in Fig. 
 62, which shows the arrangement of the stalls. A 
 row of large boxes runs through the. center and 
 the middle partitions through the entire row are 
 
 V N/ W W W \K N^ 
 
 X7^7^S 
 
 / w w w \y w \y 
 
 6 >,& , 6 A 
 
 FIG. 60— AN INDIANA CATTLE BARN (FRAMEWORK). 
 
 is more than compensated for=by the protection 
 from fire in this detached engine-house. The 
 well is equipped with a 6" pipe and the supply 
 is fairly inexhaustible.* Hot , and "cold water is. on 
 tap in the barn, The entrance to the huge upper 
 
 .movable, so that two boxes may be thrown into 
 one. On either side the cows with calves" may 
 be tied, two to a stall, although each stall will 
 comfortably accommodate three cows. The con- 
 venience of the calf pens needs no explanation. 
 
 floor for hay and corit- fodder is at the corner „ThIs barn is very substantially built but without 
 nearest the engine-house. ,. ; , ,1r -extravagance. 1 It was. designed throughout by 
 
 The side of the framework is shown in Fig. 60. "f'Mr. Nave as "the most convenient plan that he 
 
 FIG. 61— AN INDIANA CATTLE BARN (FRAMEWORK AND FOUNDATION). 
 
46 
 
 FABM BUILDINGS. 
 
 I J)iiin.(«p 
 
 ■fflmn 
 
 / l 
 
 JwC 
 
 u-r; 
 
 ZS" c 
 
 u~ \ ' .. .;.vc: 
 
 3 (tit ton .iH«i«; 
 
 
 an . ■■ 4^ < 
 
 
 3^C=3 
 
 ^ 
 
 tal* rt»u. 
 
 *' ■ *4I » M* ■ i IT 
 
 Oowit — 
 
 PIG. 62 — AN INDIANA CATTLE EARN (GROUND PLOOR PLAN). 
 
 PIG. 68— A HOOSIER CATTLE BARN (SIDE ELEVATION). 
 
 could figure out for the economical care of a large The second story will hold all the provender 
 
 herd. It will easily accommodate 150 head of and forage needed for a large herd, thus doing 
 
 cattle, and 200 head may be comfortably housed away with the necessity of hay barns and fodder 
 
 without crowding. stacks. In the west end the mill rooms are lo- 
 
CATTLE BABNS. 
 
 47 
 
 cated, and the prepared feed drops below to the 
 mixing floor. 
 
 A HOOSIEB CATTLE BAEN. 
 
 Figs. 63 and 64 show the ground plan, interior 
 arrangement and elevation of one of the large 
 cattle barns on the farm of J. H. Miller of In- 
 diana. The arrangement of this barn is very con- 
 venient, and while it is large and roomy it has 
 not cost an extravagant amount of money. The 
 advantage of the arrangement of the different 
 stalls and paddocks will be readily perceived, and 
 
 4" x 4" ; rafters, 2" x 4". and the barn cost about 
 $2,500. 
 
 AN OCTAGONAL CATTLE BARN. 
 
 An octagonal barn that will accommodate 
 about 50 head of cattle is shown in Pigs. 65 and 
 66. 
 
 The octagonal form has always seemed open to 
 the objection of being hard to fill with hay and 
 more difficult to arrange in the interior. How- 
 ever, it may be that the great amount of space 
 secured at the cost of a much less amount in the 
 
 FEED TROUGH on 
 
 &70NC WALL 
 
 
 BULL CALF STABLE 
 15X20 r- 
 
 DULL PADDOCK 
 15 X 20 n 
 
 ODOR 
 
 a 
 
 
 FEED 
 
 RACK 
 
 
 
 5 F - T 
 
 WIDE 
 
 
 FOR LOOSE STOCK 
 13 K. X 78 FI 
 
 CALF STABLE 
 
 HEIFER BARN 
 
 DOOR 
 
 FEED TROUGH 
 
 FOR LOOSE STOCK 
 \SX 38 
 
 FEED RACK 
 
 T FT WIDE 
 
 FOR LOOSE STOCK 
 13 ''v X 76 n 
 
 COW STABLE 6 COWS 
 
 lb FI 
 
 
 
 I 1 
 
 2* F 
 
 1 
 
 T 
 
 1 
 
 i I 
 
 , 
 
 
 
 FECI) WAY 
 
 4 V 
 
 I DOUBLE 
 
 « Bull stall 
 
 o 
 
 DOUBLE 
 BULL STALL 
 
 
 
 
 
 FEE0 
 
 BOX 
 
 1V& r; 
 
 4 BULL STALLS 
 
 i 
 
 5 
 
 FEED WAY 
 
 40 FI 
 
 , OOOB 8 F T 
 
 ** BULL STALLS 
 30 F T 
 
 BULL 
 PADDOCK -n 
 
 56 FS 
 
 FIG. 64— A HOOSIER CATTLE BARS (BASEMENT PLAN). 
 
 it will be noticed that a wide driveway extends 
 through the barn from north to south, so that the 
 stalls can all be conveniently cleaned and the 
 manure hauled away readily without much extra 
 labor. 
 
 The feed-bins are on the second floor with 
 chutes to the basement. There is a traveling 
 feed-box of about ten-bushel capacity swung to a 
 steer hay track above the feedway, running the 
 whole length of the barn, 78'. Above the base- 
 ment is a large hay mow and roofs for feed and 
 machinery. The basement itself it 8' high, the 
 posts are 12"xl2"; joists, 2"xl2"; braces, 
 
 square form more than balances the objection. 
 This octagonal barn of 25' on a side has in it 
 about 800 square feet more space than the same 
 amount of wall in a square form. That is equal 
 to gaining a barn 20' x 40'. However, the main 
 objection, that of filling the barn, remains to be 
 attacked, This may largely be overcome by erect- 
 ing a gable on one of the sides of the roof and 
 running a track in from that height which may 
 be carried across to within 20' of the opposite 
 side, and that will serve very well to distribute 
 the hay. 
 The walls should be made 24' high, the base- 
 
48 
 
 FABM BUILDINGS. 
 
 ment 8' to 10', the roof will rise 20' and the little 
 turret in the peak will be about 48' above the 
 foundation. The roof is self-supporting, the 
 plates being bolted together at the corners and 
 held by a band of iron 4' long bent to fit and 
 solidly bolted so that the corners can never spread. 
 The plates are of 2" x 12", two parts. All parts 
 are of joist construction. 
 
 The basement plan shows stalls for over 60 
 cattle; the larger cattle would be in the outer 
 circle, the smaller ones in the inner row. One 
 
 JTG. 68— AN OCTAGONAL CATTLE BARN (ELEVATION). 
 
 TIG. 68 — AN OCTAGONAL CATTLE MRS (GROUND PLAN). 
 
 feeding alley serves for the two rows and a circu- 
 lar track brings in grain or silage 1 and another 
 circular track and conveyor takes away the 
 manure. Above the passage and just within the 
 outer door there will be chutes from above, down 
 which will come hay, bran and other feed, the 
 granaries being located there, and filled from the 
 same door that takes in hay. There would be 
 other hay chutes leading down to the feed alley. 
 
 Abundant light and air are let in to the base- 
 ment by a practically continuous window 3' high 
 and 3' above the ground. The sashes of this 
 window hinge at the bottom edge and incline in- 
 ward, each one being opened all at one motion or 
 closed by a motion, the mechanism being the 
 familiar contrivance employed in greenhouse con- 
 struction. The outer walk is 4' wide at its nar- 
 rowest point. Perhaps 3' would be better, as it 
 would give more room between the cattle, and 
 with the manure conveyors there is not the need 
 of wide passages that there once was. Cement 
 floor throughout and Van Norman stalls com- 
 plete the basement construction. 
 
 A CO'BJST-BEI/T BAKN". 
 
 The Illinois barn illustrated in Figs. 67, ,68 
 and 69 has an immense storage capacity afforded 
 for hay and straw, and in view of the vast quan- 
 
 uiiF*Mij, ii 'I lit jmpumiUBaaewW^- 
 
 PIG. 67— A CORN-BELT BARN (END SECTION). 
 
 tity of forage of that description wasted annually 
 from lack of protection from the inclement 
 weather the question arises as to whether or not 
 more attention should be given to that subject 
 in the construction of barns. 
 
 eoxsml 
 
 coir 
 
 $*T£ 
 
 MINIMI 
 
 to n $m 
 
 My 8/ir f/?o/H <?/)ou*/o ro/roof 2o'srso' 
 
 &rf 
 
 Cow 
 
 /fii£y 
 
 J' 
 
 cnw 
 
 pens 
 
 ^vgj/? 
 
 £»« 
 
 I I I I LUtUWXJJJt 
 
 iv/iiLS B£>sii/o car ne 
 
 
 ctif 
 
 P£t/<S 
 
 fire 
 
 PIG. 69— A CORN-BELT BARN (GROUND PLAN). 
 
 The plan indicates a barn 50' x 70', with cattle 
 stalls and a 3' alley on each side, central space 
 and entire area above the stalls being devoted to 
 the mowing of hay and straw. The "end section" 
 (Fig. 67) is intended to show this arrangement. 
 
 There are doors at the rear end of the barn the 
 same as in front and over the main doors in the 
 
CATTLE BABNS. 
 
 49 
 
 rear are two smaller doors wide enough to admit 
 the straw-carrier of a threshing machine, so that 
 when threshing the machine dumps the straw into 
 the loft of the barn over the stack on either or 
 
 There is also 
 
 both sides by moving the machine, 
 
 a large door 10' x 9' for taking hay from the load 
 by the horse hay forks on a trade running the 
 entire length of the comb of the barn, hauled up 
 by horse at the other end of the barn. 
 
 Material of the following description is used: 
 
 TIG. 70— MODERN TYPE OT CATTLE BARN (ELEVATION). 
 
 
 Cbv*r 
 
 J*"/ 
 
 
 PIG. 71— MODERN TYPE OF CATTLE BARN (GROUND PLAN). 
 
 Sills, 6" x 8" ; joists, 2" x 8" ; corner posts, 6" x 6" ; 
 other posts, 4" x 6" ; braces, 4" x 4" ; girts, 2" x4" ; 
 plates, 4" x 6"; rafters, 2" x 4" ; sheeting, second 
 fencing; shingles, 18", best; siding, 12" stock 
 boards; flooring,?" x 8". 
 
 MODEEN TYPE OF CATTLE BAKN". 
 
 A sanitary, comfortable and commodious barn 
 recently built is that designed by Joseph E. Wing 
 for H.H. Trimble of Iowa. It has 84 single 
 stalls and 10 box-stalls or breeding pens. There 
 are bins for grain and storage for 350 tons of 
 forage above. Silos may be conveniently added, 
 one at the end of each wing, where the feed-car- 
 rier will convey the silage down the central alley 
 between the rows of cattle. 
 
 The barn is 30' wide and forms three sides of 
 an open court (Pig. 70), 66' x 78', which is 
 designed to be paved with vitrified brick or con- 
 creted, having a water tank in center, thus form- 
 
50 
 
 FABM BUILDINGS. 
 
 ing a convenient sheltered yard where cattle may 
 exercise any day in severe weather. Fig. 71 shows 
 the ground floor. The specifications provide this 
 barn with manure-carriers behind the cattle, feed 
 carriers with track in front of them and numer- 
 ous windows to admit light and air. The win- 
 dows are hinged at the lower edge and open 
 inward with ,greenhouse construction, so that a 
 
 about 300 tons of hay and there is a place directly 
 over the meal bin for two carloads of bran or 
 feed. One floor of the barn is cement, having 
 a slope of 5" from where the cows are chained 
 in the box-stalls. The stalls also slope 2" from 
 
 MBBT3m$t K|"il"a ■ gljif m ■ |@j S IH ffl; 
 
 M p bl i_ia|— p| — lap— m — fa|_laM 
 
 .: '..J Musi i i ; { ; I L i .'...: [.... 
 
 JBTG. 74— AN ILLINOIS CATTLE BABN (SIDE ELEVATION). 
 
 turn of a wheel opens a row of them. Sectional 
 hay chutes extend down into the feed alleys. The 
 barn has cement floors and Van** Norman stalls. 
 This barn has proved very satisfactory to the 
 proprietor, who says that "we believe we have 
 
 FIG. 72— A BABN FOB BBEEDING CATTLE (END ELEVATION). 
 
 outside the barn to the drain behind the cows. 
 The drain slopes gradually from both ends to- 
 ward the center, where there is a till to receive 
 the liquid. There are six large ventilators run- 
 ning from the bottom of the barn up to the 
 
 124 
 
 Pi 
 
 "ool 
 
 FEED BIN 
 12X12' 
 
 ''>'■ 
 
 
 
 
 >- 
 
 — 1 
 — 1 
 
 8 
 
 
 
 
 
 FEED BIN 
 12x12' 
 
 DRIVE WAY 
 
 14' 
 
 8' 
 
 
 
 
 
 
 8' 
 
 4 
 
 8' 
 
 
 ■ 
 
 
 
 
 8' 
 
 jo . ALLEY 
 ran? 
 
 COWS TIED uj IN CHAINS 
 ^ PUMP 
 
 ool 
 
 8' 
 
 |4'D 
 
 ALLEY, £ 
 ,4.n: 
 
 2 7-1 
 
 8' 
 
 
 
 
 
 
 8' 
 
 Ar 
 
 DRIVE WAY 
 
 12X12 
 FEFD BIN 
 
 4'D. 
 124' 
 
 
 
 
 
 12X12 
 FEED BIN 
 
 '-- -i 4 
 
 ITG. 73— A BABN FOB BBEEDING CATTLE (GBOUND PLAN) 
 
 saved $1,000 of its cost in one season in grain and 
 hay and in preventing loss of flesh in the ani- 
 mals." 
 
 A BARN FOE BBEEDING CATTLE. 
 
 The cattle barn at the Willow Lawn farm of 
 E. Reynolds & Son of Illinois is 56' x 134'. It 
 is 22' to the eaves and 48' to the peak, giving 
 ample pitch to ihe roof. This barn will hold 
 
 cupolas. There are 24 windows below and several 
 opening into the loft. (See Figs. 72 and 73.) 
 The barn cost about $4,000. 
 
 ILLINOIS CATTLE BARN. 
 
 Col. Frank 0. Lowden's large cattle barn on 
 his farm in Illinois is one of the most complete 
 and conveniently arranged buildings to be found. 
 There is a perfet system of water-works and sew- 
 
CA1TLE BABNS.' 
 
 51 
 
 erage in the barns and yards and there are water 
 troughs in every yard that drain directly into the 
 sewer, so that when hot in use they can be 
 
 iSECTION SHOWING FRAMING 
 or INTERIOR BAYS 
 
 iSrCTJOH SHOWING FRAMING 
 
 OrijABLf fNDi 
 
 FIG. 75— ILLINOIS CATTLE BARN (SECTION). 
 fl|£ 
 
 i na 
 
 i; n 
 
 na 
 
 i4'iu' 
 
 156 
 
 i2ir 
 
 at 
 
 14' 
 
 as 
 
 14' 
 
 7fT"~ 
 
 i FIRST FLOOR PLAN i FOUNDATION PLAN 
 
 PIG. 76— ILLINOIS CATTLE BARN (PLAN). 
 
 drained, thereby obviating the danger of freezing 
 and insuring water of even temperature at all 
 times. 
 
 The dimensions of this barn are 71' 8" x 121'- 
 
 10". The diagrams shown in Pigs. 74, 75 and 76 
 present a clear idea of its arrangement. 
 
 Peed is conveyed by trolley cars on either side 
 of the main floor and in front of the cattle stalls. 
 The capacity of the hay loft is 260 tons. The 
 hay is taken up in the center of the barn and con- 
 veyed by reversible carriers to either end of the 
 barn and is thrown down in center of main floor 
 to feed cattle in the stalls. The racks in the 
 box-stalls are filled directly from the loft through 
 trap doors in the floor which may be closed when 
 not in use. Alleys behind the stalls are wide 
 enough so that a manure spreader for receiving 
 the manure may be driven through and taken 
 directly to the fields. 
 
 AN OPEN CENTEK CATTLE BAEN. 
 
 The cattle barn shown herewith is 50' x 105' 
 with a basement 10' high and second floor posts • 
 
 
 o 
 
 Nv 
 
 /Y H*f 
 
 vs. ^ 
 
 VS Ui 
 
 vs. u% 
 
 / \ 
 
 SO 
 
 ~1 ^ 
 
 / \ 
 
 FEET. 
 
 / \ 
 
 PIG. 77— AN OPEN CENTER CATTLE BARN (PRAME WORK). 
 
 16'. Pig. 77 illustrates plainly the method of 
 frame. It will be seen that this is an open-cen- 
 ter barn. With -large barns of this type there 
 must be unloaded a great deal of hay and there 
 is nothing that compares with the sling for un- 
 loading hay, and the use of the sling calls for an 
 open-center barn with no ties across the mow 
 floor. Two purlin plates support the roof. The 
 roof is half pitch. This frame is built of solid 
 timber but 2" joists may be used. In this case 
 a few hundred dollars in expense may be saved 
 and perhaps a stronger and better frame secured. 
 Pig. 78 shows the basement floor. The feed 
 passage is 4' wide with the mangers taken off ; hay 
 is thrown directly into the feed passage down 
 chutes reaching from the mow above and coming 
 down the purlin posts. There is room between 
 the rows of stalls for the driving in of the wagons 
 to clean out the trenches, although there is not 
 room to drive in between the cows when thev' 
 
52 
 
 FARM BUILDINGS , 
 
 are in their stalls. The stalls may be put further 
 apart than they are if it is not thought best to 
 turn the cattle into the yard while the stable 
 is being cleaned. The stalls are 3y 2 ' apart, thus 
 getting 14 animals in a row. The whole barn 
 may be divided in this way or part of it may be 
 made into pens in which polled or dehorned cattle 
 may run loose. 
 
 ■ ■■ ■ -— w — ■■■ 1 
 
 W/Uk 
 
 | C|0 |W.| S J T | A | L | L | S | | 
 
 FEED PASSAGE 
 
 t m a <i 
 
 WALK 
 
 ■ * 1 
 
 FEED ALLW. 
 
 ■ ■ ■ 1 
 
 *™ -■■- — — 
 
 • Poil ■ ■ 1 
 
 ClOUND PLAhf_or 
 Cattle Barn. 
 £ 50 x /Of WitK 
 ^ IS Ft. Walus. 
 
 ■ ' Posi" ' 
 
 _ These btnti ma-fbi nibtd. 
 ' uu 1 1 it. /e n j for jauhii o.^ttle- 
 
 ' IL Ft. ' I8-Ft • It Ft. ' 
 
 w 
 
 . _ m ■ 
 
 PIG. 78— AN OPBN CENTER CATTLE BARN (GROUND PLAN). 
 
 Very thorough ventilation should be provided 
 in so large a barn where so many animals are 
 confined. The hay chutes provide quite well t6 
 carry off. the vitiated air but provision should be 
 made for a fresh in-flow. The bents are spaced 
 15' apart because that distance fits the stalls. If 
 
 the lumber must be bought it would be better to 
 use 16' spaces, making a wider feed alley, as odd 
 lengths are not kept in stock. This would make_ 
 the length of the barn 112'. 
 
 HAY. 
 
 
 INCLINE 
 
 D*ive ovtucisttw 
 
 Bins Foil Oau Etc 
 
 
 HAY. 
 
 
 i ^ !l iy 
 
 PIG. 79— AN OPBN CENTER CATTLE BARN (DETAILS). 
 
 Fig. 79 shows the floor. The incline of the 
 driveway is built over a cistern which receives its 
 supply of water from the roof. The oats and 
 ground feed may be spouted from the bins to two 
 feed alleys. Distribution of the ground feed may 
 be made by means of the small cart pushed by 
 
 
 
 
 
 PIG. 80— MISSOURI BARN PLAN. 
 
 hand from which may be measured the rations 
 that each animal is to receive. Fig. 79 also 
 illustrates the method of keeping the joists from 
 being in the way of the feed alleys. The location 
 of the stalls in the basement should be made with 
 
CATTLE BABNS. 
 
 53 
 
 accuracy before the building, is erected, so that 
 nothing will be in the way when all is done. If 
 built in joist frame this ba"rn can be completed 
 in good shape and fitted with stalk for from 
 $1,000 to $1,200. 
 
 A MISSOURI BARN PLAN. 
 
 The cattle barn shown in Pig. 80 was built by 
 James A. Barrett of Missouri. The length is 52' ; 
 width, 36'; 9' and 16' posts are used. The tim- 
 bers are 8" x 8" and 8" x 10". An 8' x 26' self- 
 feeder is placed in the basement. The chutes A 
 and the octagon ends of the cribs empty into the 
 self-feeder. The barn has a capacity of 25 tons 
 of hay, 1,500 bushels of corn and 500 bushels of 
 oats. Nine "single and two box-stalls afford ample 
 stabling quarters. Forty head of cattle find com- 
 fortable quarters in the basement. Diagram G 
 represents oat bins ; C corn cribs ; B the box-stalls 
 (which are 10%' x 12') ; S single stalls 5'; D a 
 10' driveway; H harness-room; K and F stair- 
 ways to the hay mow and basement respectively. 
 At either end of the row of single stalls shown 
 at the top of Fig. 80 chutes are placed for throw- 
 ing hay into the basement, This barn was built 
 at a cost of $1,750. r 
 
 A CATTLE FEEDING BARN. 
 
 A convenient and comparatively cheap barn in 
 which to grow "baby beef" in the Corn-belt may 
 
 FIG. 81— A CATTLE FEEDING BARN (ELEVATION). 
 
 be constructed from the .general description and 
 plans following: 
 
 To get best results among average cattle and 
 in a climate like that of the Corn-belt the animals 
 should run loo^e in a rather small yard, with 
 shelter from wind and storm. It is with a view 
 of meeting this requirement that the enclosed 
 yard shown in Fig. 81 is provided with a shed 
 on three sides, 8' in the clear and with hay 
 loft above. There is a manger running along 
 the outside of the shed in which may be fed hay 
 or silage. Hay is thrown in this directly from the 
 mow through a slit in the floor and it may be 
 boarded up to make a continuous chute open at 
 the bottom through which the cattle draw their 
 hay. The mow is 7' to the eaves and over 18' 
 to the peak, allowing the use of horse forks for 
 filling with hay. While it does not hold a very 
 great amount of hay, it will hold an entire rick 
 
 and the design is to draw during good weather 
 a rick at a time and stow it away in the dry. 
 The sheds and yard are large enough for about 
 125 head of yearling steers. 
 
 SAt«t 10VJ 
 
 
 FIG. 82— A CATTLE FEEDING BARN (FLOOR PLAN). 
 
 Two silos are provided having a capacity of 
 more than 200 tons each. The doors for empty- 
 ing are inside the sheds and there may be an over- 
 head track carrying a large box along the line of 
 
 FIG. 83— A CATTLE FEEDING BARN (CROSS SECTION) 
 
 the manger, thus making feeding easy and rapid. 
 In the yard (Fig. 82) may be provided open 
 boxes for feeding ear corn or shock corn when 
 desired. As this yard is not very large it might 
 be expedient in .many, cases to, cement the entire 
 
54 
 
 FARM BUILDINGS. 
 
 bottom and save mud and waste of manure. Suf- 
 ficient corn should be fed on the stalk to bed the 
 yard thoroughly and keep it dry and clean. 
 A cement tank affords water for the cattle. Eave 
 troughs carry away the drip from the eaves. 
 Modern tin generally lasts about five years and 
 good galvanized iron makes a better trough. 
 
 Forty acres of corn in a favorable season will 
 a little more than fill the silos. There is silage 
 enough in the two silos to feed 175 calves (year- 
 lings) for six months, provided they are fed at 
 the rate of 25 pounds per head per day. If there 
 is a little silage left over until summer it can be 
 used to advantage in supplementing pastures, 
 which often are short during a part of that 
 season. 
 
 The cross section of the frame (Fig. 83) shows 
 a building 30' wide, which is preferable to one 
 , of less width. With the hay self-feeder in place 
 I with a width of 30', a height of posts of 18', with 
 I long rafters 16' and short rafters 10' enclosing a 
 court 80' in diameter the barn will hold nearly 
 300 ton® of hay. The self-feeder is shown in 
 cross section (Fig. 83); the continuous chute is 
 30" wide, the manger 24" out from that, the 
 chute reaching to within 6" of the top level of the 
 manger. Doors in the chute admit of hay being 
 thrown in from any level. Strong feed-racks 
 3%' x 8' that can be set where convenience dic- 
 tates and readily removed on occasion are pre- 
 ferred to permanent mangers. The side opposite 
 the hay-feeder and next to the enclosed yard is 
 open except that gates may be hung so that 
 cattle, when putting in silage for instance, can 
 he shut into the yard. 
 
 A BARN FOE FEEDING CATTLE LOOSE. 
 
 There is a demand for cheap barns in which to 
 store forage and feed to cattle below running 
 
 loose. The design submitted (Figs. 84 and 85) 
 has several good features. Hay stored above is 
 thrown through chutes into the central feeding 
 alley, and thence placed in two long mangers, in 
 which grain may also be fed. The openings may 
 be at the ends or sides and wagons will be driven 
 through to remove the manure. 
 
 Shed 1111,0 
 
 Minftr into 
 
 
 FIG. 85— A BARN FOB FEEDING CATTLE LOOSE (GROUND PLAN). 
 
 This building may be of any convenient length, 
 or may enclose three sides of a square open to 
 the south in which cattle will be sheltered. It is 
 all of joist frame construction, without sills or 
 wooden floor. The floor is hard clay, which is as 
 good as anything where cattle run loose. The 
 barn has a hay track in the peak and, hay is taken 
 in at one end of barn. 
 
 AN IOWA STEEK BARN. 
 
 H. J. Hess' Iowa barn shown in Figs. 86 and 
 87 is 60' x 80' with 14' outside posts. It was built 
 for feeding steers and will accommodate more 
 than 100 head besides 160 tons of hay. The first 
 
 FIG. 84— A BABN FOR FEEDING CATTLE LOOSE (ELEVATION). 
 
 FIG. 86— AN IOWA STEER BARN (CONSTRUCTION). 
 
 floor or basement is one large enclosure with a 
 driveway running through lengthways. This 
 driveway is wide enough to admit a team and 
 manure spreader to pass through the barn. 
 
 The mow floor is supported by posts which 
 stand upon cut stone caps 12" x 14", and these 
 caps rest upon concrete bases 18" x 18" and 24" 
 
CATTLE BABNS. 
 
 55 
 
 deep. In making the concrete bases (see Fig. 
 87) holes were dug a little more than 2' deep and 
 into each was placed an empty cement barrel 
 having about 12" of it sawed off and the head 
 taken out; the concrete was then tamped thor- 
 
 }-,»--£ 
 
 >--•*---£ 
 
 *□ 
 
 — *■ -iff- *■' -Kf- * HO 1 J» — 
 
 E J D □* 
 
 CONCRETE "PIERS Igxlgx^'IlEEP WITH STONF CAP 12x14 
 "D D El DO* 
 
 *D 
 
 & 
 
 — w- - . - f - — itf_ _ _ . ? _ ;_ 
 
 •»□ 
 
 9 s 
 
 Sf4'- - 
 
 tf*- 
 
 c 
 
 - Mff" > «- »*- - 
 
 « . «■-■* » 
 
 EIG. 87— AN IOWA STEER BARN (BASEMENT PLAN). 
 
 oughly in these barrels and when it became hard 
 the hoops on the barrels were cut and the staves 
 removed, leaving a round concrete pier on which 
 to lay the stone caps. 
 
 The outside wall of the barn was made of 
 stones (boulders) laid in cement. It is 3J^' high, 
 
 ELEVATION 
 OCTAGONAL SALE BARN 
 
 TIG. 88— CATTLE SALE BARN. 
 
 3' wide at the base and 2' wide on top. About 
 38" of it is in the ground. From the ground 
 
 floor to the mow floor is 10' ; this gives the cattle 
 plenty of room. The second floor or hay mow 
 will hold about 160 tons of hay, which is fed 
 through six chutes, three on each side of the barn, 
 placed 10' on each side of the center of the mow 
 thus making the two rows of chutes 20' apart. 
 These chutes are cone-shaped, larger at the top 
 than at the bottom, and feed into a manger 
 below. They extend to the roof and hay may be 
 pitched into them at any point. 
 
 The barn is built of 2" pine stuff; there is not 
 a solid timber in it. All the posts are continuous 
 from the cap stones to the roof, being spliced with 
 heavy spikes. The siding is 8" dressed and 
 matched. The large hay room or mow was made 
 possible by constructing the hip roof. Hay is 
 taken in by slings. The barn cost $2,000. 
 
 A CATTLE SALE BARN". 
 
 Designed for use as a barn in which to hold 
 auction sales of pedigreed beef cattle, this 
 
 FIG. 89— CATTLE SALE BARN. 
 
 building (see Fig. 88) seats 600 people (Fig. 
 90) and has stalls for 30 cattle (Fig. 89). As 
 it is not meant regularly to accomodate cattle no 
 provision is made for the storage of hay or grain, 
 which will be received at the barn in small 
 amounts, the hay in bales, and stored temporarily 
 in the passage. The seats are over the cattle 
 stalls and are arranged in a regular incline, giv- 
 ing every visitor a good view of the sale-ring, 
 which is 24' in diameter. The building is 25' 
 long on each side, of octagon shape, and 16' high 
 at the eaves. Light to the sale-ring is afforded 
 by sky lights in the roof. The stalls are well 
 lighted by two windows in each side. The build- 
 ing is very economical of material and space and 
 
56 
 
 FABM BUILDINGS. 
 
 30' in diameter and around the side of the build- 
 ing are 20 large stalls, as shown in Pig. 92. 
 Fig. 92 shows the arrangement of the ground 
 
 TIG. 90— CATTLE SALE BARN. 
 
 may be built at very moderate expense or if 
 desired made quite elaborate. 
 
 A CATTLE SALE PAVILION. 
 
 The cattle sale pavilion shown in Fig. 91 cost 
 about $1,000. It was built by Stow & Ginrich, 
 proprietors of the Clover Wave Hereford Farm in 
 Iowa. This barn is 60' in diameter and 50' high. 
 The sills are made of boards 1" x 6" green native 
 lumber six boards thick, placed on edge on the 
 foundation, making a sill 6" x 6". The studding 
 is of pine 2" x 6" and 16' long. The girders are 
 1" x 4" native lumber bent around the outside of 
 the studding. The boards are double and put on 
 so as to break the joints. This makes a 2" x 4" 
 girder. The plates are made of 1" x 6" in the 
 same manner; the rafters are of pine 2" x 6" and 
 18' long to purlin plate, which is made of 1" x- 
 6" native lumber. The upper rafters are same 
 length, reaching up to the top plate which forms 
 the base of the cupola. The cupola has 2" x 4" 
 studding 6' long and at the top is another plate 
 made of native lumber 1" x 4". The siding is pine 
 8" boards; the sheathing is l"x3" native lumber 
 except on cupola, which is 1" x 2", so as to bend 
 more easily. About 35,000 shingles were re- 
 quired to cover it. The doors are hung on rollers 
 and are curved the same as the side of the barn. 
 The roof is cone-shaped and is self-supporting. 
 The hay capacity of the mow is 150 tons and the 
 ground floor will accommodate 32 head of large 
 cattle. In the center of the barn is a sale-ring 
 
 PIG. 81— CATTLE SALE PAVILION (ELEVATION). 
 
 FRANCE TOR STOCK 
 
 ^Om- CNTRAN ct 
 
 FIG. 98— CATTLE SALE PAVILION (PLAN). 
 
 floor. The entrance for stock is 6' wide and the 
 front entrance 4' wide. The aisle is 4' wide. 
 Gates opening into the stalls are 4' wide and are 
 made to fasten across the aisle when open for 
 convenience in handling stock. There are 12 
 feed boxes around the circle in the center for that 
 number of large cattle or quite a number of calves 
 could be put in loose. 
 
HORSE BARNS AND STABLES. 
 
 On the farm a general style and principle may 
 be employed in building housing for horses and 
 cattle. Preceding pages in this work may be 
 taken as providing horse shelter for many farms, 
 but when it comes to building stables exclusively 
 designed for horses special plans must be fol- 
 lowed. The ceaseless activity of the horse, young 
 and old, must be reckoned with from first to last 
 and this necessitates a solidity of structure in 
 detail which need not be observed in the erection 
 of ordinary farm buildings. 
 
 A fairly large barn is desirable on account of 
 the economy of construction involved. Box-stalls 
 must be provided for stallions and for mares and 
 foals. The walls of every box should be made 
 so that they slope inward for the first four feet 
 of their height, being at the ground point one 
 foot inside the perpendicular of the wall. This 
 prevents a horse from being cast or rubbing his 
 tail or bruising his hocks. ' Doors from each box 
 should open to the outside. This insures a ready 
 egress for the animals in case of fire and an easy 
 way to clean out the boxes day by day. Once the 
 manure is thrown on the outside it may be drawn 
 away and spread on the grasslands or fields at 
 once and its utmost benefit secured to the farm. 
 A gravel or stone road should be laid entirely 
 around a stable with these outside doors. The 
 inside space of a large barn must necessarily con- 
 tain boxes which cannot open to the outside. 
 These should communicate with large doors by 
 broad alleyways. 
 
 Convenient space should always be reserved on 
 the ground floor for a feed-mixing room and hay 
 may be delivered to the manger in each box di- 
 rectly by chutes or to convenient spots in the 
 alleyways. If each box is equipped with a chute 
 a great waste of hay is almost certain, as the ten- 
 dency will be to save time and work by filling 
 the chute full and allowing the horse to stand to 
 hay all the time. This is one of the most costly 
 and most unnecessary wastes on the American 
 farm. 
 
 Loft-room should be very ample. To this end 
 the open form of construction in the roof has 
 been found to be the most satisfactory. Large 
 bins for keeping grain and bran should also be 
 provided as nearly rat-proof as possible and con- 
 nected with the feed-room below by spouts. In 
 the comb of the roof in large barns there should 
 be a complete system of tracks for hay forks or 
 
 slings, admitting of the filling of the loft from 
 each end. 
 
 Partitions between box-stalls for the first five 
 or six feet from the ground upward must be very 
 strong and substantial. Above this, iron rods %" 
 thick or heavy wire netting should be used. 
 Horses love company and if closely confined but 
 unable to see each other they are likely to get 
 restless and contract the bad habit of pawing. 
 These iron rods should be set top and bottom in 
 oak or other hardwood timber 2" x 4" in size and 
 the edges should always be rounded off with the 
 plane. It seems likely that partitions of concrete 
 will come into great favor. For the mangers iron 
 is preferred by some and wood by others, but 
 when wood is used it will be found that the short 
 and crabbed grain of the dry beech tree is the 
 best. The perpetual gnawing to which most 
 wooden mangers are subjected, chiefly by colts, 
 makes little impression on beech wood. Some 
 prefer to leave nothing in the box at all on which 
 the horse may fix his teeth. A portable feed-box, 
 placed inside the door and removed when 
 the feed is finished, and hay fed on the floor 
 are preferred by many of the best breeders and 
 horsemen of the day, but the feeding of long 
 hay on the floor is wasteful. It is better to pro- 
 vide a manger bound with tin or sheet iron to 
 prevent gnawing. The best flooring for the boxes 
 is a hard clay. 
 
 Light and air are essential in all horse barns. 
 Windows should be easily opened and each one 
 should be fitted with a wire screen so that in 
 summer the flies may be kept out. Doors to the ' 
 outside should be in two parts, the lower half 
 about 5' high and the upper smaller, its place to 
 be taken in hot weather by strong wire screened 
 netting. This must be protected by a frame work 
 of hard wood bars. With windows and doors thus 
 opened and screened, the horses will be cool and 
 comfortable as possible in hot weather. Electric- 
 ally driven fans of course may be installed, but 
 they are not common. 
 
 If the design is to build a barn which may 
 be used partially for breeding horses and also 
 for driving horses, a series of standing stalls 
 should be arranged. These may be floored with 
 pine or other planks for two-thirds of their 
 length, allowing the fore feet to rest on a clay 
 floor. A well-built harness-room fitted with cases, 
 in .which the leather goods may be shut up air- 
 
58 
 
 FARM BUILDINGS. 
 
 tight is desired. The ammonia arising from the 
 stables where horses are kept is very destructive 
 both to leather and the varnish on carriages. For 
 this reason the carriage-house should be shut off 
 from the section in which the horses are kept. 
 Glass doors should be used in the harness cases 
 in order that the condition of the leather may 
 be readily noted. 
 
 Ventilation is one of the essentials in a stable. 
 There must be air shafts from the lower story 
 leading to slatted cupolas on the comb of the 
 roof. If a reasonable amount of attention 
 is paid to the location of the windows and doors 
 there need not be any trouble as to the supply 
 of necessary fresh air, but ample shafts to carry 
 off the heated foul' air must be provided. 
 
 Generally it is well to devote barns to one dis- 
 tinct use or another but very satisfactory com- 
 posite structures may be built. If there are 
 several stallions, usually the most valuable ani- 
 mals on the farm to be cared for, it is best to 
 give them a stable to themselves, and in such a 
 case^ more than in any other, doors should open 
 to the outside. Fire is an ever-present possibility 
 and the horse is the most stupid of all the domes- 
 tic animals when fire is to be fought. The utmost 
 celerity of action is necessary, and any plan of 
 construction which does not coincide with that 
 is faulty. 
 
 The method of watering is rather unimportant 
 so long as the water is pure. Perhaps as good a 
 way as any to water horses is the old-fashioned 
 one of carrying it to them in buckets. A hydrant 
 in the barn or a convenient pump are preferred 
 by many owners to a system of water troughs 
 in the stalls which must be cleansed daily or 
 become foul from the dropping of food in them. 
 A watering trough of cement, galvanized iron or 
 wood, conveniently placed in the stable yard or 
 inside the stable, is perhaps as economical of 
 time and labor as the individual troughs in each 
 stall, when the trouble of keeping the latter clean 
 is considered. Fresh cool water in the summer 
 and tempered water in the winter add much to 
 the comfort and thrift of the horse. Water fresh 
 from a well or hydrant meets both conditions. 
 When horses are watered from an outside trough 
 in winter a tank heater is necessary to keep it free 
 from ice. In all cases the water should be close 
 at hand. 
 
 THE STABLING AT AKLAWN FARM. 
 
 When horses were first kept at Oaklawn 35 
 years ago the big basement barn was the main 
 structure on the premises made so famous by the 
 late Mark W. Dunham, DuPage Co., 111. It is 
 still a central figure. Observe this barn in the 
 diagram showing the stabling o.n this farm. See 
 also the engraving constituting the frontispiece 
 
 of this volume. There are three stories in it — 
 the stone basement filled with box-stalls only, 
 the floor or "show barn" on the ground level 
 also filled with box-stalls, and the loft above for 
 the storage of hay and grain. This barn stretches 
 its length east and west. The barn where the 
 driving horses are kept adjoins it on the west, 
 but that in its width extends some 12' or more 
 to the southward, which can not be seen in the 
 picture. Room is provided in single stalls on the 
 upper ground level for 12 driving horses. Still 
 to the west of this driving barn is the coach house 
 with room for 20 vehicles of all sizes from the 
 barouche to the run-about or single speeding 
 buggy. Above the driving horse barn and the 
 coach house are the lofts where the seedcorn and 
 other similar supplies are stored in winter — a 
 fire being kept in the coach house in cold weather. 
 Below these two divisions are the root-cellars, 
 solid stone walled pits where hundreds of tons 
 of carrots, sugar beets and mangels are stored 
 each fall for the winter consumption of the 600 
 or more horses, young and old, on the farm. 
 
 Observe now the convenience with which the 
 manure is handled from these two barns. The 
 ground-level floor contains the 12 drivers and 
 more stallions in boxes in the show barn. The 
 manure is thrust from properly covered apper- 
 tures in the walls to the ground below on the 
 level of the floor of the basement and is there 
 joined by the manure from the boxes therein. 
 It is all thrown in piles on a stone causeway and 
 removed daily by a teamster whose sole duty it 
 is in and out of season to keep this litter spread 
 out on the grasslands. 
 
 Adjoining the root-cellars on the lower level 
 and stretching at right angles to the basement 
 come the sheds, one story structures, running 
 first from the root-cellar south, then east and 
 then north to meet the "running shed," a vaulted 
 structure 300' long by 120' wide used for showing 
 stallions to customers in cold or stormy weather. 
 This running shed stretches its length east and 
 west and is advantageously used in summer for 
 the storage of grain and hay, loads of sheaf grain 
 or hay over night, or corn fodder in the fall, the 
 only requisite being that it shall be free for 
 showing and exercising in the winter selling 
 season. 
 
 On the opposite side of this big shed and run- 
 ning northward is a row of box-stalls, terminat- 
 ing in a double-stalled bam near the hedge as 
 marked in plat, Fig. 92a. About half-way 'be- 
 tween the running shed and the terminal barn 
 as here described a row of stallion boxes runs east- 
 ward to the west line of Barn No. 5. There are 
 double boxes in this row, the doors facing north 
 and south. The manure from these is thrown 
 m piles at the doors each day and removed almost 
 
HOUSE BABNS AND 8TABLJHS. 
 
 59 
 
 as soon as thrown out. Above all these boxes are 
 lofts for the storage of hay and grain.' 
 
 Barn No. 5 is used altogether for the housing 
 of colts. It stretches again east and west and 
 along its north side there is an alleyway from 
 which feed may be placed in the mangers. The 
 boxes in this very large stable are spacious and 
 hold from three to ten foals or yearlings and 100 
 head may safely be housed in it. Spouts bring 
 oats from large bins in the loft to a feed-room 
 in the extreme west end of the building and 
 hay is run down convenient chutes at intervals 
 throughout its length. No. 6 and the running 
 shed terminate about on a line at their eastmost 
 extremities. A court is formed within the two, 
 the west end being encompassed by the row of 
 boxes and the exercising of horses may be done in 
 this court at anv time. 
 
 grown and fed at Oaklawn, and the excellence 
 of the grain crops on this farm prove the efficacy 
 of this method of utilizing the vkst quantities of 
 horse manure which must be handled each season. 
 In addition, after the fertilizing elements have 
 had due opportunity to be dissolved and sink into 
 the earth, the unrotted straw is carefully raked 
 up again when dry, and carted back to the barns, 
 where it is stacked and made to do duty as bed- 
 ding once more. 
 
 In the second story of No. 6 is a vast amount of 
 hay and grain storage, that portion of the barn 
 having been built with an open center with a 
 view of affording the utmost room for this pur- 
 pose. Large storage of oats and bran is also pro- 
 vided, the necessary bags of these products being 
 swung to their place by means of an ingenious 
 system of ropes and pulleys which enables the 
 
 BLAtKSthlTH 
 
 BAlRN 
 □ 
 
 .No I 6 
 
 I 6 ° 
 
 -Q- 
 
 5HEDS 
 
 RUNNING 
 -a h h- 
 
 SHED 
 
 ^B^N^ 
 
 ^ 
 
 
 "^ W 
 
 JL. 
 
 SHOW 
 
 HOUSE 
 
 [] 
 
 BARN 
 
 □ 
 
 ENGINE 
 
 Q 
 
 BOXES 
 
 BA 
 BA 
 
 NK 
 RN 
 
 -H- 
 
 qBARNq 
 
 ^ 
 
 CARRIAGE 
 HOUSE 
 
 OFFICE 
 
 ROAD 
 
 > 
 2 
 
 GRA53 
 
 PLOT 
 
 CRASS 
 
 ROAD 
 
 FIG. 92a^-GENERAL ARRANGEMENT OTT BARNS AT OAKLAWK. 
 
 The big barn farthest east is No. 6. It is the 
 largest and best barn in Kane county that is 
 devoted exclusively to the keeping of commercial 
 horses. It is 112' long, 62' wide and 54' high ' 
 from sill to peak of roof, the posts being 28' high. 
 Storage capacity for over 400 tons loose hay is 
 afforded. Main timbers are 10" x 12" and 32' 
 long. In it on the ground floor there are box- 
 stalls only with accommodations for something 
 like 28 stallions. All but a very few of the stalls 
 open to the outside and the few in the center have 
 access to the outside by broad alleyways. The 
 manure here is thrown to the outside where hard 
 gravel roads have "been made and, as in all other 
 barns, is removed each day or twice a day as the 
 case may be, to be at once spread on the land 
 most requiring it. The enormous crops of hay 
 
 work to be easily .and quickly done by horse power. 
 Similarly the. hay floor is filled from the wagons 
 by means of slings, harpoons and grip forks, the 
 tracks being laid in the apex of the roof with the 
 object of filling the loft from either or both ends, 
 as the case may be, and at the same time from 
 both if desired. It may be said that this barn 
 was built from plans approved beforehand by the 
 insurance companies with which the risk was 
 placed. 
 
 Directly south of about the middle of the run- 
 ning shed and well down the hill is the black- 
 smith shop, safely removed from both that shed 
 and the single story sheds which run north and 
 south to meet it at its westmost end. In the 
 middle of the quadrangle formed by the root- 
 cellars, the single story sheds and the basement 
 
60 
 
 FABM BUILDINGS. 
 
 barn stands the engine which pumps the water 
 for the entire farm, boils feed, grinds grain, 
 shreds fodder, saws wood and the like. 
 
 In each barn there are several hydrants. The 
 well which is driven in the center of the quad- 
 rangle described grants an abundance of the 
 purest water, which is pumped by the engine to 
 a reservoir back of Oaklawn House on the highest 
 part of the farm. From there the water is dis- 
 tributed to every barn and field by means of 
 pipes sunk 6' to 8' in the ground. The supply 
 is never-failing, but is reinforced by a multi- 
 plicity of windmills and wells in the pastures 
 somewhat remote from the main engine. An- 
 • other well, fitted with a powerful windmill, is 
 placed at the southeast corner of the show barn, 
 as shown in the picture, Pig. 92a, to aid in 
 maintaining a full supply in times of drouth. 
 In addition to supplying the stables and fields 
 with water the engine and main well are also 
 made to supply Oaklawn House and other smaller 
 dwellings on the farm. 
 
 Such is the Oaklawn plant. Its convenience 
 for the purpose for which it is used is beyond 
 criticism. The small barn, where the show and 
 
 are all painted a dark rich red, the trimmings 
 being white. The mares and foals are kept on 
 other parts of the farm which cannot be seen 
 in the engraving to which this refers. 
 
 BARN FOR LIGHT HORSES. 
 
 A very complete and convenient horse barn was 
 built several years ago in Pennsylvania for the 
 stabling of light horses. The diagrams (Figs. 
 93 and 94) afford a capital idea of the front 
 elevation and the ground plan of the structure, 
 which is very handsome in its architecture, 
 economical in its construction and admirable in 
 its arrangement. 
 
 The dimensions and capacity appear in figures 
 on the diagrams. The grooms have very com- 
 fortable steam-heated quarters in the second 
 story, over the harness and wash-rooms, and 
 there is ample reserve room over the left wing 
 of the front of the barn. A feature not shown 
 in the diagram is the half-story over the entire 
 circle of boxes, which affords storage for- a large 
 quantity of hay that can be mowed away and 
 pitched out at various convenient points: Most 
 of the Eastern light horse-breeding establish- 
 
 JISM^ 
 
 m Rffl! 
 
 FIG. 93— BABN FOB LIGHT HORSES (FRONT ELEVATION). 
 
 breeding horses are kept for the most part, is 
 situated by itself and about half way from the 
 double-stalled barn to No. 5. It extends north and 
 south nearly to the main road and is in itself a 
 model for its uses. It has limited hay storage 
 above the boxes and plenty of room for grain, 
 while the appliances for mixing feed on the main 
 flooT are thoroughly modern. 
 
 The same may be said of all the other barns. 
 The object has been in arranging the entire plant 
 to make the steps taken by the- grooms the fewest 
 possible under the circumstances. The hay may be 
 dropped just where wanted and the grain spouted 
 to its place for mixing. The walls of the box- 
 stalls are all fitted with small sliding doors open- 
 ing into the mangers so that the grooms need not 
 enter the boxes when feeding the horses and most 
 of the boxes are also fitted with water troughs 
 into which a supply of water may be turned at 
 will or in which one may be retained permanently 
 by means of ball and float valves. The buildings 
 
 ments are equipped either with stables in which 
 boxes are arranged around a big covered area or 
 else with large riding or training schools, in both 
 of which large and costly roofs are needed. Pro- 
 vision has been made in this case for such a train- 
 ing school without the expense of the roof by 
 allowing the roof of the boxes to project over the 
 ' inner circular court twelve feet, thus affording 
 a covered track under shelter the entire distance 
 around without a single post. The drain-pipes 
 from the eaves are hinged, so that they may be 
 hooked up to the inner side of the roof out of 
 the way, thus giving an arena 119' in diameter, 
 with 12' under cover all around the outer circle. 
 The inner circle on the diagram is an imaginary 
 line, designed to show the distance that the roof 
 projects over the court. The entire court, is laid 
 in rolled cinders and has a slight fall toward the 
 center for drainage. All doors opening onto it 
 may be tightly closed, thus affording as fine a 
 training and exercising arena as could be 
 
HORSE BABJSS AND 8TABLES. 
 
 61 
 
 desired in clear weather, while it must be a very 
 wild day that will interfere with work on the 12' 
 track under shelter. Twenty-eight box-stalls, 
 each 10' x 12', give luxurious quarters to the 
 horses. 
 
 A KENTUCKY 0OAOH AND STALLION 
 BAEN. 
 
 J. B. Haggin's combination coach and stallion 
 barn at the famous Elmendorf farm is in keeping 
 with the substantial buildings "at that great 
 breeding establishment. It is constructed of 
 stone and brick, the upper part of the building 
 being of the latter material, while over all is a 
 tile roof, making the. structure ; as nearly fire- 
 proof as it is possible to make such a building 
 (See Fig. 94a.) 
 
 Mr. Haggin had in mind the great value of his 
 stallions when he ordered the barn built. As a 
 
 stallion barn it is a fairly large structure, the 
 main barn having two wings, one on each side. 
 In both the main structure and the wings are 
 box-stalls for the coach horses and the valuable 
 stallions which form the nucleus of his Thor- 
 oughbred stud. The, partitions between the box- 
 stalls and the main barn are of brick (Pig. 94b) 
 so that no ordinary fire would be able to do any 
 great amount of damage to the animals contained 
 therein. On one, side of the main barn are open 
 stalls for the coach horses. In addition to the 
 doors to the box-stalls from the interior are small 
 windows and on the exterior i of the stalls are 
 windows placed well up. They afford plenty of 
 light while ndt allowing the stallions a view of 
 what is going on outside. v 
 
 In the center of the stallion barn are large 
 ventilators, while the wings are ventilated with 
 circular ventilators made of galvanized iron. In 
 
 PIG. 94— BARN FOB LIGHT HORSES (GROUND PLAN). 
 
62 
 
 FABM BUILDINGS 
 
 JTG. 94a— KENTUCKY COACH AND STALLION BARN (ELEVATION). 
 
 the upper barn is room for the feed, hay and 
 grain. 
 
 As a model of fireproof construction the Hag- 
 gin coach and stallion bam is considered the best 
 around Lexington, Ky. 
 
 A MONTANA HOESE BARN. 
 
 The dimensions of this barn, shown in Pig. 95, 
 are 36' x 84'; posts are 12' apart; two horses are 
 put in a stall; the stalls are 12' wide, facing the 
 sides of the barn. There are several advantages 
 in this arrangement : horses are easily put in and 
 
 taken out, easily groomed, harness may be hung 
 on hooks suspended by pulleys right behind them 
 and drawn up out of the way. Besides with such 
 wide stalls it is easy to put feed in their mangers 
 even when the horses are in place. The trans- 
 verse driveway is to be used only when hay is put 
 in ; at other times it is closed with swinging par- 
 titions and made into two box-stalls, which are 
 very useful in any stable. This stable may be 
 equipped with an overhead track and carrier for 
 taking out the manure. In the mow floor there 
 should be bins for oats or corn, to be spouted 
 
 FIG. 94t> -KENTUCKY COACH AND STALLION BABN (INTERIOR). 
 
HOUSE BABNS AND STABLES. 
 
 63 
 
 down beside the posts, and filled by a horse-hoist 
 from the central driveway. The frame is all 
 joist, ,with a self-supporting curb roof. 
 
 A MODERN STALLION BARN. 
 
 Plans for an admirable barn (Fig. 96) for 
 stallions recently built in Northern Illinois are 
 herewith given. 
 
 The main barn has 18' studding. The lower 
 story is 9' high, covered outside with drop-siding, 
 galvanized iron, molded gutters, red cedar shin- 
 
 wmjOw 
 
 WINDOW 
 
 wn«aw 
 
 
 mrvaw 
 
 ««i W 
 
 WINDOW 
 
 Vtmct» 
 
 
 
 
 
 
 nuwo <t»v 
 BOX3TAU. 
 
 
 •DouslcStau. 
 
 DtXJOLCSTAU. 
 
 8 
 
 
 
 
 
 DRJVf 
 
 i. WAY S 
 
 1 
 
 
 i 
 
 
 ■ 
 
 
 a 
 
 3 
 1 
 
 Vcmuca 
 
 
 
 Dmvt-w4Y 
 Box Stall 
 
 fhXBLcS-nai. 
 
 12 f T. WIDE 
 
 
 . 
 
 
 
 M4NGCP 
 
 
 
 JTG. 95 — MONTANA HORSE BARN (GROUND PLAN). 
 
 gles, lined throughout — the lower 4V2'with2" xl2" 
 dressed lumber, above 4%' with matched fencing. 
 Partitions between stalls are 7' high of 2" x 10" 
 oak the lower 4^', and 2y 2 ' of 2" x 12" hem- 
 lock. Alley partitions are 6' high of 2" x 12" 
 hemlock; wall studding 2"x6"; floor joists 
 2" x 12" ; rafters 2" x 8" ; supporting timbers 
 4" x 6" and 6" x 6". Stall doors are of 1" x 6" 
 matched fencing and double. The wing is one 
 story high, 36' x 110'; it has a row of box-stalls 
 opening into the exercising room. The latter is 
 lighted by windows 3' high, set on upper end of 
 rafters over box-stalls and under the upper end of 
 rafters over exercising room, giving perfect light 
 and ventilation. An office and carriage-room are 
 in main building; men's sleeping room over the 
 office. The stable was built at a cost of about 
 $2,600. 
 
 A HORSE BARN WITHOUT CROSS TIES. 
 
 This horse barn possesses many excellent 
 features, among them being the minimum of 
 
 cost for accommodations secured, economy of 
 space, convenience and healthfulness for the 
 occupants. It is built either with joist or solid- 
 timber frame (Fig. 97), without cross-ties or 
 
 EXERCISlNGj ROOM 
 24 'x lio' 
 
 T 
 
 / 
 
 T 
 
 T 
 
 T 
 
 1 
 
 12X12 
 
 12x12 
 
 12x12' 
 
 12/12 
 
 y 
 
 I2x|2 
 
 y 
 
 12x12 
 
 s_ 
 
 12X12 
 
 s 
 
 12X12 
 
 / 
 
 WflqON SHED 
 
 i^ 
 
 12X12 
 
 12X12 
 
 b^ 
 
 \2t\7 
 
 \\ 
 
 12x12 
 
 ^. 
 
 12x12' 
 
 ^ 
 
 I2'x 12' 
 
 FEED ROOM' 
 
 ib- 
 
 > 
 
 CARRIAGE ROOM 
 
 V 
 
 12X12. 
 
 ^V 
 
 12X12 
 
 ~?7~ 
 
 12*12 
 
 12X12 
 
 7T 77 
 
 12x12 
 
 ~A 
 
 \ii\t 
 
 £ 
 
 I CM 
 
 FIG. 96— A MODERN STALLION BARN 
 
64 
 
 FABM BUILDINGS. 
 
 even purlin plates. The roof is self-supporting, 
 each rafter being so spliced to the one above as to 
 make it virtually one piece and the half of an 
 arch. This arrangement gives ample strength 
 to the roof. 
 
 END ELEVATION or FRAME 
 FIG. 97— HORSE BARN WITHOUT CBOSS-TIES 
 
 firmly in place. At the peak there is the collar- 
 beam 1" x 6", which adds materially to the rigid- 
 ity of the frame. The hay track is put on this 
 collar-beam. No floor is used nor sills, the posts 
 resting directly on stone. 
 
 The floor is of hard earth. The stalls are 
 double, two horses being put in each. Grain (in 
 bins in the second story) is spouted down to each 
 alleyway and hay chutes reach into the feeding- 
 alleys. These chutes should reach up through 
 the mow nearly to the roof, should be 3%' 
 square and open on one side. These chutes form 
 very, efficient ventilators. There is an alleyway 
 (Fig. 98) that gives access to the central passage 
 where horses are harnessed or hitched to the 
 vehicles. There should be a window to the har- 
 ness-room, omitted in the drawing, opposite the 
 one in the alley. 
 
 Ladders through the hay chutes give access 
 to the mow. Hay is taken in at either end 
 through doors arranged so as to allow the use of 
 slings and the taking in of draughts at any 
 desired height, these doors reaching from the 
 peak down to the floor of the mow. This barn 
 
 MAIN LJspcut 
 
 ■ D» 
 
 FEED 
 ALLEY 
 
 HARNESS 
 
 ROOM [ 
 
 ^ 
 
 
 
 FEED 
 ALLEY 
 
 
 1 J 1 ■ L 
 
 I 
 
 
 
 
 I 
 STALL 
 
 
 
 
 
 
 1 
 
 
 
 
 I 
 
 
 OR'OUNO PLAN 40X70 
 FIG. 98— HORSE BARN WITHOUT CROSS-TIES. 
 
 In lieu of cross-ties there are %" iron rods 
 running from the plates at the posts to the joist- 
 bearers below. These keep the sides from spread- 
 ing. The rafters are 2" x 6" and join at the ends 
 by butting together. Below the rafters there is 
 a triangular piece of oak about 2' long cut to fit 
 in the angle. This is firmly nailed. On each 
 side of the joist there is now added a board of 
 some tough wood, 1" x 12", which also is nailed 
 
 could be easily converted into a cattle barn by 
 putting in cattle stalls where the horse stalls are 
 arranged. 
 
 PLAN POE HORSE BARN. 
 
 The plan shown in Fig. 99 is for a barn 
 36' x 60'. It will accommodate fourteen horses. 
 By increasing the length IS' it will accommodate 
 eighteen head. It has two feed-rooms, a safe and 
 
HOUSE EABNS AND STABLES. 
 
 65 
 
 convenient place for harness, two box-stalls and 
 12 open stalls. 
 
 The barn may be sided with 16' stock boards 
 with battens or with shiplap. By making the 
 eaves higher than 16' there will be more room for 
 hay, but a barn of the dimensions given will con- 
 tain all the hay required, as it will hold about 
 40 tons. 
 
 Instead of chutes or the regular mangers to 
 feed hay there is a feedway 3' wide, with per- 
 pendicular sides 3' high from the floor of the 
 stalls, and it is floored on a level with the top of 
 the sill. A feedway like this is better than man- 
 gers or chutes, as it allows a man to pass along 
 the entire length of the barn in front of the 
 horses when feeding; there is absolutely no 
 waste of hay, as the horses stand with their heads 
 
 and driveway. Instead of a harness-room hooks 
 can be put up along the sides of the feed-rooms 
 next to the driveway, which will be found to 
 answer as well as a regular harness-room and 
 more convenient, as it will be more accessible. 
 
 The box-stalls should be sided perpendicularly, 
 inside and out, from floor to ceiling, with hard- 
 pine flooring, except the front, which can be sided 
 up 4' high and left open, unless a stallion is to 
 be kept, in which case the front may be finished 
 out to the ceiling with half-inch rods set four 
 inches apart in the top of the partition or the 
 regular box-stall wire work may be used. No 
 manger should be used in the box-stalls, the hay 
 being fed on the floor. None will be wasted 
 unless more is fed than the animal should have. 
 
 The floor of the hav mow should be not les> 
 
 
 1 H 1 
 
 a 
 
 O 
 
 Oi 5 
 
 6 § 
 
 H 
 
 - £NTfirro ■ 
 
 ' FFEDROOM 
 
 *- 
 
 D 
 
 H H « W ft 
 
 FEED WAY 3 FT. WIDE 
 
 3 
 
 -M H 
 
 
 
 
 5 2 
 
 
 "X 
 
 v 
 
 ^ v. 
 
 V, 
 
 V 
 
 
 
 
 
 
 | 
 
 
 
 BOX 
 
 
 SHED /6X36 
 
 
 
 
 
 
 
 
 
 STALL 
 
 
 
 
 & 
 
 10 $ 
 
 
 
 
 
 
 
 
 
 /2X/2 
 
 
 WHICH CAN BE 
 
 
 
 
 
 
 
 
 
 
 
 
 
 ADDED IF 
 
 
 
 
 
 
 
 
 
 
 
 
 f 
 
 
 DES/RED- 
 
 0) 
 
 MOOKS fOK HARNESS 
 
 
 
 
 
 
 
 Co 
 
 
 
 Co 
 
 
 
 
 K 
 
 
 
 r^ 
 
 
 C5 
 
 
 J* 
 
 
 
 
 
 
 
 (a 
 
 
 
 5 
 
 
 
 
 Si 
 
 DRIVE WAY 12 FT. WIDE. 
 
 
 
 
 ci 
 
 
 o 
 
 
 
 Q 
 
 
 53 
 
 
 * 
 
 
 
 
 
 
 c 
 
 
 Oi 
 
 
 
 % 
 
 
 
 ftOOffS FOB f*Afft*£3S. 
 
 
 
 
 K " 
 
 o. 
 
 
 
 
 
 
 
 
 OPEN 
 
 
 
 
 
 
 
 
 11 
 
 
 
 
 
 STALL 
 
 
 
 
 
 
 
 
 1 
 
 0. h, 
 (0 O 
 
 
 
 
 
 6X9 
 
 
 
 
 BOX 
 
 
 
 
 
 
 
 
 
 
 
 
 3 
 
 ■ D 
 
 STALL 
 
 
 
 
 ft 
 
 J>- 
 
 H < 
 
 D 
 
 \ 
 
 
 ^ 
 
 ^ 
 
 ^ 
 
 A 
 
 \ 
 
 /2X/2 
 
 -HI II 
 
 
 
 
 £H7KY TO . 
 FEE0ROOM 
 It 
 
 — H- 
 
 FEED WAY 3 FT WIDE 
 
 »-■■ ... It H u h 
 
 
 iv w * w 
 
 IMG. 99— PLAN FOB HORSE BABN. 
 
 over the hay while eating and do not pull it out 
 and drop it under their feet, and the chaff is not 
 constantly falling down in their eyes, as when a 
 manger is used that feeds from above. 
 
 The feed-rooms are situated on each side of 
 the driveway and are each divided into two com- 
 partments and an entry so as to allow a variety 
 of feed to be kept and to be easy of access. 
 
 The barn should be lighted with ten windows 
 on each side, two to each box-stall, two to each 
 feed-room and one in front of each -single stall. 
 Common barn sasb should be used, having six 
 8" x 10" panes to each sash, a single sash to each 
 window, with the longest way of the sash up and 
 down. They should be put in on top of the girt, 
 about 4' from the bottom of the sill, and should 
 be arranged to open by sliding to one side. 
 
 Feed-rooms should be sided with hard-pine 
 flooring with the smooth side next to the stalls 
 
 than 9' from the floor of the barn, though 10' or 
 even 12' would be better for sanitary reasons. 
 The mow should be floored solid, except over the 
 feedways, which should be left open to throw 
 feed down. The roof should have from one-third 
 to one-half pitch, and should be self-supporting, 
 so as to do away with all cross-ties in the mow. 
 The driveway can be floored with 2" plank and 
 clay floors used in the stalls, but that and many 
 other minor details must be governed by the 
 individual taste and requirements of the builder. 
 This barn was built for about $1,000. 
 
 A NEBRASKA HOESE BABN. 
 
 It will be seen from the accompanying dia- 
 gram of the ground plan (Fig. 101) that the 
 interior arrangements of this substantially built- 
 stallion barn in the main consist of a wide drive- 
 wav 24' x 152', with a row of boxes on either side. 
 
66 
 
 FABM BUILDINGS. 
 
 ■Hi 
 
 ■ » - fm |n| i fife p > ! ;T|^|jM 
 
 -NEBRASKA HORSE BARN (SIDE ELEVATION). 
 
 This driveway affords a place in which to exercise 
 the horses every day in the year, being of such, 
 dimensions that they may be taken on a gallop 
 if desired from one end to the other — and all 
 horsemen understand the value of such a place 
 when the inclemency of the weather prevents 
 outdoor exercise. 
 
 Another special feature is the construction of 
 the boxes. The partitions between the boxes and 
 abutting on the hall consist of a solid 4" wall of 
 pine, made of 2" x 4" pieces laid like brick, one 
 on top another, with a cap-piece of oak 5' up. 
 Above this for 3%' more there is a grating of 
 gas-pipe %" in size, outside measure, and 4" 
 apart. To provide means of speedy egress in case 
 of fire there is an outside door to every stall. 
 
 The foundation consists of a solid 18" wall 18" 
 deep; piers and interior posts are 18" x 18" and 
 3' deep. The frame is a mortise and tenon; 
 8" x 8" stuff for posts, sills and cross-beams; 
 posts 22' high. The first floor is of earth and the 
 second floor over boxes is matched flooring, and 
 over hall common boards. The joists are 2"xl0" ; 
 16" apart over stalls, 12" apart over hall. Sides 
 5y 2 " patent siding; rafters 2" x 8", 2' apart, with 
 2"x8" ridge-pole; shingle roof, with eaves pro- 
 jecting 24". Stall windows have nine lights and 
 slide to one side. The hall and office windows 
 have twelve lights 10" x 18", and second floor 
 windows have twelve lights 10" x 14". The inside 
 doors are of three thicknesses of %" matched 
 flooring. There is a cellar 9' deep under feed- 
 
 OTG. 101— NEBRASKA HORSB BARN (GROUND PLAN). 
 
HOBSE BABNS AND STABLU8. 
 
 67 
 
 room for carrots. The sides and ceiling of office- 
 room are matched ceiling of pine and in the 
 second-floor room laths and plaster. The large 
 ventilator is 10' x 10' and handsomely propor- 
 tioned. 
 
 Several years ago the cost of this barn was 
 probably between $8,000 and $9,000. Pig. 100 
 shows the elevation. 
 
 THREE-STORY FARM AND HORSE BARN. 
 
 The three-story farm and horse barn shown in 
 Figs. 102, 103 and 104 is 34' wide and 80' long, 
 
 with six double stalls, two single and four large 
 box stalls. Though the basement (Fig. 103) is a 
 cross driveway. Grain is spouted down into 
 small bins at one side of the passage and closets 
 on the other side will be found convenient for 
 harness and stable furniture. 
 
 As this three-storied barn is narrow it was 
 needful to restrain the height as much as is safe 
 to avoid wrong proportion, so each story was 
 built 8' in the clear. With the self-supporting 
 roof ample room for hay storage is secured. Hay 
 
 9 
 
 I. 
 
 MACHINES 
 
 B SLIDING DOORS 
 
 TOOLS 
 3' 
 
 :i 
 
 ■ 
 
 
 tei MIDDLE FLOOa 
 
 S3 
 
 m 
 
 [ 
 
 
 3f X SO 
 £C P 
 
 Foa 
 
 MACHINES 
 AND 
 THRESHED GRAIN 
 
 
 1 
 
 H 
 
 I 
 
 
 LAODEf* HAV 
 [— | CHUTE 
 
 U 
 
 1 
 .1 
 
 J 
 
 GFtAIM 
 BIN 
 
 • 
 
 
 M 
 
 GIRAIN % 
 BIN 
 
 H 
 
 [ 
 
 
 
 
 i 
 
 1 
 f" 
 
 
 i 
 
 Ej 
 
 1 
 
 I 
 
 
 BE 
 
 IL.^... 
 
 J 
 
 PIG. 103 — THREE STOUT FARM AND HORSE BARN. 
 
 FIG. 104— THREE STORY FARM AND HORSE BARN. 
 
68 
 
 FARM BUILDINGS. 
 
 is taken in from outside, though empty wagons 
 may be driven through the second story. To 
 make the drive high enough to take in loads of 
 
 ,,i<^N. 
 
 hay would be a useless extravagance. Hay doors 
 may be put in each end. To take out braces and 
 yet make the center span of joist-bearers strong 
 enough can be done by the wooden truss shown 
 which makes the span unbreakable. 
 
 AN IOWA STALLION BARN. 
 
 The brick stallion barn shown in Fig. 105 was 
 built by Champlin Bros, in Iowa at a cost of 
 $16,100. This barn is built of solid brick and 
 is 140' x 75'. The front elevation shows two 
 stories high, the rear is three stories. (See Fig. 
 
 FIG. 103— THREE STOKY FARM AND HORSE BARN. 
 
 REM ELEVATION 
 
 FIG. 107— IOWA STALLION BARN. 
 
 FIG. 105— IOWA STALLION BARN (FRONT ELEVATION). 
 
HORSE BABNS AND STABLES. 
 
 69 
 
 PIG. 108— BARN FOB FORTY HORSES (SIDE ELEVATION). 
 
 Ctmtq t 
 
 Uxk. 
 
 ■3 
 
 Cross 5ect/on of Stalls. Cinttnt Fla 
 
 A-opan win or iron mor'k or jftiajs 
 
 W. W. . Jl JW k SAJi/ij Z).j 
 
 vBiqs.d&ovox 
 
 Dn/e Way /or 
 
 
 
 s 
 
 - 
 
 
 5 l- 
 
 
 
 
 
 
 
 
 
 
 w: 
 
 gfi Vrm Way /or rfarn«.» «.«•, Bo». 
 
 I I I I— I — J >i fcza 
 
 B<»5t«H 
 
 Box 
 this. 
 
 mam. w — * 
 
 (./I passapt. 
 
 ■Douplc jff'olif f _ 
 j)«or. 
 
 Dnrcmdy Mica 
 
 Unloadiiio; Hay 
 
 'Bins aiovi" 
 
 6// fHtlsafi, 
 
 StatU Mat 
 13* 16. 
 
 JrftT 
 
 5/afl 
 
 FIG. 109— BARN FOR FORTY HORSES. 
 
 /ti//. 
 
70 
 
 FARM BUILDINGS. 
 
 107.) The first and second floors are for horses 
 and the third floor is for hay-mow and grain bins. 
 It has a capacity for 100 horses, there being 40 
 box-stalls and 60 single stalls. The blacksmith 
 shop, heated harness-room, wash-room, robe-room, 
 offices and large space for showing horses are on 
 the first floor (Fig. 106), and a large carriage 
 room is on the second floor. The barn is equipped 
 with an electric motor, which cost $1,000, to run 
 elevator, grind feed, pump water and unload hay 
 and oats. 
 
 BARN FOE 40 HORSES. 
 
 This barn for about 40 horses (see Figs. 108 
 and 109) was erected on a large Kansas farm and 
 has many excellent features. There are stalls for 
 
 architecture has been preserved throughout, pre- 
 senting a very pleasing impression. Plymouth 
 Stud comprises a breeding department, where 
 stallions, mares, foals and young horses receive 
 attention, and a training department, where 
 harness and saddle horses are schooled for the 
 market and for the shows. Good taste rather than 
 lavish outlay has characterized the building of 
 this establishment, and the idea ever foremost has 
 been the utility and sanitation of the stables and 
 the comfort of the men as well as the horses. 
 
 Details are not submitted, but the accompany- 
 ing illustration No. 109a will afford an idea of 
 the equipment of the place in general. Stallion 
 boxes, brood mare boxes, boxes with yards for 
 foals and yearlings, with liberal allowance of room 
 
 FIG. 109a— PLYMOUTH HACKNEY STUD STABLE. 
 
 42 horses and three box-stalls, abundant hay 
 room, harness room and room for stableman. 
 The latter room may be made into a box-stall if 
 preferred. The diagrams show the interior 
 arrangement and exterior appearance of the barn. 
 
 PLYMOUTH HACKNEY STUD STABLES. 
 
 An excellent illustration of the combination of 
 utility and taste which m'ay be obtained in the 
 construction of the stabling on a horse breeding 
 farm is found in the equipment of Plymouth 
 Stud, property of Eben D. Jordan, Chiltonville, 
 Mass., near Plymouth Rock. These buildings rep- 
 resent the accretions of several years, as demands 
 for space multiplied, but the same general style of 
 
 in each instance, constitute the stabling, and com- 
 fortable sleeping and resting quarters for the 
 grooms are also provided. In connection with the 
 stables a commodious riding school has been 
 erected, one of the largest and best lighted to be 
 found at any private establishment in this coun- 
 try. This structure has been very valuable in 
 conditioning horses for the show arena and the 
 market, All the buildings are frame with 
 shingled sides and roofs and are stained lichen- 
 gray. 
 
 BANK STABLE FOR HORSES. 
 
 This building is 36' wide and 52' long, there 
 being two bents of 16' each and for convenience 
 
HORSE BABNS AND STABLER. 
 
 71 
 
 in placing posts two bents of 10' width at the 
 box-stalls. It has a feed alley 6' wide and a wider 
 passage between- the box-stalls. Bins may be 
 above this wider passage with spouts down. 
 Abundant light and air may be provided, as the 
 wall sets back to allow a row of windows on each 
 side. Ventilation also through the hay chutes 
 
 make the structure stronger. The barn has a 
 capacity for 175 to 200 tons of hay. 
 
 A KENTUCKY BARN FOR SPEED 
 HORSES. 
 
 AVhat is considered one of the best barns in 
 Kentucky from a sanitary and practical stand- 
 
 Titd Am, aJi 
 
 £>....«•«- 
 
 inu<iA» 
 
 
 
 
 
 
 
 »l 
 
 
 
 
 L 
 
 ■*"/..- •*•*,„,, 
 
 
 
 J*-* 
 
 
 
 
 V 
 
 FIG. 110— BANK STABLE FOB HOBSES^FBONT ELEVATION). 
 
 will help keep the horses in health. The stalls are 
 5' 4" wide, ,thr v ee to a bent. (See Figs. 110 and 
 111.) 
 
 MeMILLAN'S HORSE BARN. 
 
 A convenient barn for draft horses built by 
 H. G. McMillan on his Iowa farm is shown in 
 
 FIG. Ill— BANK STABLE FOB HORSES (PLAN). 
 
 point is that of L. V. Harkness at the Walnut 
 Hall farm at Donerail, near Lexington. It is 
 an impressive structure on account of its size and 
 on close examination all practical horsemen are 
 taken with it, mainly because of its practical 
 merit. 
 
 FIG. 112— M'MILLAN'S HOBSE BABN (ELEVATION). 
 
 Figs. 112 and 113. The dimensions are 56' x 76'. 
 The engraving (Fig. 112) shows the north end 
 of the barn. On the right extending from the 
 southwest corner of the barn to the west is a 
 shingled roof shed 24' x 48'. On the left extend- 
 ing east from the northeast corner of the 
 barn is another shed 32' x 80'. Both of these 
 sheds open to the south. There is a driveway 
 running north and south and crosswise east to 
 west. The drop roof on both sides gives excellent 
 light in the upper part of the barn, and may also 
 
 The building itself is 400' long by 70' wide. 
 (See Fig. 113a.) It is located on a knoll not 
 far from the track on which the Walnut Hall 
 youngsters are developed for speed and not far 
 from the homestead where Mr. Harkness makes 
 bis home when in Kentucky. The situation is 
 superb, as it insures the best of drainage, an 
 absolute necessity where the stall floors are com- 
 posed of dirt, as is the case at Walnut Hall. 
 
 In the center of the stable from one end to the 
 other is a large runway, large enough so that in 
 
72 
 
 FABM BUILDINGS. 
 
 d„, 
 
 
 Dmrtw/Jrs 
 
 FIG. 113— M'MILLAN'S HORSE BARN (GROUND PLAN). 
 
 stormy weather it is possible to exercise the horses 
 indoors. (Pig. 113b.) This really has all the 
 merits of a covered track — all that is needed 
 indeed for a barn in that section of the country. 
 Exactly in the center of the stable is a section 
 for road carts and sulkies and here also are doors 
 opening from the stable capable of allowing a 
 man in a vehicle to drive out. In this section 
 are cement floors for the washing of the vehicles. 
 On either side of the driveway, which extends 
 the whole length of the barn, are the box-stalls. 
 These are commodious with doors facing on the 
 interior driveway and also doors facing on the 
 exterior, while above are small windows. These 
 exterior doors are constructed so that in case of 
 fire the attendants will be able to liberate all of 
 
 FIG. 113a— A KENTUCKY BARN FOR SPEED HORSES (EXTERIOR VIEW). 
 
 FIG. 113b— A KENTUCKY BARN FOR SPEED HORSES (INTERIOR VIEW). 
 
HORSE BARNS AND STABLES. 
 
 73 
 
 the horses without going into the building. Once 
 out the horses can roam as they please and be 
 captured at will. 
 
 'Above the large box-stalls is limited space for 
 the daily feed of the horses. Evidently Mr. 
 Barkness' idea in constructing the building was 
 to afford plenty of space for air, and in this 
 respect the barn is an admirable pattern. That 
 the idea is all that was intended is best evidenced 
 from the fact that few horses have ever had any 
 sickness in the stables. 
 
 The entire barn is of frame construction and 
 while not elaborate in regard to finish is certainly 
 practical and has every convenience for everyday 
 use. 
 
 AN ILLINOIS STALLION BAEN. 
 
 This stallion barn built a few years ago in 
 Illinois is regarded by many as a model of con- 
 venience, although there is nothing very preten- 
 tious in its architecture, neither is it an expen- 
 sive building. 
 
74 
 
 FARM BUILDIpTOS. 
 
 Fig. 114 represents the south elevation of barn 
 and shed connected with it. Basement with box- 
 stalls and the plan of the yards and distribution 
 of water also are shown in the drawing. (Fig- 
 114.) The barn (40' x 70') is located on the 
 south and near the top of a gentle ridge running 
 east and west. It is constructed partly on the 
 side-hill or basement plan, the north wall being 
 only full height of basement and this wall is all 
 above ground except 3', which gives room for 
 large windows. All other foundation walls are 
 on a level and extend but a few inches above the 
 ground floors, which are of earth in the boxes 
 as well as in the driveway of basement. Founda- 
 tion walls and frame-work of basement corre- 
 spond with the main framework of the building. 
 
 attached to the top of this post, which is swu^g 
 round by the workman as his work proceeds and 
 enables him to form a perfect arch. 
 
 Inch-and-a-quarter gas pipe is laid from cis- 
 tern to hydrant in barn basement and also to 
 yards and pastures as desired. 
 
 The diagram representing stock-waterer (in- 
 cluded in diagram) shows two barrels set side 
 by side, connected by a short piece of gas-pipe, D. 
 The water enters the barrel, A, from the bottom, 
 E, to a height controlled by a float connected by 
 a copper wire to a hinged valve. This allows the 
 water to stand in the barrel to just such a height 
 as desired. As the barrels, A and B, are filled 
 to the same height any water taken from the 
 drinking-tub, C, is quickly replaced. For a 
 
 FIG. 116— CONVENIENT COLT STABLE (EXTERIOR VIEW). 
 
 The framework, consisting of five 14' bents, gives 
 the space of 28' x 40' on each side of the drive- 
 way on the second floor. ■ This driveway is 
 reached from the north side of the building. A 
 stone wall 20' long and parallel with the building, 
 14' distant, gives foundation for a driveway. 
 Against this earth is graded, forming an easy 
 approach to the second floor. 
 
 The reservoir or cistern is located on the high- 
 est ground obtainable, and this not being as high 
 as desired a portion of the arch is built above the 
 natural level and heavily banked with earth. It 
 is bricked up from the bottom with an 8" brick 
 wall laid in cement and the mortar well flushed 
 against the earth bank and finished with a heavy 
 coating of cement on the inside of brickwork. 
 The pipes should be laid at the same time the 
 cistern is built. The diagram shows the manner 
 of constructing the arch. A post is firmly set 
 in the center of the cistern to a height at which 
 the arch is designed to begin. A hinged rod is 
 
 drinking-tub one-half of a beer barrel set in the 
 end of a kerosene barrel may be used. 
 
 CONVENIENT COLT STABLES. 
 
 The colt stable illustrated and described here- 
 with is one of a series built by the late M. W. 
 
 FIG. 115— CONVENIENT COLT STABLE (ARRANGEMENT). 
 
 Dunham at Oaklawn, the noted Illinois horse- 
 breeding establishment. He regarded these 
 
HORSE BARNS AND STABLES. 
 
 75 
 
 FIG. 117— CONVENIENT COLT STABLE WITH PARTITION IN PLACE. 
 
 stables as of especial value with reference to the 
 development of young horses. 
 
 The buildings are situated in line east and 
 west, about 40 rods from building to building. 
 The strip of land used is 60 rods wide. This 
 gives a pasture 20 x 30 rods for each field and 
 each affording abundant pasture for two animals 
 the year round. (See Pig. 116.) Of course in 
 the winter a certain amount of hay is necessary. 
 Each stable contains stall room for eight animals, 
 with the partitions in (Figs. 115 and 117), so 
 that four animals are in the fields and four in 
 the stable alternately. In the summer time the 
 
 doors are left open and are provided with a can- 
 vas fastened at the top, fitting the doorway 
 closely. This excludes the light and protects the 
 animals when in the stable from the flies. In 
 the angle of each stall, which combine to form 
 the center of the stable, is a hydrant to which is 
 attached a float valve (see Fig. 118) which con- 
 trols the supply of water, except in the intense 
 cold weather in the winter when the float valve is 
 removed and the tub filled with water from the 
 hydrant as required. 
 
 The grain is also fed from the center, directly 
 over the water tub. The feed bin is about 6' 
 
 WIO. 1 18— CONVENIENT COLT STABLE WITH PARTITION REMOVED. 
 
76 
 
 FARM BUILJHNOS. 
 
 square and of sufficient height to hold about 200 
 bushels of oats. The bottom of the bin tapers 
 to the center at an angle of about 60° and is 
 closed by a circle of sheet-iron with eight holes 
 of sufficient diameter to hold two quarts of oats, 
 and projects to within 2" of the bottom of the 
 feed trough. Another sheet-iron plate, fastened 
 
 FIG. 119— MULE BARH (END ELEVATION). 
 
 in the center, with holes corresponding to the 
 pipes, is placed flat upon its top surface, to which 
 is riveted a lever. The slot in which this lever 
 works is long enough to allow the opening and 
 closing of the holes in the lower plate by the 
 movement of the lever. By this device the move- 
 ment of the lever permits the filling of the pipes 
 
 slow feeding, consequently better mastication. 
 The fences enclosing the pastures are T high, the 
 upper 2' being made of woven wire. 
 
 The necessity for natural development of 
 young horses in the open air and on green feed 
 in order to secure the highest usefulness when 
 grown led Mr. Dunham for many years to pas- 
 ture his young stallions in the summer; and the 
 losses incurred by accident where 'numbers were 
 kept together prompted the devising of the plan 
 just described. 
 
 Mr. Dunham found the use of these buildings 
 and pastures of great advantage. Where the ani- 
 mals are put in in a healthy condition there is 
 almost entire immunity from disease. By this 
 means health and natural growth are secured and 
 accidents and unsoundness are rare. 
 
 A MULE, BAKK 
 
 As a type of special-purpose building the mule 
 barn shown in the accompanying illustration, 
 Fig. 119, is admirable in its way. It is designed 
 for about 165 mules and the arrangement is com- 
 mendable. The mules are fed, watered, harnessed 
 and taken out without interfering with each 
 other. The sanitation is excellent; the light is 
 ample ; the provision for aeration is sufficient and 
 there is ample warmth in cold weather. 
 
 FLOOR PLAN OF BARN B4X 100 
 TIG. 120— MULE BARN. 
 
 with oats and the reversal shuts off the supply, 
 giving each animal two quarts, or any quantity 
 the pipes are made to hold — the grain filling the 
 pipes— and is eaten from the bottom. This 
 method of feeding has the advantage of rapidity, 
 uniform quantity, prevents waste and secures 
 
 As the barn is quite wide three carriages and 
 three tracks are used in filling it with hay. This 
 saves a great deal of hand labor in moving away 
 the hay. The floor plan (Fig. 120) explains 
 itself. Painted neatly this barn presents a very 
 attractive appearance. 
 
DAIRY BARNS. 
 
 The dairy barn shown in Figs. 121 and 122 
 was built in Southern Illinois by the late H. L. 
 Borden. It is a frame structure on stone piers 
 from 1' to 2' off the ground. It is used as a cow 
 stable and has a loft overhead for hay, which is 
 elevated by hay slings in the center of the barn. 
 The cow stable consists of two rows of stalls (see 
 Fig. 123) with some box-stalls. Each single cow 
 stall is 5' wide. The passageway behind the cows 
 
 eighty cows and ten horses and which would per- 
 mit of driving behind the cattle in cleaning and 
 in front of them in feeding green fodder. A silo, 
 a granary and storage place for dry fodder suffi- 
 cient for all the animals were desired, and the 
 whole was to be covered by the same roof, to be 
 conveniently accessible in all its parts, but not 
 very expensive. 
 
 The plan in several fundamental features 
 
 FIG. 121— ILLINOIS DAIRY BARN (ELEVATION). 
 
 is wide enough to allow the passage of a two- 
 horse manure spreader, which saves the handling 
 of the manure very often. The barn cost about 
 $2,400. 
 
 A BOUND DAIRY BARN. 
 
 The accompanying plan of barn for a dairy 
 farm was designed some years ago by Prof. F. 
 H. King for a Wisconsin dairyman. The design 
 was the result of a request for a plan of a barn 
 for a dairy farm which would accommodate 
 
 embodies ideas which are believed to be worthy 
 of general imitation: 
 
 1. Whatever other advantages or disadvan- 
 tages a shelter for live stock possesses, it should 
 in no way interfere with the best performance of 
 the animals housed. 
 
 2. The shelter should so be built that the heat 
 necessarily given off by the bodies of animals 
 housed shall be sufficient to maintain the best 
 stable temperature during cold weather and at 
 the same time admit of ample ventilation, while 
 
78 
 
 FABM BUILDINGS. 
 
 during warm weather the surplus heat may 
 readily escape. 
 
 3. The construction should be such as to admit 
 the needed amount of light to all the animals 
 housed. 
 
 4. The construction of the shelter should be 
 such as to reduce the labor of caring for the ani- 
 mals, to the smallest amount which will admit of 
 the largest yearly net profit. 
 
 capacity of 14,126 cubic feet, occupies the cen- 
 ter. Around this silo in the first story 98 
 adult cows are accommodated in two circular 
 rows facing a common feeding alley 9' wide, and 
 behind each row of cattle is a wagon drive 6' wide 
 for cleaning the barn, which leaves and returns 
 to the common single broad entrance. 
 
 Extending entirely around the silo in the 
 second story is a barn floor 18' wide, from the 
 
 TIG. 1 aS— ILLINOIS DAIRY BARN (CONSTRUCTION). 
 
 5. The form and arrangement of the buildings 
 should be such as to necessitate the least first cost 
 and the smallest maintenance expense compatible 
 with the necessary accommodations. 
 
 Pigs. 124 and 125 are birdseye views of the 
 interiors of the first and second stories designed 
 to show the construction of the barn and the 
 
 outer edge of which, through chutes leading to 
 the feeding alley in front of the cattle, green 
 fodder can be delivered to them from the wagon 
 or dry fodder from the storage space above. This 
 floor also permits of driving around the silo and 
 out at the entrance after unloading, even when 
 the silage cutter is being run to fill the silo. 
 
 i — u u - ■ u * — s a u u 
 
 I 
 
 . \ \ \ «' 
 
 
 SMIL 
 
 D8 
 
 00 
 
 DO 
 
 10 DO 
 
 V 
 
 ID 
 
 DO 
 
 01 
 
 ID 
 
 mi air re" » 
 
 cmr PEN ~ 
 
 BOLL PEN 
 
 DO 
 
 DO 
 
 
 , ! 
 
 1 
 
 1 
 
 1 
 
 III 
 
 1 
 
 1 
 
 1 1 
 
 1 
 
 1 1 1 1 I 1 1 
 
 1 1 
 
 1 II .. 
 
 1 1 1 
 
 1 II r 
 
 
 I DRIVING FLOOR I2I'L0N(J!(I2-W 
 
 o 
 
 ! L 
 
 STALL 
 
 I 
 DO 
 
 1 
 DO 
 
 1 
 DO 
 
 DO DO. 
 
 
 DO 
 
 — L 
 00 
 
 1 
 DO 
 
 1 
 DO 
 
 I 
 w 
 
 GMFPEN 
 
 1 1 
 
 DO. 
 
 1 1 
 
 CALF PEN 
 
 1 U 
 
 BULLPEN 
 
 1 U 
 
 DO 
 
 1 U * 
 
 DO 
 
 s 
 
 IS 
 
 n n n n _u □. . D 
 
 / f / \ 
 
 
 JIG. 133-ILLINOIS DAIRY BARN (GROUND PLAN). 
 
 arrangement of its interior. It will be seen that 
 in form the barn is cylindrical, covered with a 
 conical roof, which is surmounted by a cupola 
 of the same form. The barn is 92' in diameter 
 and 28' from sills to eaves. A cylindrical silo 
 24' outside diameter and 34' deep, having a 
 
 On the outside of the barn floor, on the right 
 of the entrance, is stable room for ten horses, 
 16' from front to rear, 34' frontage on the barn 
 floor and 55' from end to end at the outside. On 
 the left of the main entrance is a workshop and 
 granary whose combined floor space equals that 
 
JDAIBY BABNS 
 
 79 
 
 occupied by the horses. In the rear of the silo 
 i& a space 16' deep for farm tools, having 32' 
 frontage on the barn floor and possessing a floor 
 . space equal to 16 x 40 square feet. Between 
 the tool-room and the horse barn on one side and 
 the granary on the other.- are two hay bays which, 
 together with the space above the barn floor, tool- 
 room, granary and horse barn, furnish ample 
 storage space for dry fodder. 
 
 The siiage is delivered to the cattle barn from 
 the silo through a triangular chute shown in Fig. 
 124, extending up the inside of the silo ; in one 
 side of this chute there are doors and attached 
 to the other is a fixed ladder by which any desired 
 level in the silo may be reached. 
 
 The foundation of this barn consists of four 
 
 FIG. 124— A ROUND DAIRY BARN (FIRST FLOOR). 
 
 concentric stone walls, the inner one carrying the 
 walls of the silo and through them the central 
 portion of the floors and roof; the two middle 
 ones carrying the stationary uprights of the 
 stanchions, and through them the floor, main 
 posts, purlin plates and roof, while the outer 
 one supports the walls of the structure. The 
 laying of the walls to a circle and leveling them 
 was a simple matter and accomplished with the 
 aid of a straight-edge, one end of which was fixed 
 to a post in the center, with the lower edge at the 
 level desired for the top of the walls. The mov- 
 able end of the straight-edge rested on a ring of 
 boards tacked to stakes driven in the ground 
 outside the wall being built. The inner wall was 
 first built and the straight-edge lengthened as 
 necessary. The frame of the barn consists almost 
 wholly of 2" stock and the only long timbers are 
 the eleven posts carrying the purlin plates. No 
 mortise and tenon work was used in its construc- 
 tion, all work being done with the hammer and 
 saw. The first story sills of the barn are single 
 2" x 10" plank sawed in 4' sections and bedded 
 in mortar on the walls, the sections having heen 
 sawed on a bevel determined by the direction of 
 the radii of the barn. On the sills 2" x 10" studs 
 are set 2' apart and constitute the outer frame 
 of the basement; 2" x 12" studs set flatwise on 
 the two middle walls, at the right distance apart 
 
 to serve as the uprights of the stanchions, and 
 2" x 12" studs in the walk of the silo, as shown 
 in Fig. 124, constitute the vertical supports for 
 the second story. The sills of the second story 
 consist of short pieces of 2" x 10" plank spiked 
 down upon the ends of the three outer circles of 
 studding, as shown in Fig. 124, and of three 
 thicknesses of 6" boards bent around the upper 
 ends of the silo studding and resting on the 
 shoulders sawed for them. Two thicknesses of 
 plank rest on the stanchion supports, but the 
 outer sill is single ; upon these 2" x 10" joists are 
 distributed, as shown at 5, Fig. 124, and these 
 carry the floor of the second story. 
 
 Each of the posts carrying the purlin plates 
 rests on four 2" x 10" joists spiked together and 
 ■ resting on the sills carried by the two rows of 
 stanchions, the particular stanchion uprights 
 where these posts come being strengthened by 
 2" x 6" studding spiked to them at the edge not 
 occupied by the cows. On the tops of these posts 
 short pieces of 2" x 10" plank are spiked, as 
 shown at 1, 1, 1, Fig. 125, and upon them the 
 purlin plates rest, spikes being driven upward 
 into them to hold them in place. 
 
 The rafters and studding for the second story 
 are 2" x 6" stuff, the latter being set 3' apart, 
 and the lower ends of the rafters are carried by 
 
 FIG. 125— A ROUND DAIRT BARN (SECOND FLOOR). 
 
 two layers of 2" x 6" pieces spiked to the tops of 
 the studding, the upper layer breaking joints 
 with the lower. Fig. 125 shows the manner of 
 placing the rafters. 
 
 The rafters were cut so that their ends when 
 in place were vertical and the fascia was formed 
 by springing a board to them. The lower one or 
 two rows of roof board were sawed in short sec- 
 tions, reaching from rafter to rafter, and then 
 fencing was used, full length, and sprung to the 
 rafters over the remainder of the roof. It was 
 not necessary to cut shingles in laying, except 
 on the cupola, and in laying them each man was 
 provided with a "horse," made by driving spikes 
 
80 
 
 FARM BUILDINGS. 
 
 through one edge of a short piece of 2" plank, 
 which served as legs and prevented sliding. A 
 mark was filed in the edge of the shingling 
 hatchet at a distance from the nailing face equal 
 to that which the shingles were laid to the 
 weather, and this served as the only guide in 
 placing them, which was done rapidly and 
 readily, the men following one another round and 
 round. 
 
 This barn is covered outside with drop siding 
 sprung and nailed to the studding so as to break 
 joints, and on the inside of the cattle barn, horse 
 barn and granary with shiplap. 
 
 In the construction of the silo, 2" x 6" stud- 
 ding were used above the basement, these being 
 spiked side by side to form the eleven long ones, 
 which extend to and help support the roof. The 
 lining of the silo consists of three layers of half- 
 inch lumber, formed by ripping common fencing 
 in two, and between these are two layers of tarred 
 paper. The same kind of lumber forms the outer 
 covering of the silo and the spaces between the 
 studding act as ventilating flues for the cattle 
 barn. 
 
 The large doors slide open and are made of 
 matched fencing nailed to cleats having the same 
 curvature as the sides of the barn. These cleate 
 are made by springing the boards into the desired 
 curvature and then fastening them securely 
 together while in that attitude. When this is 
 done they remain bent as if they had grown in 
 that form. 
 
 The feeding mangers in the cattle barns are 
 made by forming the earth in the shape of shal- 
 low, round-bottomed troughs in front of each 
 row of cattle, raising the earth between them 
 into a broad rounded ridge. This earth after 
 being thoroughly firmed was plastered with a coat 
 of water lime. 
 
 When it is known that air once breathed, unless 
 diluted with that which is fresh, cannot support 
 higher animal life; that one-fifth of the weight 
 of materials taken into our bodies daily is oxygen 
 from the air, and that we must breathe 346 cubic 
 feet of air to get it; that on the average our live 
 stock consumes more air per capita than we do, 
 and that horses have died from suffocation while 
 being shipped in box cars, it should be evident 
 that, coupled with our efforts to secure warm 
 barns there should also be those to provide ample 
 ventilation. The plan here described possesses 
 a very simple, cheap and effective method. It 
 will be seen from Figs. 124 and 125 that the 
 32 spaces between the studs in the walls of the 
 silo, being open at the floor of the cattle barn 
 find also at the top, constitute so many ventilat- 
 ing flues, each 34' in length. The heat given 
 to these flues by the silage in the silo, the warm- 
 ing of the air in the basement by the cattle, and 
 
 the suction produced by the wind blowing 
 through and around the cupola, all combine to 
 maintain a strong current of air out of the barn 
 through the cupola and in through the 
 gangs of auger holes in the outer walls 
 
 FIG. 126 — A BARN FOR DAIRY COWS. 
 
 shown at 2, 2 in Pig. 124. It will be seen 
 from the arrows in the cut that provision is'made 
 for fresh air to enter the barn from all sides, 
 which, rising between the studding and flowing 
 along the space between the joists, falls between 
 the two rows of cattle, but is first mingled with 
 the warmest air of the barn, while the coldest and 
 most impure air is constantly drawn out from 
 along the floor. A very important feature in this 
 method of ventilation is that pure air comes 
 
 END ELEVATION 
 
 FIG. 127— A BARN FOR DAIRY COWS. 
 
 direct to all animals alike, while the impure air 
 is drawn out in a uniform sheet all around the 
 silo. It will be seen that this ventilation is secured 
 without sensibly affecting the cost of the build- 
 ing, while at the same time the walls of the silo 
 are kept dry and thereby protected from decay. 
 The temperature of a barn whose plan of ven- 
 tilation is the one here described is under as good 
 
DAISY BABNS. 
 
 81 
 
 control as is possible where artificial heat is not 
 employed, because the cold air is introduced at 
 the warmest part of the barn, while it is the 
 coldest and most vitiated air in the barn which 
 
 INTCfUOR 8CNT OF wINCS JOIST fRAMC 
 
 FIG. 128— A BARN FOE DAIRY COW5. 
 
 is being removed. Then when the barn is too 
 warm the doors to the feed chutes may be opened, 
 thus providing a direct escape of the over-heated 
 air from the ceiling. 
 
 This barn was built for a little less than $2,400. 
 By combining everything under the single roof, 
 by adopting the cylindrical form, which requires 
 
 FIG. 129— A BARN FOR DAIRY COWS. 
 
 the smallest amount of siding, roofing and paint, 
 and which admits of the cheapest and least lum- 
 ber for the frame, and by distributing the lumber 
 so as to make it perform two or more func- 
 tions a great deal of economy was secured in this 
 barn. 
 
 Another advantage which the consolidated 
 barn possesses over several small, scattered struc- 
 tures, and especially where the feeding is done 
 from a central point, as it is in the plan in ques- 
 tion, is the large saving of time which it makes 
 possible in feeding and caring for the animals. 
 
 The great economy of the circular plan for 
 farm buildings over other types of structure 
 diminishes as the size of the building decreases, 
 but it is nevertheless well adapted to some of the 
 smaller structures, such as horse barns and sheep 
 barns. In any case where an octagonal barn is 
 desired the circular type will always be found 
 cheaper and more stable. 
 
 Where a silo is to stand separate from other 
 buildings there is no other type of structure which 
 can be built so cheaply as the circular one, even 
 if its diameter is not greater than 12' x 16'. 
 
 A BARN FOR DAIRY COWS. 
 
 This barn is designed for 20 dairy cows- It 
 has ample breathing space for them and provision 
 is made for as much light and sun as possible, 
 unless the plan of detached shed with sky-lights 
 is adopted; the manure is removed at the mini- 
 mum of labor and the entire building is planned 
 to be labor-saving. The little room termed an 
 
 TEED AlLCr ♦■*! 
 
 
 M 
 
 IOCSL BAflN 3t.it 
 
 FIG. 130— A BARN FOR DAIRY COWS. 
 
 office, containing lavatory, towels, soap, records 
 and the like, is possibly larger than is needed 
 and in that case it may be narrowed to a smaller 
 limit and another stall or two made of the room. 
 The feed-room is a convenience that no dairyman 
 can afford to do without. Peed is stored in three 
 or more bins above and spouted down to one large 
 mixing bin, where it is measured or weighed, 
 mixed, scooped up and fed. 
 
 Reference to the side elevation, Fig. 126, shows 
 the window-openings on the south side (turning 
 the building east and west). The over-hang is to 
 protect the door-way where hay is taken in at 
 the end, as there is no space wasted in drive- 
 ways to unload hay. Fig. 127 shows the end 
 elevation, and in the gable is noted a combination 
 of window and ventilated shutter that looks well 
 and acts well. Providing these at each end there 
 is no need of ventilators in the roof, as ventila- 
 tion will be upward through the hay-chutes. 
 These may if desired be extended through the 
 roof, though if metallic shingles are not used 
 (which condense vapors) there is no ill effect in 
 
82 
 
 FARM BUILDINGS. 
 
 letting the ventilation proceed through the 
 gables. ,The doors to take in hay open down to 
 the line of the floor so that hay may be taken 
 in without raising it to the level of the track. 
 This is an open-center building, with joist-frame 
 construction, as shown in Fig. 128. The frame 
 is all of 2" stuff, is very much cheaper, fully as 
 strong and in every way more desirable than the 
 old-fashioned frame. It is put together with 
 spikes and bolts in a very short time. The base- 
 ment is made 10' high, not for the sake of head- 
 room so much as for better air and light. 
 
 Pig. 129 illustrates the mow plan; hay is 
 thrown down into the feed-alleys ; ladders should 
 
 take the manure away. In the, space between the 
 feed-room and office the milk-wagon may stand 
 if necessary. The VanNorman stall is used. 
 ' This barn is adapted to either beef cattle or 
 dairy cows, though there is no provision for 
 calves, as it was designed- primarily for milking 
 cows. 
 
 A HYGIENIC DAIEY BAEN\ 
 
 After studying for many years to learn the 
 best way to fasten cattle in a barn a great many 
 dairymen have, come to believe that the best way 
 is not to fasten the animals at all. A good plan 
 is to have a large open shed to which light and 
 
 FLEVA-inN 
 FIG. 131— A HYGIENIC DAIRY BARN. 
 
 be built in the chutes. The stairway is apt to be 
 covered over at times with hay. The bran bin is 
 large enough to allow storage of a great deal of 
 bran. 
 
 Fig. 130 shows the arrangement of stalls. It 
 will be noted that there is everywhere plenty of 
 room. The cart can go between the cows and 
 
 air have free access and in which are feed-racks 
 and troughs. This shed should be kept well 
 bedded and aired. The cows, loose and dehorned, 
 stand in it day and night. Adjoining this shed 
 as planned is a small stable fitted with stalls and 
 stanchions where some grain is fed and the milk- 
 ing done. The cows are in their stalls only while 
 
 CATTLE SHED 40X100 
 
 WTO C ~\ 
 
 GROUNO PLAN 
 
 or 
 
 HYOENIC DAIRY BARN 
 
 ENCLOSURE 42X100 
 
 FIG. 133— A HYGIENIC DAIRY BARN. 
 
DAIRY BABNS. 
 
 83 
 
 they eat and are being milked. The barn should 
 be white-washed two or three times a year by 
 means of a sprayer that reaches every nook and 
 crack and the floor kept clean. Pigs. 131, 132 
 
 FRAME Or CATTLE SHED 
 FIG. 133— A HYGIENIC DAIBT BARN. 
 
 and 133 show the plan quite clearly. The barn 
 is well ventilated and convenient in arrangement. 
 Three silos are shown in Fig. 132. No provision 
 is made for storing hay. 
 
 A NEBRASKA DAIEY BARN. 
 
 The Nebraska dairy barn illustrated in Fig. 
 134 was erected in 1896 to house a herd of Jer- 
 seys. The floor plan and dimensions are shown 
 in Fig. 135. The cows stand in the south L, 
 which is protected by the north L from the winter 
 
 winds. The two Ls are the same size — each 
 30' x 48', 8' posts. The barn is floored upstairs 
 as well as down (except the space occupied by 
 silos), and cows stand high and dry 3' to 6' above 
 the ground, and there is a window for every two 
 cows. The latter stand in two rows facing in on 
 a feeding alley and are tied with halters. The 
 floor of the manger is level with the feeding alley 
 and for convenience in cleaning the manger is 
 open in front. 
 
 There are two thicknesses of boards on all 
 sides, keeping the temperature even and above 
 
 FIG. 134— A NEBRASKA DAIBT BABN (FRONT VIEW). 
 
 the freezing point. The silos extend 10' below 
 the floor and up into the loft, making them about 
 20' deep. The silos and the separator-room have 
 a thickness of building paper between the boards. 
 With a separator at the barn only the cream is 
 taken to the dairy-house and the skimmilk is fed 
 warm to the calves and pigs. The barn has a root 
 
 
 
 
 i- ~ 
 
 
 _ — 
 
 30 
 
 
 " - > 
 
 
 «.*- ' - - - - --> 
 
 £«■* Stall 
 
 
 1 
 
 fia - £Xa\\ 
 
 
 ? 
 
 
 
 sr . 
 
 " '* 
 v \. 
 
 *■*-• 
 
 ■r V, 
 03 V 
 
 ■ L 
 
 
 
 1 ' 
 
 I 
 1 
 
 1 
 
 . 1 
 
 1 
 
 1 l*_ 
 
 I 1 a 
 
 Silo 
 
 
 8" DnP 
 
 2." - D %. t P. 
 
 1 
 
 ] 
 
 (¥- >"■> 
 
 1 
 
 n 
 — j 
 
 
 r 
 
 
 
 "* 
 
 
 
 
 
 ri 
 
 
 i T ' y"> 
 
 J _! 
 
 H 
 
 
 
 
 
 
 
 
 
 
 
 
 * 
 
 
 ■ 
 i 
 
 1 
 
 1 
 
 
 
 
 
 
 
 
 
 '*3 
 
 
 
 
 
 ' 
 
 
 
 
 
 
 
 
 i- 3'-' 
 
 
 
 
 ' 
 
 
 , G u -tt* v - 
 
 /' vx\ a.x. 
 
 
 % 
 
 a 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 to 
 
 ,'^ 
 fff/ 
 
 -J 
 
 - Box Stall 
 f-g"x 9-b | 
 
 1 i r=L 
 
 FIG. 135— A NEBRASKA DAIBT BARN (GROUND PLAN). 
 
 J° 
 
84 
 
 FARM BUILDINGS. 
 
 cellar under the south end and cost $1,300. It 
 will accommodate a dairy herd of about 30 cows. 
 
 A PENNSYLVANIA DAIEY BAKN. 
 
 A very complete, elaborate and convenient barn 
 (Figs. 136 and 137) for dairy cattle is thus 
 described by the proprietors: 
 
 TIG. 136— A PENNSYLVANIA DAIRY BARN (SECTION A B). 
 
 "Our barn is a polygon of 16 sides. It is 
 believed that nothing has been neglected which 
 would add to the comfort or healthfulness of the 
 herd. The barn is heated by steam and in win- 
 ter a uniform temperature of from 40 to 45° F. 
 is maintained night and day, never colder than 
 
 PIG. 137— A PENNSYLVANIA DAIRY BARN (ELEVATION). 
 
 40°, never warmer than 45°. Self-registering 
 thermometers in locked cases show at all times 
 any variation from this temperature. The aim 
 is to maintain a temperature just above the 
 freezing point. 
 
 "More attention to proper ventilation has been 
 paid than to all else. The barn is surmounted 
 by a cupola 20' in diameter. This is open every 
 
 day and night in the year. The lower sash of 
 each window is raised 8" and a board placed 
 under the sash. A hole 6" in diameter is cut 
 through this board in which is placed a zinc pipe 
 opening outwardly and turned up on the inside 
 some 3' in height. This allows for the admission 
 of air between the two window sashes and also of 
 a full current of air through the 6" pipe, thus 
 
 PIG. 138— A PENNSYLVANIA DAIRY BARN (BASEMENT PLAN). 
 
 preventing any possibility of a current of air 
 striking directly upon the animals. By this 
 arrangement, no matter what the weather may 
 be, a full supply of pure fresh air is given to 
 every animal by the current from the lower floor 
 passing up the stairway in the center of the barn, 
 
 PIG. 139— A PENNSYLVANIA DADJY BARN (SECOND FLOOR PLAN). 
 
 and also through two chutes extending from the 
 lower floor well up toward the roof. 
 
 "The basement (Fig. 138) of the stable is 
 devoted mainly to the milking cows. It is laid 
 with concrete. Gutters covered with iron grat- 
 ings extend back of the cows and terminate in a 
 sewer which leads 100 rods away from the stable. 
 This floor can be scalded out with hot water, the 
 
DA1BY BABNS. 
 
 85 
 
 gutters and sewers flushed and the cattle put back 
 in the barn on a dry floor in an hour's time. 
 
 "The first floor (Fig. 140) is of two thicknesses 
 of matched yellow pine with tarred paper between 
 
 FIG. 140— A PENNSYLVANIA DAIRY BARN (FIRST FLOOR PLAN). 
 
 the layers. Sawdust is used for bedding on this 
 floor, which is devoted mainly to box-stalls, both 
 open and tight, for the service bulls and for cows 
 soon to calve. 
 
 "The second-floor space (Fig. 139) is devoted 
 to storage for fodder, grain and bedding and also 
 for power cutter, which cuts one ton of dry corn- 
 fodder into one-third inch lengths in 25 minutes. 
 
 "The barn is lighted by 60 incandescent elec- 
 tric lamps. A night watchman is employed who, 
 at intervals of every half -hour, makes a complete 
 tour of the stable, seeing that all is well, a touch 
 of the button enabling him at any time to notify 
 the superintendent of anything wrong. To 
 insure the watchman's wakefulness and attention 
 to duty an electric time detector is in use which 
 keeps perfect record of his movements through 
 the barn." 
 
 A WISCONSIN DAIRY BARN. 
 
 The barn shown in Fig. 141 was built by A. 
 Dutton & Son in 1896 ; It is 60' in diameter 
 and built on a southern slope with a basement 
 for stock. Stone was used on the hill side; the 
 rest is built the same as the upper part.. The 
 studs are 2' apart; it is sided with drop ^siding 
 and sealed on the inside. The basement floor is 
 made of cement. There are 20 patent sta£ls and 
 room for 15 head of young cattle, six horses and 
 a box-stall. There is a silo in the center 16' in 
 
 FIG. 141— A WISCONSIN DAIRY BARN. 
 
 "In a room on this floor is placed the cream 
 separator and engine. On this floor is also a 
 cleaning machine, which by a system of revolv- 
 ing brushes cleans a cow perfectly in from three 
 to five minutes' time. During the winter months 
 each cow receives a daily cleaning, three men 
 being able by this method to thoroughly clean 
 160 head per day. 
 
 diameter and 34' deep. It will hold 150 tons of 
 silage. The studs above the basement are 20' 
 high; this, makes the barn 28' high to eaves. 
 There is room for 70 tons of hay. A hay-carrier 
 is used on a circle track. On each side of the 
 driveway there is granary room for 2,000 bushels 
 of oats and a carload of, bran. The silo is filled 
 from the upper floor.. 
 
SWINE BARNS AND HOUSES. 
 
 What would be the business future of the 
 swine breeder whose hogs were compelled to be 
 exposed to the cold blasts of winter or the glaring 
 sun of summer ? What would their condition be 
 if they were obliged to eat and sleep in filth? 
 What would the pig crop be if the sows were 
 allowed to farrow in the fence corner some cold 
 stormy night with only the canopy of heaven 
 to shelter them ? Answers to these questions will 
 urge the proper equipment of the farm for the 
 breeding of pure-bred swine. How extensive the 
 equipment should be will depend of course on 
 the number of animals to be carried on the farm 
 and the amount of money to be invested. 
 
 First a swine breeder should have necessary 
 buildings for housing the herd, the feed, the 
 apparatus for mixing and preparing the feed and 
 the procuring of the necessary water. There are 
 many kinds of buildings for this purpose, many 
 of which are satisfactory. Breeders have dif- 
 ferent ideas regarding this matter, many pre- 
 ferring the large gloomy hoghouse or building 
 where the whole herd may be kept under one roof, 
 and where the bedding, feed, water and every- 
 thing pertaining to the comfort of the animals 
 may be kept convenient and used with the least 
 labor, and where all the work in oaring for the 
 herd may be done under cover. This plan has 
 many advantages and where adopted the build- 
 ings should be so arranged that as much sunlight 
 as possible may be admitted to the pens and feed- 
 ing floors. There are other breeders who prefer 
 the outdoor individual house large enough for 
 only one sow and her litter, with a grass lot of 
 at least one-half acre where the sow and pigs may 
 always be by themselves. This latter plan will 
 of course occupy considerable land, at least where 
 the herd is large, and will necessitate consider- 
 able fencing into lots along either side of a lane 
 and the hauling of all the feed to the different 
 lots at each feeding time. But this plan insures 
 both abundant pasture for the sow and litter as 
 well as plenty of room for the necessary exercise 
 and has the advantage of always affording clean 
 quarters for the hogs. 
 
 There are many different plans for both the 
 large houses and small individual houses, from 
 which may be selected whatever best pleases the 
 breeder. As much or little expense may be put 
 
 into the building of hoghouses as the breeder 
 desires. 
 
 All buildings used for breeding and feeding 
 swine should be strongly built and made of good 
 material, and all should have floors both for feed- 
 ing and sleeping apartments. Floors made of 
 wood are preferable in the sleeping quarters, 
 being warmer and more easily kept dry. Where 
 the large hoghouse is used many prefer the feed- 
 ing floor to be constructed of concrete or cement 
 and the sleeping floor of wood. Where the build- 
 ing is used for the feeding of a large number of 
 swine together some prefer the feeding floor to be 
 constructed along the outside of the building, and 
 in such instances the floor should be constructed 
 of concrete or cement, raised slightly above the 
 surrounding surface. A cement feeding floor of 
 this kind properly made would be practically 
 indestructible and would be easily kept clean 
 either by sweeping or flushing with water. 
 
 Where the individual system of houses is used 
 there is no necessity for a feeding floor except a 
 small one about 8' x 8' in one corner of the lot 
 most convenient to feed, and this only for the 
 use of the litter where the pigs may be fed secure 
 from the intrusion of the mother. She may be 
 fed near them from a single trough. 
 
 Where the individual houses are used it will 
 be necessary to have a feedhouse or building so 
 arranged that all feed may be kept there in 
 separate bins ; where water may be easily obtained 
 either from an elevated tank or from a pump in 
 the building and where the mixing of the feed 
 may be done. With this system the easiest way 
 to distribute the feed to the various lots is to use 
 a wagon not to exceed 12" in height from the 
 ground, and large enough to hold three or four 
 barrels of feed set upon it. Such a wagon with 
 a pair of shafts and a gentle horse kept for the 
 purpose of hauling all feed and water to the 
 different lots make it very easy for the feeder to 
 care for 100 or 200 hogs in a short time with 
 very little labor. 
 
 Where the feeding is all done in one building 
 or house a feed carrier suspended from a steel 
 track above the alley is the most convenient way 
 to handle the feed, as it requires but very little 
 effort to carry a large amount of feed in this 
 manner along the alley. 
 
SWINH^BABNS AND HOUSES. 
 
 87 
 
 • There are many kinds of troughs on the mar- 
 ket. Some of them are good, others better and 
 some absolutely worthless. Old-fashioned wooden 
 troughs are about past. They are expensive 
 because so soon destroyed, and are always damp 
 and convenient for animals to put their feet in 
 while eating. There are several types of gal- 
 vanized iron troughs as well as two or three cast 
 iron troughs. One of the latter is made for 
 animals of any size and is absolutely unbreak- 
 able. This trough weighs 120 pounds, is round 
 and accommodates eight animals, and whether 
 small or large animals they are never crowded, 
 as the trough forms a circle. A hog or pig can- 
 not get his "feet into it, for the reason that he 
 eats out of a cup just large enough to stick his 
 nose in. These cups are filled from the center 
 in a receptacle where the feed falls on a cone, 
 thus being evenly 'distributed to the eight indi- 
 vidual cups which are separated by a heavy iron 
 rod, and the pigs can eat only from the cup 
 before them. These troughs are always clean, 
 having no place for the feed to lodge and become 
 
 down into it and have to swim through the dip 
 will pay on any pure-bred swine farm. It is of 
 great value in preventing disease. 
 
 Another valuable appurtenance is a first-class 
 feed steamer. It is generally admitted that while 
 cooked or steamed feed is of no advantage so far 
 as economy or nutriment is concerned it is of 
 great value in the feeding of young pigs during 
 the cold months, as young pigs fed on warm feed 
 either cooked or scalded with hot water thrive 
 almost as well during cold months as through 
 the warm weather. It also is of value in feeding 
 brood sows during the winter season, as a mixture 
 of clover hay, or where possible alfalfa, run 
 through a feed cutter and mixed with meal, bran 
 or middlings and steamed or mixed with hot 
 water is an ideal feed for brood sows. 
 
 THE MOKGAN HOG BABN. 
 
 F. W. Morgan's hog barn on his Wisconsin 
 farm is a T-shaped' balloon-frame building, 
 ceiled on the inside and outside, and has a shingle 
 roof. (See Pig. 143.) It is 280' wide and 
 
 fflG. 142— MORGAN HOG BARN (FRONT ELEVATION). 
 
 foul. This style of trough possibly is not suited 
 to pens along a feeding alley in a building, but 
 for outdoor use it is admirable for feeding 
 slop. The matter of feed troughs is of great 
 importance, as all feed fed in the condition of a 
 slop or mush should be fed in good troughs 
 easily kept clean. No feed should ever be fed 
 on the ground, unless it may be ear corn where 
 the ground is frozen or is hard and smooth. 
 
 A breeding crate should always be used. This 
 is an important matter. By this method of breed- 
 ing the number on the ear tag or the ear mark 
 may be taken and entered in a book, at the time 
 of breeding, giving day and date. There are 
 several kinds of breedings crates and the breeder 
 can easily learn which is best for his purpose. 
 
 Another necessary fixture on the swine breed- 
 ing farm is a good dipping tank. This is of 
 great value not only for the purpose of disin- 
 fecting swine, destroying vermin and mange but 
 in keeping the skin and hair in a healthy condi- 
 tion. Such a tank sunk into the ground with a 
 chute from an incline . where the animals slide 
 
 extends back 130'. There are in all 52 pens, each 
 with a small rustling box for winter use and an 
 outdoor addition extending back 24'. There is a 
 9' shed roof extending from the barn proper over 
 this.. Each outdoor pen has a cement wallowing 
 trough/ so that each hog gets two rooms and a 
 bath.. 'At each end of the barn are rooms 24' 
 square and 20' high, which are kept at an even 
 temperature during the winter, and are very use- 
 fur in the case of young pigs. The entire floor 
 is of cement. The large room in the center is 
 30' square and 24' high. It is supported by truss 
 work inside so as to be entirely open. It is used 
 as an engine and mixing room. Fig. 143 shows 
 the details of interior arrangement. 
 
 A NEBBASKA HOG-HOUSE. 
 
 The hog-house erected by McKelvie & Son of 
 Nebraska faces south and is 24' x 3^5'. , It stands 
 on level ground and is built on a brick wall 
 2' 6" high and the space underneath the building 
 is utilized for shade in the summer and makes a 
 warm sleeping room for cold weather. There are 
 
88 
 
 FABM BUILDINGS. 
 
 two doors in the south wall, also two directly 
 opposite in the north wall. The north doors are 
 closed in the winter and the late summer and 
 fall pigs that are weaned run in there to sleep, 
 Tiaving the space divided so that the fall pigs take 
 
 on this was put huilding paper and then the best 
 6" drop siding. This makes a wall that wind 
 does not blow through. Tar paper also was used 
 under the shingles. This makes a warm roof and 
 keeps the wind and fine snow from driving 
 
 5MAi_L. RUSTLING BCWES 
 FOR WINTER USE 
 
 CEMEHT 
 WALLOWING BOXES 
 ONE TO EACH PEN 
 
 DD 
 
 7 
 
 
 
 
 
 SHED ROOF 
 1 OOMES TO HERB 
 
 STORE 
 ROOM. 
 
 --24.'--- — - - 
 
 ■IOO- 
 
 -20'- 
 FIG. 143— MORGAN HOG BARN (GROUND PLAN). 
 
 IOO' - -*■ ZO! i 
 
 one-half and the summer ones the other half. 
 By; opening all the doors in the summer the pigs 
 are enabled to get in out of the extreme heat and 
 the flooring of the house gets thoroughly dried. 
 
 through. Besides it gives a warm building which 
 is ventilated by raising one or more of the upper 
 windows shown in Fig. 144. The north roof is 
 17' long and the south roof is 12' long. The 
 
 tu- 
 
 wrv 
 
 
 S y //<</// y / y ////// y S y y y y y y~71^ 
 // y y y/yy/y / / zzz Z / i^Zz£££zz2t 
 
 WW 
 
 vrr 
 
 D- Door 
 
 FIG. 144— A NEBRASKA HOG HOUSE. 
 
 2r¥ rr--^= r ' *w\»Kun(^£"C C"' 
 
 .Scale 
 
 ^iach=|fr 
 
 The flooring of the building is made of 1", 
 lumber and doubled and the stuff used should 
 be clear of knots so there will be no leaks to let 
 water through. The sides of the building are 
 also double. The first is common sheeting and 
 
 offset in the roof where the windows are set in 
 to give light for the north pens is 3' 8". This 
 is the space between the roofs. A larger window 
 can be used here if so desired. 
 
 The interior is divided as follows: A 4' aisle 
 
8 WINE BARNS AND HOUSES. 
 
 89 
 
 runs through the long way east and west, leav- 
 ing 10' on each side to divide up into pens. This 
 divides it into five pens on each side, two of each 
 five being 6' x 10' and three 8' x 10' with a door 
 to each pen. One pen is used for stove and bunk. 
 By the construction of the front and roof as 
 shown sunshine is admitted in the pens during 
 the greater part of the day, particularly during 
 the middle of the day, when it is most beneficial. 
 The pens are made of movable partitions, so that 
 if desired one or all of them can be raised and 
 the entire floor used for feeding. It makes a 
 very good place to fatten hogs during the winter 
 in case it happens that it is not wanted as a 
 breeding-house, as less feed is needed to keep up 
 the animal heat. The chimney or flue is at one 
 end and 2' north of the aisle. The stove is at the 
 other end and the pipe runs the length of the 
 building and heats it with very little fuel. Where 
 the cost of fuel is not much of an object heating 
 could be done with steam. Where a steam cooker 
 is used the building can be heated conveniently 
 and very evenly. The hogs get into the house by 
 approaches (not shown in the illustration) made 
 to lead to each door and are 8' long, one end rest- 
 ing on the ground and the other end just below 
 the door. This makes a gradual slope and the 
 hogs walk up easily on the slats which prevent 
 their slipping. 
 
 This is an all-purpose hoghouse and a farrow- 
 ing place in particular, where no matter what 
 the weather the litters can be saved. After the 
 
 which are provided with small houses 7' x 7' made 
 of shiplap 5' on south and 2' 4" on north, with 
 a drop door in the south side to let in the sun- 
 shine. Here they are kept for a time, one sow 
 and litter to a lot. Here they have the ground to 
 run on, which, like daylight and sunshine, is 
 essential. These small houses and yards are all 
 that are required for pigs during mild weather, 
 but for early or late fall pigs it would no doubt 
 pay to build such a house as described. The cost 
 of this building was about $250. 
 
 AN ILLINOIS HOG HOUSE. 
 
 The peculiar feature of the windows at the 
 apex of the roof serves to admit, in the early 
 
 PIG. 145— AN ILLINOIS HOG HOUSE (PBAME). 
 
 spring, the warm rays of the sun on the north 
 row of pens, the south' row being lighted by the 
 
 3 ccvU I I I I I I I I I I I i o T'c. 
 
 PIG. 146— AN ILLINOIS HOG HOUSE (GROUND PLAN). 
 
 pigs are farrowed and a few days old and the lower tier of windows, thus affording a sun-bath 
 weather will admit they are hustled out on the to all the occupants, the value of which in swine- 
 ground into lots of about one-eightb of an acre, culture is well known. (See Fig. 147.) 
 
90 
 
 FABM BUILDINGS. 
 
 The foundation is made of "blocks of stone 
 which are laid about 4' apart. Sill beams are 
 of 6" x 6" lumber. The frame consists of 2" x 6" 
 scantlings placed 2' apart and which are 1' high. 
 There are two rows of 4" x 4" posts — one on each 
 side the alley, 6' apart, extending to and sup- 
 porting the roof — as shown in Fig. 146. Girts of 
 2" x 6" go 1 across every 6'. Plate beams consist of 
 a 2" x 6" and 2" x 4" spiked together. Rafters 
 are 2" x 4" and 2' 6" apart. The roof is one-third 
 pitch (see Fig. 145) and is made 1 of sheeting 
 and shingles. , Sides are of drop-matched 6" sid- 
 ing. Eaves and gables project 13". Floor joists 
 
 side; this leaves 10' in the center for a feeding 
 floor to feed young pigs on and two bins on each 
 side at the north end for feed 8' x 10' and a 
 mixing room 8' x 10' for cooker. Water is to 
 be piped to mixing room, concrete is to extend 
 from A to B. The object of the concrete not 
 extending all over the whole floor is to have 5' 
 of dirt at the back end of each stall for pigs and 
 sows to lie on. 
 
 HOUSE FOE TWENTY SOWS. 
 
 The house (shown in Figs. 150 and 151) for 
 20 brood sows is practically rat-proof. The plan 
 
 W 
 
 m 
 
 r~T 
 
 ^5L^ 
 
 i i 
 
 t — n 
 
 it i 
 
 I _i_ 
 
 :l.. i i 
 
 ?F^ 
 
 i.i i r - 
 : i — i— i 
 
 i i r 
 
 il_L.1 
 
 TT ' 
 
 CTiir 
 
 .../ \ t — r 
 
 ' > 
 
 ' t 
 
 1 ' ' I I I ' I t ' I > 
 
 _s_ 
 
 a Tt' 
 
 FIG. 147— AN ILLINOIS HOG HOUSE (SIDE ELEVATION). 
 
 are 2" x 8" and 2' apart. Floor of 2" plank. 
 Windows are 2' by 2' 3". Those above are made 
 to slide sideways and the lower ones up and down. 
 All the partitions are movable drop partitions 
 except those adjoining south side of alley and 
 
 shows a row of feeding pens around the building, 
 which means a concrete floor all around the 
 building. This floor is on the level of the board 
 floor in the breeding or sleeping stall and the 
 concrete in the alleyway through the center of 
 
 8 FT 
 
 68FT. 
 
 FIG. 148— HOG HOUSE FOB SOWS AND PIGS (SIDE ELEVATION). 
 
 the middle cross partition. The total cost of this 
 building was about $200. 
 
 HOG HOUSE FOE SOWS AND PIGS. 
 
 The hog-house shown in Figs. 148 and 149 is 
 intended for sows to farrow in. Pigs when weaned 
 may also be fed in it. This house is 68' x 30' ; 
 stalls are 6' wide and 10' deep, a row on each 
 
 the house. The concrete feeding floor and alley- 
 ways are to be built first and with a fall of 3 " 
 in t'h6 length of the building to give drainage 
 so that the alleyway may be flushed out often. In 
 extremely cold or stormy weather it may be desir- 
 able to feed and slop the sows in the sleeping 
 pens. Some may object to the plan of board floor 
 for the sleeping stalls, but experience shows that 
 
SWINE BABNS AND HOUSES. 
 
 91 
 
 w w 
 
 68 FT. 
 
 www 
 
 w 
 
 w 
 
 5 FT. 
 
 '*■ — 1-rBll 2" 
 
 O' ! 
 
 DOOR 
 
 \ 9 
 
 
 A 
 
 DIHT 
 
 •4—4—3 6- 
 
 CONCRE 
 
 —7- 
 
 ^ 
 
 CONCRETE 
 
 -Mt-> 
 
 -12- 
 
 13— 
 
 w 
 
 CONC RETE 
 
 -14— 
 
 — 15- 
 
 DIRT 
 
 -16- 
 
 -17— 
 
 w 
 
 w 
 
 -8 g--4— lo— 
 
 -18— 
 
 -19- 
 
 w 
 
 w w 
 
 ■•'* 68 FT. 
 
 FIG. 149 HOG HOUSE FOB SOWS AND PIGS (GROUND PLAN). 
 
 -20— 
 
 FEED 
 BIN 
 
 MIXING o 
 
 BOOM ]J v ooot 
 
 \. 
 
 FEED 
 
 BIN c 
 
 sows and pigs are warmer and require less bed- lay the nail ties for the floor, so that the cinders 
 
 ding on the board floor than on concrete. or sand will fill the space completely up to the 
 
 _ In building fill the spaces under the floor with floor. This makes the floor solid, warm, dry and 
 
 cinders or coarse sand or fine gravel and in this effectually shuts out rats, as they can not burrow 
 
 ns 
 
 A 
 
 □□ DD DD □□ -- □□ 
 
 ^^ 
 
 _( ,„ 1^=17. 
 
 FIG. 1E0 — HOUSE FOB TWENTY SOWS (ELEVATION). 
 
 TIG. 151 — HOUSE FOB TWENTY SOWS (FLOOB PLAN). 
 
92 
 
 FABM BUILDINGS. 
 
 in cinders. The cinders should be at least 6" 
 deep; deeper is better. The durability of the 
 concrete floors depends on the construction. A 
 poorly-built concrete floor is short-lived; a well- 
 built one is practically as lasting as granite. The 
 concrete and board floors can all be made before 
 the building is erected, but one will have a firmer 
 building and fences to erect the frame of the 
 building and set posts for the outside fence before 
 laying concrete. 
 
 The plan of construction gives sizes and 
 lengths of material, so that any handy farmer can 
 do the carpenter work. The siding is what is 
 called patent siding, tongued and grooved. It 
 should be well dried before it is put on. It is 
 covered with redwood shingles. The sash have 
 
 himself. A cistern or drive-well will add to the 
 convenience and place water at hand. 
 
 The cost of the building not painted will be 
 about $200. This plan places the health of the 
 herd above the convenience of the herdsman. 
 Sanitary conditions are the first requisite of 
 health and these mean plenty of sunlight, pure 
 air and clean dry sleeping places. The cement 
 floor outside favors a clean house inside, reduces 
 inroads of filth and rats and adds to the comfort 
 of the sows and pigs. 
 
 FARROWING PEF FOR EARLY LITTERS. 
 
 For warmth, sunlight and convenience the far- 
 rowing pen shown in Fig. 152 is unexcelled. Its 
 
 ~t 
 
 FIG. 152— FARROWING PEN FOR EARLY LITTERS (FRONT VIEW). 
 
 six lights, each 8" x 10" ; they can be bought 
 ready glazed. The plan shows them in pairs. 
 To get a better distribution of sunlight they 
 should be distributed so as to divide the dead 
 space equally between windows. The»deck sides 
 are not perpendicular but have an 8" slope in the 
 2%' of height, thus admitting more direct rays 
 of the sun. By this arrangement of sash one can 
 have sunlight in every corner of the house and 
 by hinging half of the sash and elevating or 
 lowering it as in a green-house one can have 
 almost complete ventilation. 
 
 By doors opening into the alley one can change 
 or sort the sows or pigs readily and from the end 
 or side doors sows can pass to as many different 
 grass lots or fields as are available. If one wants 
 fire in the house for heating it or making slop 
 he can arrange that in the alley and have a flue 
 put in the deck when building. More space "for 
 stove or boiler may be had in the center of "the ''* 
 house by setting the partition of a stall on each 
 side back one foot, thus making two small stalls 
 G' x 7' and stove space 8' x 8'. In building every ' 
 other partition of stalls may be made movable, 
 but this is a matter for each man to settle for 
 
 foundation is on stone pillars. The joists are 
 2" x 6" by 20' long ; the floor is tight. The south 
 
 
 \ 
 
 A/sls S'x.S4-' 
 
 o 
 
 Sroye 
 
 I 
 
 Pens 
 7%X.8' 
 
 FIG. 158— FARROWING PBN FOR EARLY LITTERS (PLAN). 
 
 side is 6y 2 ' to the eave; north side 4' 8" to eave; 
 highest point of house, 12' ; 4" x 4" corner posts 
 and also to roof in center. The sides are all 
 
SWINE BABNS AND HOUSES. 
 
 93 
 
 boxed tightly, papered and weather-boarded. The 
 roof is sheeted down solid, papered aifd shingled 
 with best shingles. Sash are 2%' x 6i/ 2 ' each. 
 The partitions and doors are made of matched 
 
 torn 8" from floor and with inside 8" from par- 
 tition. The great advantage of using matched 
 flooring for partitions is it prevents one sow from 
 knowing what her next neighbor is doing and 
 one disturbs the other but little. A pen 8' x 16' 
 
 FIG. 154— 1,0 VB JOY FARROWING PENS (FRONT VIEW). 
 
 flooring and are 33" high and movable. The 
 dotted lines around each farrowing pen (Fig. 
 153) are a 2" x4" hardwood scantling with bot- 
 
 FIG. 155— LOVEJOT FARROWING PEN (CONSTRUCTION). 
 
 for each farrowing pen is on the outside of the 
 house, and is made so one pig cannot get in his 
 neighbor's pen, thus allowing the sow to be fed 
 outside of the house and exercise for sow and pigs 
 
 FIG. 156— A PORTABLE PIG PEN (COMPLETE). 
 
94 
 
 FABM BUILDINGS. 
 
 when the weather will admit. The cost of this 
 house complete was about $125. 
 
 LOVEJOY FARROWING PENS. 
 
 These pens or portable houses (Fig. 154), 
 designed by A. J. Lovejoy of Illinois, are each 
 situated in the middle of an acre lot and on 
 either side of a driveway, the divisions being 
 made by the use of wire fencing. The houses 
 are 8' square. Pour 16' boards make the floor, 
 arid the roof and sides are made of matched floor- 
 ing, lined with building paper, and that covered 
 on the inside with common lumber. The houses 
 are set to front south. There is a door in both 
 north and south ends and a window in the south 
 end, the latter being hinged at the top with rope 
 and pulley attached so that it can be swung up 
 out of the way when it is open. In cold weather 
 
 about $10. They are set up on blocks in the sum- 
 mer to keep* the floors dry and in the winter time 
 they are dropped to the ground and banked to 
 keep the wind out from under the floor. 
 
 A PORTABLE PIG PEN. 
 
 The primary object of this pig house "(Figs. 
 156 and 157) is to secure shelter, warmth, sun- 
 shine and pure air at reasonable cost, and the 
 secondary object is to have it as handy for feeding 
 and handling the sows and pigs as possible. L. 
 N. Bonham of Ohio perfected 'this plan. 
 
 This house is 5' x 6'. Four scantlings 2" x 2" 
 x 12' and two scantlings 2" x 4" x 12' will make 
 the frame and roof supports. The bottom rail 
 is 2" x 4", the others 2" x 2". The three pieces 
 for the roof are cut 6' 6" to give a 3" projection 
 of roof beyond the sides. 
 
 FIG. 157— A PORTABLE PIG PEN (TOP AND FRONT OFF). 
 
 and early spring the north door is closed, and if 
 necessary the south openings also are closed, 
 fresh air being secured through the ventilator in 
 the roof that is made by carrying the ridge a 
 trifle higher than the sides that comprise the roof. 
 This is shown clearly in Fig. 155. 
 
 In hot weather the houses are converted' into 
 summer resorts by leaving both doors and window 
 open. Each house is nicely painted with two 
 coats and trimmed in white, and costs complete 
 
 Fig. 156 shows, the house;' set up and the drop 
 window partly down. Fig. 157 shows the top off! 
 The construction is readily seen. After the hous^ 
 is ready to set together have the floor made just 
 large enough to let the sides of the house set 
 outside the floor. The cost of this house is about 
 $5. It pays to paint the roof every three years 
 but the sides will last without paint as long as 
 the roof will painted. -Taken down each fall and 
 spring and whitewashed and set up against a 
 
SWINE BABNS AND HOUSES. 
 
 95 
 
 fence or in a shed until needed it will give long 
 service. 
 
 PIG HOUSES AND FEEDING FLOOR. 
 
 The floor shown in Fig. 158 is made of 6" 
 flooring as free from sap and loose knots as it is 
 possible to secure it, and nailed every two feet 
 to the 2" x 3" nail ties. On the ends and sides 
 of the floor joists '£*jx 8" are set onedge, over 
 which the floor lapi^fl^^MBts ke^p ..the cin- 
 ders in and the edges*oJi fhe'«jf>r solid. "'On such 
 
 cleaned off before the snow is packed. The clean 
 dry feeding floor invites the pigs out many an 
 hour when pigs in the average pen will not ven- 
 ture out. If one has three or four sows to farrow 
 the same week he can put them in these pens and 
 make them more comfortable than in the large 
 house. If but one or two sows farrow in the same 
 week they are assigned to the single houses lo- 
 cated at convenient places for good sanitary sur- 
 roundings. 
 
 With this floor 16' x 48' there is room for four 
 
 TIG. 158— PIG HOUSES AND FEEDING FLOOR. 
 
 a floor one can drive a team without injury to 
 the floor. With a fall of 2" in 16' there is good 
 drainage and it is easy to clean. 
 
 The feeding and slopping are done on the floor 
 outside the houses, as this is the only way to 
 keep the pen dry and free from droppings. The 
 size of the pens, 6' x 1', also favors this. If the 
 pens are much larger the pigs will use a corner 
 for droppings and keep the floor wet and air foul. 
 
 The space on the floor in front of the pens is 
 divided by gates, so the sows and litters are kept 
 separate the first week or two until they begin to 
 want to go out onto blue-grass. After that the 
 gates are swung back against the fence and the 
 sows and pigs are encouraged to go out every 
 bright day. 
 
 It is surprising how soon these floors are dry 
 and warm after snow storms if the floors are 
 
 of these houses and floor room left sufficient for 
 feeding 50 shotes. 
 
 PLAN FOR MOVABLE HOG HOUSE. 
 
 The hog houses used at the Iowa Experiment 
 Station are made as indicated in Fig. 159. The 
 dimensions are 8' square, with 2' 8" corner posts 
 and 5' rafters. The pen is supported by five 
 2" x 4"s running from end to end and sawed 
 slanting at the front end, the two outside pieces 
 having holes for attaching a rope, thus enabling 
 the house to be drawn by a team and placed in 
 different locations when desired. The floor is 
 made from four rough boards 1" x 12" x 16' cut 
 in the center, and the roof is made of grooved 
 roof boards 1" x 10" x 12', cut in the center. The 
 sides and ends are made of 8" drop siding and 
 the pen when complete is given two coats of 
 
96 
 
 FABM BUILDINGS. 
 
 paint. All dimension pieces are of 2" x 4". The 
 roof window is 2' x 5' and covered by a hinged 
 section of the roof the same width, which may 
 be open or closed to admit or exclude sunshine. 
 The door is 2' 6" by 2' 8", and the opposite end 
 contains a gable window 2' by 21" for light and 
 ventilation. Tbe pen complete, including win- 
 dows and painted two coats will cost about $12. 
 After the pigs are old enough for the sows to be 
 turned together as many as three sows and eigh- 
 teen pigs may be accommodated without difficulty 
 in one of these pens. 
 
 They may also be used for fattening hogs and 
 for this purpose they possess some important ad- 
 
 FIG. 159— MOVABLE HOG HOUSE. 
 
 vantages over larger apartments or shed room, 
 chief among which is that they can be readily 
 moved and placed where desired and also that 
 pens of this size prevent the hogs from piling up 
 and injury by overcrowding. Another point is 
 that this system permits the hogs to be moved 
 readily to clean fresh quarters as often as may 
 be desired. This is the most effective way of 
 disinfecting after a scourge of hog cholera. This 
 system of handling hogs may be modified as ex- 
 perience or varying conditions dictate. 
 
 A MAEYLAND HOG HOUSE. 
 
 Neither corn nor pork can' be successfully pro- 
 duced without plenty of sunshine. In the North 
 this sunshine in winter will have to be brought 
 into the pens through glass. In more Southern 
 latitudes under normal conditions it is only neces-,* 
 sary to face the pen to the south ; allow the sun's 
 rays to reach to the back of the pen on the beds 
 and give good shelter and protect from the north 
 and west winds. 
 
 The end elevation and floor plans, designed by 
 the Maryland Experiment Station, give almost a 
 complete idea of the pen at that station which 
 
 has met with very general favor. A few of the 
 special points in construction are thus given : 
 
 1. It is faced to the south (Fig. 160) so as to 
 permit the rays of the sun to shine on the beds 
 
 , jJBSShb 
 
 E- 
 
 
 Sf^H A 
 
 ^m®mm®mm 
 
 JTG. 160— A MARYLAND HOG HOUSE (FRONT ELEVATION). 
 
 of the pigs at the extreme rear end of the pen in 
 the winter season and also to give shade in that 
 portion in summer. 2. The lattice construction 
 
 Bed 
 
 
 
 
 t • 1 
 
 IS 
 
 • S 
 
 -1 
 
 V--^- 
 
 DRIVEWAY \ \> 
 AND MANURE \ >#■ 
 
 
 
 m 
 
 
 FEED 
 FLOOR 
 
 
 
 
 
 
 
 
 
 
 PASSAGE 
 
 |i FEED BINS I 
 
 
 
 II 
 
 FIG. 161— A MARYLAND HOG HOUSE (INTERIOR ARRANGEMENT). 
 
 between the pens at the ends and rear admits of a 
 free circulation of air in warm weather. 3. The 
 location of the manure pit (see Fig. 161) in the 
 
 FIG. 163— A MARYLAND HOG HOUSE (SIDE SECTION). 
 
 center and below the level of the sleeping and 
 feeding floors with all drainage toward it aids 
 materially in maintaining a proper sanitary con- 
 dition. 4. The ease and facilitv with which the 
 
SWINE BABNS AND HOUSES. 
 
 97 
 
 manure can be removed. 5. The swinging gates 
 close the pigs into their beds while the manure 
 is being loaded; 6. The swinging fronts to the 
 pens permit the food to be easily placed in the 
 trough and evenly distributed so that the pigs 
 have an equal chance at feeding time. 7. The 
 manure pit is concreted, which enables the sav- 
 ing of all liquid excrements, which with the pig 
 
 amounts to 51 per cent of the total manure value. 
 
 8. Ease of changing pigs from pen to pen. 
 
 9. Feed bins are placed in front of each pen 
 which facilitates feeding and enables keeping dif- 
 ferent feeds for each pen if desired. (See Pig. 
 162.) 10. The gene^l plan can be used and 
 the dimensions and materials modified so as to 
 meet the demand of circumstances. 
 
 SHEEP BARNS AND SHEDS. 
 
 In the old world there is little housing of sheep. 
 In England many flocks are in the open the year 
 round ; in France they are housed and artificially 
 fed winter and summer in some parts, mainly 
 no doubt because of the great value of the land 
 and the cheap labor. In America cold winters, 
 drenching storms and intense summer heat are 
 encountered so that there is in the region north 
 of Tennessee and east of Colorado need for pro- 
 vision for shelter. 
 
 Inexperienced flockmasters err in making too 
 careful provision for shelter. Sheep need to be 
 dry and out of the wind — that is all. Many 
 expensive sheep barns fail because of lack of 
 fresh air. Sheep have been fed in these expensive 
 barns at a loss and in later years they have been 
 fed in the open yard alongside the barn, the feed 
 being stored within, at a profit. 
 
 The sheep is not a hardy animal. A native of 
 mountainous regions it is used to having its 
 lungs full of pure fresh air. Deprived of this 
 no amount of feed or coaxing will make it thrive. 
 Some one has said that "the worst enemy of a 
 sheep in the barn is another sheep." The sheep 
 barn then needs primarily two things : a water- 
 tight roof and provision for the entrance of an 
 abundance of fresh air. Add to these things 
 provision for storing a large amount of forage 
 and a supply of pure water and the sheep barn 
 should prove satisfactory, whether it is built 
 cheaply or expensively. 
 
 Perhaps the best manner of ventilation is by 
 haying all of two sides provided with continuous 
 doors, divided horizontally, the lower half swing- 
 ing outward like a gate, the upper half lifting 
 up horizontally, as a box lid lifts, and held up 
 by props hinged to the door. These doors may 
 then be opened slightly to admit some air during 
 a blizzard, wider on a cold day, entirely up when- 
 ever the weather is warm and the air sluggish, 
 and one side may be left wide open at all times. It 
 is better to leave off the upper doors altogether, 
 
 leaving mere open spaces there, than provide 
 doors and then forget to open them. 
 
 Sheep bear crowding together in the fattening 
 flock and six square feet of floor space to a 
 fattening lamb eight months old is ample. Twice 
 that will suffice for a pregnant ewe. To crowd 
 them without providing fresh air is of course to 
 be avoided. 
 
 Movable racks are best. Make them of such 
 length that they may be set to form ■ partitions 
 in the barn. The most economical hay-racks are 
 those in which the sheep thrusts its head in be- 
 tween the slats, then eats without pulling the hay 
 out and trampling it beneath the feet. Try to 
 prevent this waste by making very narrow slats 
 and the waste is doubled, as all hay is first drawn 
 through the narrow spaces before being consumed 
 and very much of it is wasted. Provide plenty 
 of racks, so that every lamb can eat at the same 
 time. It matters little how many sheep are kept 
 in a pen if the air and water are pure and 
 each lamb has a chance to eat at will. Certainly 
 in the breeding flock there must be separate pens 
 for the ewes advanced in pregnancy and many 
 small pens for ewes that have lambed. These 
 pens may be built of simple tight panels about 
 4' high and 5' long, two panels hinged together 
 and when opened at right angles and hooked into 
 a corner of the room they form the other two 
 sides of a very convenient small pen. 
 
 A small yard paved or concreted attached to 
 the sheep barn is indispensable. Do not make it 
 large, as it will cause loss of droppings and be 
 more difficult to keep dry. 
 
 The fattening flock should be confined to the 
 barn at all times save when feed is being put 
 in ; then it is convenient to run them in the yard. 
 In this way the saving of manure is material and 
 the lambs or sheep fatten faster to have little 
 exercise. There should be provided inside a flood 
 of pure air for them. 
 
 Water should be in abundant supply and so 
 
98 
 
 FABM BUILDINGS. 
 
 convenient of access that the sheep have no diffi- 
 culty at any time in satisfying their thirst. It 
 should be kept pure enough for man's use. Sheep 
 are dainty in their appetites and readily detect 
 foulness in the water. 
 
 When the sheds are keg^ well littered with dry 
 straw there is no harm in permitting the manure 
 to accumulate to considerable depth. The tread 
 of the sheeps' feet prevents its heating and all Is 
 saved. It should be hauled out, however, as fast 
 as the condition of the fields will allow and all 
 cleaned out on the approach of warm weather. 
 Sheep manure being rich in nitrogen it is good 
 economy to sprinkle the bam frequently with 
 finely ground phosphate rock or phosphate flour 
 or with acidulated- rock or aoid phosphate. Ap^ 
 plying the manure to the land with a manure 
 spreader it may be put on more thinly when so . 
 treated. The manure from sheep barns forms 
 a considerable source of profit 'and has made 
 some farms famous. 
 
 A dipping tank is part of the indispensable 
 sheep barn furniture. It may be of galvanized 
 iron or cement. It may be 16" wide at the top, 
 8" at the bottom, 4' long at the bottom and 10' 
 at the top>, giving an incline on which sheep may 
 walk out. All sheep that have traveled on cars 
 are probably infected with scab germs. Dip them 
 thoroughly before they go into the sheds. Turn 
 them in wet and allow them to rub their wet 
 
 a small turnip house. On all sides of the barn 
 are hay self-feeders. The wings are 32' wide. 
 
 FIG. 164— THE MOBGAN SHEEP BARN (GROUND PIAN). 
 
 The plan shown in Fig. 164 gives a clear idea as 
 to arrangement. 
 
 A NEBRASKA SHEEP BARN". 
 
 On a Nebraska farm where from 5,000 to 7,000 
 lambs annually are raised two large barns have 
 been constructed according to the affixed plans. 
 
 The barn in which the greater number of the 
 lambs are dropped is shown in the ground plan, 
 
 FIG. 163— THE MOBGAN SHEEP EARN (BEAB ELEVATION). 
 
 sides against the posts and racks. All home 
 sheep are apt to be ticky. Dip them once a year 
 and the tides may be eradicated. There is no 
 stock on the farm more miserable than poorly 
 cared-for sheep. 
 
 THE MORGAN SHEEP BARN. 
 
 This barn built by F. W. Morgan in Wisconsin 
 is of ordinary balloon frame construction ceiled 
 on inside and outside with shingle roof. (Fig. 
 163.) It is 182' wide by 155' long in the shape 
 of a cross. The entire floor is of grout construc- 
 tion. In the front is a shearing and engine room 
 and in one corner of the center of the barn is 
 
 Fig. 165. There is a loft above in which hay is 
 stored and chutes down which it is thrown to 
 be fed in the permanent hay-rack shown. This 
 hay-rack partitions off the space so that the cen- 
 tral part is used for one class of ewes, generally 
 the ones least advanced in pregnancy, while those 
 showing nearness to lambing are placed in the 
 outer space. 
 
 The small pens on three sides of the barn 
 are for the reception of ewes after lambing or 
 in some cases before lambing. They are 4' x 6' 
 in size furnished with convenient gates, with also 
 a wooden trough communicating through the par- 
 tition to furnish two pens with water, which is 
 
SHEEP BABNS AND SHEDS. 
 
 99 
 
 carried in buckets. There is also a small feed 
 trough to each pen. 
 
 The hay feeding arrangement is unique. At 
 the outside of the building there is a bin4ike 
 addition with hinged lids that open upward, as 
 shown in Fig. 165. This is the hay feeder. Par- 
 titions across the front keep the lambs out while 
 allowing the hay to be pulled through readily. 
 The hay is placed in the feeders from wagons 
 along the outside. Where hay is generally 
 stacked outdoors, this arrangement has much 
 to commend it. 
 
 it. Allowing 12 sq. ft. to the ewe and lamb this 
 barn will carry 2,000 ewes. It will not hold a 
 liberal amount of hay for that number and the 
 chief and only important defect of the building 
 is its lack in height. . 
 
 It is a question that must largely be settled 
 by environment and individual preference 
 whether this is a cheaper type of barn than the 
 barn in which the hay is stored in lofts and the 
 entire floor-space devoted to the sheep. In each 
 of these barns hay is rapidly placed by machinery 
 and horse-lifting. While no elevation of these 
 
 ^T 
 
 1 1 1 1 1 1 1 1 1 1 1 1 1 ! 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 J 
 
 mound rLAH ar itHtr mk I 
 FIG. 165— A NEBRASKA SHEEP BARN. 
 
 Grain is fed the ewes before lambing in a 
 small yard outside the barn. The dimensions of 
 the building are 88' x 112', the basement story 10' 
 high, the mow should have a* height of at least 
 10' at the plates, making a 20' post. 
 
 Fig. 165 shows a very large Western barn, the 
 dimensions of which are 120' x 288'. It is com- 
 paratively low, has no loft but instead is more 
 in the nature of a covered yard. The hay is 
 stacked in this building in long ricks or mows 
 16' x 56'. There are eight of these ricks. The 
 roof of the building rises in steps, there being 
 plenty of windows and change of air through 
 them, so that the light and ventilation are good. 
 Self-feeders are provided in this barn so that win- 
 ter lambs may be produced and old ewes fattened 
 with their lambs. 
 
 A fence divides, the barn lengthwise in the 
 center and a system of gates is so conveniently 
 arranged that sheep are very easily managed in 
 
 buildings is shown the intending builder can 
 readily adapt another* elevation to 'fit, choosing 
 from among the forms of pole or joist frames. 
 
 EXPERIMENT STATION SHEEP BARN. 
 
 The sheep barn built, several years since at the 
 Wisconsin Experiment Station is believed to em- 
 brace many features worthy of general adoption 
 by practical sheep-breeders and several points 
 that are vitally essential to successful sheep hus- 
 bandry are brought out. 
 
 The building (see Fig. 169) consists of a main 
 part 24' x 30' two stories high, under the whole 
 of which is a root cellar, and two wings reaching 
 out at right angles from it. The east wing is 
 125' long, 18' wide and one story high. Only, 
 a part of this is shown in the cut. 
 
 The south wing is 100' long, 18' wide and two 
 stories high. An alley or passageway 4' wide is 
 partitioned off along the entire west side of the 
 
100 
 
 FARM BUILDINGS. 
 
 building by means of a low fence-like partition 
 (see Fig. 166). This leaves a space 14' wide and 
 a little over 83' in length, exclusive of a lambing- 
 room that may be occupied by the flock as one 
 large room, or it may be divided into any desired 
 number of pens up to ten by means of a light 
 but strongly-fastened panel that rests in grooves 
 made for it at each end (see Fig. 167). These 
 panels are easily managed and when placed in 
 position are entirely secure without fastenings of 
 any kind. 
 
 Since it has been explained how all the space 
 in the shed may be used as one room, we will from 
 now on consider the building as it is when divided 
 into ten parts. Each pen is 8' 4" wide and is 
 entered from the passageway through a sliding 
 gate (see Fig. 167) that is suspended from a 
 2" x 4" scantling which is fastened in a hori- 
 zontal position to the upright pieces of the pas- 
 sageway partition. 
 
 Each pen is provided with a low flat-bottomed 
 trough for the feeding of grain and also a large 
 
 ! I 
 
 YY^YYYYYY"' 
 
 ! l»M ITTTT1 
 
 FIG. 166— EXPERIMENT STATION SHEEP BARN (PLAN). 
 
 hay or fodder rack, as see Fig. 168. This hay- 
 rack is made with a tight front which prevents 
 chaff and dust from falling into the eyes and 
 fleece of the sheep while feeding and is also ad- 
 justable so that not only the angle of the front 
 but the width of the opening at the bottom where 
 the sheep throw the feed out may be changed 
 to meet the necessities of the feed that is being 
 used. The feeder or trough that is below the 
 opening where the feed is drawn out serves an 
 admirable purpose in catching all the finer parts 
 of the hay or fodder that would otherwise be 
 trampled under foot and wasted. This hay rack, 
 as illustrated in Fig. 168, can easily be changed 
 so as to meet the requirements of ordinary feeding 
 by making it so that sheep can feed from both 
 sides and long enough to reach across the shed. 
 It may serve the double purpose of feed-rack and 
 partition. 
 
 Experience has taught that adequate ventila- 
 tion must be provided in all sheep buildings if 
 trouble in their management would be avoided, 
 and it appears that the building that is best 
 adapted to the successful care of a flock is the 
 
 one that may be the most readily and completely 
 changed from an open to a closed shed according 
 as the weather makes one or the other of the 
 conditions essential. In recognition of these ne- 
 cessities each pen has double doors that when 
 opened out into the yard make an opening that 
 only lacks 38" of being as wide as the pen. The 
 manner in which these doors are operated and 
 fastened may be seen in Fig. 167. One door is 
 bolted securely at the top and bottom by bolts 
 operated by a lever, as shown in the figure, and 
 the other one fastened to it by means of an ordin- 
 ary thumb-latch so that one or both doors may 
 be opened at will. A slight upward movement 
 of the lever allows both doors to swing open and 
 when pushed shut a similar downward movement 
 locks them safely. 
 
 Over these double doors are windows that are 
 the sameCwidth as the doors and 2' high. These 
 windows are hinged at the top and are opened 
 and closed from the passageway by means of a 
 
 FIG. 167 — EXPERIMENT STATION SHEEP BARN (SLIDING GATE). 
 
 rope that runs over two small pulleys. The win- 
 dows are provided with a fastening device (Fig. 
 168) that works automatically. A pull on the 
 rope from the passageway unlocks the window 
 and raises it at the same time. When the rope 
 is released the window closes and locks itself. 
 Since the windows are operated from the hall- 
 way time is saved* and annoyance and confusion 
 to the sheep are prevented. 
 
 From what has been said it is easy to see how 
 readily the barn may be converted into an open 
 shed. If the weather is stormy but not cold the 
 flock can be kept in the barn with the doors closed 
 and the large windows left wide open, which will 
 insure the admission of an abundance of fresh 
 air without the bad results following the exposure 
 to a draught directly upon their bodies. Should 
 it become necessary to close the barn tight there 
 still is ventilation by means of shafts that are 
 constantly carrying off air from near the floor 
 of each pen. These shafts (see Fig 167) are 
 simple wooden boxes that start a foot from the, 
 floor and extend up through the roof as high as 
 the peak. They are made by nailing two 8" and 
 
SHEEP BABNS AND SHEDS. 
 
 101 
 
 two 10" boards together. Near the bottom on 
 one side of the shaft is an opening for the admis- 
 sion of air, the flow of which can be regulated 
 by a door that is hinged at the bottom and pushed 
 into the shaft. 
 
 A lambing-room occupies tne space of two pens 
 in the partition adjoining the main barn. It is 
 
 There are no permanent partitions of any kind 
 upstairs. The space is divided by means of light 
 fence panels. The sheep in going to and from 
 the second story pass up and down through a 
 chute at the end of the barn (Figs. 166 and 169) . 
 The east or one-story wing has a 4' passageway 
 along the north side which leaves a room 14' 
 
 f 
 
 FIG. 168— EXPERIMENT STATION SHEEP BARN (HAYRACK). 
 
 14' x 16%'. This, room is inclosed by tight walls 
 on all four sides, with an outside door and a 
 door leading to the shepherd's room. The wall 
 next to the alleyway and that next the first pen 
 are provided with wide hanging doors hinged 
 above, extending horizontally, which reach from 
 
 wide by 125' in length. This may be occupied 
 as one room or divided into any number of pens 
 up to fifteen, which is the maximum. The gates 
 and panels are similar to those described in the 
 south wing. 
 A reference to Fig. 166 will show that the main 
 
 FIG. 169— EXPERIMENT STATION SHEEP BABN (GENERAL VIEW). 
 
 about 2' below the ceiling to a point 4' above the 
 floor. In cold weather they are fastened down ; 
 at other times they are swung to the ceiling, 
 leaving the pen light and airy. By means of 
 movable partitions this will accommodate six or 
 eight ewes at lambing time. 
 
 The second story is also arranged for sheep. 
 The floor is constructed of 1" matched material 
 with a coating of gas tar mopped on while hot. 
 
 barn is arranged to be convenient for both wings. 
 The scales are located in the corner where the 
 passageways from the wings meet. By this plan 
 the sheep may be let out from any pen in .either 
 wing and driven along the passageway to the 
 scales. The shepherd's room is in the southwest 
 corner and by means of small windows in the 
 partition a view of the whole interior of both 
 wings may be had. A door from this room opens 
 
102 
 
 FABM BUILDINGS. 
 
 directly into the lambing-room and if necessary 
 the lambing-room can be warmed from the shep- 
 herd's room. 
 
 The dotted lines beside the shearing and in- 
 spection floor in Pig. 166 represent a railing 3' 
 high that forms the passageway partition, and 
 the space between this railing and the shepherd's 
 room is used as a shearing floor. Feeding bins 
 and stairways leading to the second story of the 
 south wing and to the root cellar below occupy 
 the rest of the space on this floor as shown in 
 Fig. 166. 
 
 A BABY MUTTON FACTOSY. 
 
 A moment's study of Figs. 170, 171 and 172 
 will show that the dominant ideas about the con- 
 struction of this building were ventilation, light 
 
 FIG. 170— A BABY MUTTON FACTORY (ELEVATION). 
 
 and sunshine — three things absolutely essential 
 to success in growing baby mutton. 
 
 The building faces the southeast and is 26' 
 x 52' with 16' posts. The lower story is 7', the 
 upper 9' and as the rafters have a rise of 10' 
 there is ample space for hay and fodder. The 
 windows in front are 3' x 6' and the sash are 
 raised and lowered at will. Those in the end are 
 hinged to open inside. Around the back and 
 northeast end above the nail tie are six doors 
 each 24" x 30". A 10' flap door admits the sheep 
 without crowding. 
 
 During the winter there are often spells of 
 warm, muggy weather which make ventilation a 
 serious problem. At such times the small doors 
 should be opened and the lower sash raised. This 
 admits fresh air next the ground and any un- 
 pleasant odors are quickly dispelled. Every foot 
 of floor space is utilized, and the hay racks are 
 high enough from the ground to furnish resting 
 places for the lambs. The water is brought by 
 piping from a nearby wind-pump. The trough 
 is an 8' galvanized iron one hung on pivots at 
 each end and can quickly be tipped over for 
 cleaning. 
 
 A bran bin reaching from the nail tie of the 
 lower story to the nail tie of the upper story 
 holds two tons and does not rob the sheep of any 
 
 of the floor space. A paddock 40' x 50' at the 
 west end, placed there after the photo was taken, 
 gives ample room for exercise when the weather 
 is good. The building is largely tenon and mor- 
 tise, but the three inside bents are somewhat dif- 
 ferent. The long braces are about 25' long, are 
 spiked to the rafters above (see Fig. 171) and- 
 the posts below and rest on the foundation. They 
 are also spiked to the girders and to the short 
 braces, which are 2" x 6". This makes a strong 
 brace and leaves unobstructed room for the hay 
 fork. 
 
 The frame and joists are of oak; the rafters 
 of sugar tree ; the mow floor and nail ties of elm ; 
 
 PIG. 171— A BABY MUTTON FACTORY (CONSTRUCTION). 
 
 the siding of pine ship-lap; the sheathing rough 
 pine; the roofing, felt. The foundation is made 
 by placing stone pillars under the posts and filling 
 the space between with bowlders, gravel and 
 cement. Therefore there are no cold draughts 
 near the ground in rough weather. Two hay 
 chutes drop the feed directly into the long rack. 
 These and the stairway assist in making the ven- 
 tilation perfect. 
 
 A UTAH SHEEP SHED. 
 
 Willard Hansen's Utah sheep barns or sheds 
 (Fig. 173) are large enough to, accommodate 500 
 ewes and lambs and 600 to 700 yearlings. In 
 the breeding shed there are 10 large pens 32' 
 square, planned for the accommodation of 500 
 ewes. The division between the sections is a long 
 feed rack. Each section may be divided into 
 four smaller pens. A movable hurdle from the 
 water trough to the door divides into two and 
 by swinging the lamb-creep into place yet two 
 other divisions are made. In the center of the 
 pen facing south is a door 16' wide and 4' high; 
 
SHEEP BARNS AND SHEDS. 
 
 103 
 
 
 
 
 
 | Stay 7?a.cA 4-S fe*f- | 
 
 
 
 
 
 
 
 Wd/J./— 
 
 | s/ayXkc-A /2/eeA~ \ 
 
 
 1 
 
 1 1 
 
 -ZZa-"i 6s 
 
 Z3 "?*'szrf 7^o o m. 
 
 1 1 
 
 Iham6i 
 
 */ 
 
 T 
 
 9nS 
 
 
 t"4 
 
 
 
 FIG. 172— A BABY MUTTON PACTOBT (GBOUND PLAN). 
 
 above this are two doors 8' wide which swing in, 
 and on either side of these two other doors which 
 also swing in. The windows above the center 
 doors may also be opened by swinging in from 
 the bottom. This arrangement makes it very easy 
 to turn this into an open or closed shed, as the 
 
 weather may demand. The water trough is of 
 galvanized iron and the amount of water is regu- 
 lated by an automatic float. As will be noted the 
 location of this water trough is such that the 
 sheep in all four pens into which the larger pen 
 may be divided have access to it. The doors in 
 the passageway on the north are arranged to give 
 greatest facility in changing sheep from pen to 
 pen. In the lambing season Mr. Hansen keeps 
 the ewes with twins and triplets in the smaller 
 pens where he has opportunity to give them extra 
 care if needed. Later these small pens with the 
 lamb creeps in position are used to feed the Jambs 
 their grain and some choice hay for their especial 
 benefit. At one end of the shed are the lambing 
 pens; a section is provided with a stove where 
 weak lambs may be cared for. At this end also 
 is the granary. Above the sheep pens there is 
 
 w 
 
 9 
 
 9 
 
 PEN 
 
 mss. 
 
 GRAIH 
 
 VPEN SHBp FOR U MBS 6 y£4fti//VG$ 
 W- WA KER 
 
 HORSE S 
 COW SHEO 
 
 SHED FOR COWS S HORSES 
 W - WATER S O-BATE 
 
 Si/PPUED by 
 WINOMILL 
 
 SROUf/D PLAN OF SHEEP SHED S BARN 
 
 DOOp 
 
 ( \DOOft\ 
 
 ! I \P0d»\'' IdooA I \ \DOOr\\ '• \ 
 
 HOVABU 
 mms emu 
 
 V 
 
 VOMBLE 
 L4MBCK&J 
 
 -,p 
 
 ^MOVABLE 
 WURDLE 
 
 TOPDOim\TOPDOOR'i>roPDOOR ' 'TOP DOOR 
 V 
 
 — 1 - ll 
 
 ENLARGED PLAN 
 OP ONE SECTION 
 
 BOTTOM DOOR; 
 
 CROSS SECTION 
 OP MANSER 
 
 CROSS SECTION OP SHEEP SHED 
 
 PIG. 173— A UTAH SHEEP BARN. 
 
104 
 
 FARM BUILDINGS. 
 
 FIG. 174— SHEEP BARN WITH GLASS COVERED LAMB SHED (END ELEVATION). 
 
 JfyloU* Core>\e*( Sko-d^ 
 
 i 1 
 
 FIG. 175— SHEEP BARN WITH GLASS COVERED LAMB SHED (ELOOR PLAN). 
 
SHEEP BABNS AND SHEDS. 
 
 105 
 
 storage room for about 100 tons of hay. The 
 rest of the hay is stacked about 100' west of the 
 shed. In the winter the hay is loaded from the 
 stack onto a wagon and with slings and a derrick 
 from 1,000 to 1,500 pounds of hay is transferred 
 at one lift to the car and from there through the 
 hay chutes to the mangers below. 
 
 South of the sheds are the yards or runs. By 
 the arrangement of the door and a gate, as shown, 
 there is either a driveway lb' wide along the 
 whole front of the shed or an open passage for 
 the sheep from the pen to the yard. The shed 
 on the north is for feeding the lambs during their 
 first winter. The arrangement is similar to the 
 breeding shed, but this is open in front of each 
 pen, no doors being provided. The hay is thrown 
 in from the wagon oh the north through doors 
 at the end of each manger. The sheep can be 
 divided as their feeding demands, 50 to 60 in a 
 pen. The shepherd can pass from pen to pen 
 through the boxes shown on the end of the long 
 mangers. 
 
 SHEEP BARN WITH GLASS-COVERED 
 . LAMB SHED. 
 This sheep barn for 100 ewes is distinctly a 
 sheep barn ; there is no room in the basement for 
 any other stock, while the floor above is all de- 
 voted to the storage of hay. Grain may be stored 
 in moderate amounts in bins built above the racks 
 at the side. 
 
 The plan (Pigs. 174 and 175) shows a building 
 36' square, with posts set 12' apart. The shed 
 at the side is also 12' wide and 36' long. It is 
 built with a brick, stone or wooden wall 4' high, 
 all above being glass, set as green-house glass. 
 
 1 The barn should face east and west, so that the 
 glass shed may be on the south side. At the end 
 there are doors at each bent so thai! wagons may 
 readily pass through to remove the manure. 
 These doors are all in two parts, the upper part 
 hinging at its upper edge and raising up as an 
 awning rises, the lower half swinging as a gate 
 swings. It will be noted in the floor plan that 
 there are two posts, set opposite the door posts 
 and 2' away, against which the doors may be fas- 
 tened if desired; this gives the sheep opportunity 
 to pass around the end of the hay-racks, or when 
 the doors are closed the barn is divided by the 
 hay-racks into three long pens. 
 
 In explanation of the floor plan (Pig. 175) H 
 shows hay-racks, which are also so constructed 
 that grain is fed in them at will; PP are posts 
 supporting the barn ; C shows the chutes 4' square 
 down which hay is thrown; DD are doors; WW 
 are water troughs ; GG the troughs or self-feeders 
 for lambs. The lambs gain access to this shed by 
 means of a creep and have it to their sole use 
 unless it is desirable to put a few old sheep there 
 so that they will have a better chance. 
 
 The elevation (Fig. 174) shows a type of joist 
 frame with open center and taking hay up from 
 the outside. It is 16' to the square, with half- 
 pitch roof and holds ample forage for the 100 
 ewes and their lambs. For cheapness, conven- 
 ience, good ventilation, comfort to the sheep and 
 general all-around practicability this barn is ad- 
 mirable. With the upper doors raised and the 
 wind circulating through, it is cool in summer; 
 with the doors lowered it is a warm winter barn 
 and with the ventilation that comes from the 
 hay chutes there is never any danger of too much 
 closeness in it. 
 
 INTERIOR ARRANGEMENT OF SHEEP 
 BARN. 
 
 The sheep barn in which the arrangement of 
 hay-racks is shown (Fig. 176) is 34' x 50'. In 
 Fig. 176 H stands between the posts dividing the 
 barn into four compartments. Each rack is sep- 
 arate from the building and may be removed or 
 turned around across the alleys if desired. At 
 each end of alley is a door of full width to admit 
 of a team passing through for convenience of 
 cleaning out manure and also to allow of perfect 
 ventilation. These doors should be in halves, 
 divided horizontally, the lower half swinging, 
 the upper half raising on hinges affixed to its 
 upper edge. This confines the sheep while allow- 
 ing free circulation of air. 
 
 The doors' are hung by common strap hinges, 
 12" or 16" size, and are held open by two %" 
 ropes fastened up about 10' and with rings in 
 them that catch in spikes driven in lower edge of 
 doors. A good way is to use small wire rope, as 
 the weather will not affect it. There may easily 
 be devised other convenient devices for raising 
 the doors. 
 
 C is the hay chute, and through it by means of 
 a ladder the mow is reached. W is either a hay- 
 rack or watering-trough, as thought best. If a 
 trough it is not so wide. It may be supplied 
 either by a hydrant or float-valve. It is better 
 to have water in the yard on the south side of 
 the barn, there being comparatively few days 
 when it is so cold that the sheep would not prefer 
 to drink there. 
 
 To give access to the various alleyways the 
 arrangement shown at P and R is very satis- 
 factory. It consists of an extra post in the ground 
 about 2' from the barn. To this post the doors 
 latch when desired, allowing man or sheep to 
 pass from one alley to the other. This is used 
 during mild weather when the sheep are not de- 
 sired separated into flocks. One such arrange- 
 ment is to be put on the opposite side of the barn. 
 
 There may also be gates through the hay-racks 
 but that is a waste of rack space. Hay is taken 
 from either side of the chute, so that all racks 
 are filled without traveling across the line of the 
 
106 
 
 FARM BUILDINGS. 
 
 m 
 
 w 
 
 w 
 
 1TIG. 176— INTERIOR ARRANGEMENT OP SHEEP BARN. 
 
 hay-racks. The arrangement of doors at P allows 
 of the sheep being assorted while passing through, 
 the operator standing at the door and by opening 
 or closing it turning the sheep into yard or into 
 adjacent alley. 
 
 Fig. 177 shows a cross section of one alley with 
 
 -INTERIOR ARRANGEMENT Off SHEEP BARN 
 (CROSS SECTIONS). 
 
 section of the hay-racks adjusted to receive the 
 hay. These racks are used for either hay or grain 
 and when grain is to be put in the hinged sides 
 are turned over, maiding a square box open at the 
 top into which the ewes cannot see. The grain 
 is then put in and all filled, the sides are turned 
 back as shown and at once the ewes begin eating 
 at nearly the same time. It may also be desirable 
 to provide a few self-feeders for the ewes suckling 
 their lambs. A, Fig. 177, represents a meal bin 
 which may extend along a good part of each side. 
 It is filled at D from outside (or inside if 
 preferred) and the meal is drawn out at B. The 
 meals should be mixed before being put into this 
 bin. 
 
 SMALL SHEEP BAEN. 
 
 The plan and elevation (Figs. 178 and 179) 
 are of Joseph E. Wing's designing and of the 
 barn he says : "For the average farm it is nearly 
 an ideal sheep house. It may be built of any 
 length and may inclose two or three sides of a 
 yard. Being narrow it is readily ventilated and 
 
SHEEP BABN8 AND SHEDS. 
 
 107 
 
 XIG. 178— SHALL SHEEP BARN (END AND SIDE CONSTRUCTION) . 
 
 
 J 1 II II 1 i 
 
 ,': SHEEP BARN / 
 '''■;,*" GROUND PLAN 20X36' 
 
 ] | || HAY RACKS | | | r 
 
 
 troughs. While the sheep eat grain, hay is placed 
 in their quarters to- which they return. The 
 building is of joist construction with curb roof. 
 The middle part contains large cribs and bins to 
 
 FIG. 179— SMALL SHEEP BABN (GROUND PLAN). 
 
 is easily divided to accommodate the breeding 
 flock. There is no waste material in the frame 
 and no encumbering .posts. The height to plate 
 is 16', the width 20'; this width without central 
 posts makes necessary the use of the 2" x 16" 
 joist-bearers and the long supporting braces. Hay- 
 racks are put in anywhere but should be of such 
 length that two of them turned crossways will 
 make a division in the room. The doors should 
 permit driving through lengthways and crossways. 
 The bents may be 12' or 14' apart, better 12', 
 so as not too heavily to burden the joist-bearers." 
 
 BARN FOR FEEDING SHEEP. 
 
 It was the idea of a feeder in Illinois to have 
 a bam to hold 500 sheep with four pens of 125 
 each and an extra pen in which grain would be 
 fed, all under cover. This building was designed 
 for him and is made up of five squares each 40' 
 x40'. (See Fig. 180.) The central square is 
 for feeding and each flock takes its turn at the 
 
 
 
 
 
 
 J 
 
 u ,.„ u 
 
 L 
 
 
 
 
 
 
 
 
 
 
 3 
 
 o a 
 
 c 
 
 
 
 
 
 
 
 
 
 
 3 
 
 a a 
 
 c 
 
 
 
 
 
 j , r L 
 
 14 
 
 " 
 
 4 
 
 3 
 
 UtiAlbU" 
 
 '"■' ' u 
 
 ■— o- - 
 
 u — 
 
 -" *T 
 
 s 
 
 
 
 
 
 
 
 
 
 
 
 3 
 
 D 
 
 
 D 
 
 
 1 
 
 D POSTS D 
 
 D 
 
 D 
 
 a 
 
 E 
 
 n 
 
 
 
 
 GATE 
 
 
 GATE 
 
 
 
 
 i 
 
 O 
 
 
 O 
 
 
 ] 
 
 d a 
 
 c 
 
 
 a 
 
 a 
 
 C 
 
 I 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 n 
 
 r» 
 
 
 
 
 40 
 
 
 
 1 
 
 1 
 
 a d 
 
 O D 
 
 t 
 
 1 
 
 
 
 
 
 
 
 
 
 
 ■, M n K n 
 
 U , 
 
 
 
 
 
 FIG. 180— BABN FOE FEEDING SHEEP. 
 
 which grain is elevated by horse-power.' The 
 upper story is lighted from the roof. 
 
 A SHEEP FEEDING SHED. 
 
 A cheap and practical shed for feeding about 
 400 lambs is thus described: 
 
 Fig. 182 shows an elevation of the frame. The 
 
108 
 
 FABM BUILDINGS. 
 
 rear is 6' high, the front 24', and the width 40'. 
 A portion of the higher part is floored to hold 
 hay. All of two bents may be floored if desired. 
 The frame should be of the simplest, either 6" 
 
 FIG. 182 — A SHEEP FEEDING SHED (SIDE ELEVATION). 
 
 x 6" posts with joist-construction plates and tier 
 or all of joist construction. The plates should be 
 2"xl0"; the roof should , be of shingles, which 
 should be nailed with either galvanized wire nails 
 or cut nails. Common wire nails do not last well. 
 
 Fig. 181 shows the front elevation of the shed. 
 The doors turn to the south and each bent has 
 its large half -door. It is not necessary to provide 
 doors to the space above the half-doors. In feed- 
 ing lambs these spaces would not need to be closed 
 on the south side often enough . in a season to 
 make it worth providing them. If they are pro- 
 vided with doors they should be hinged at the 
 upper edge so as to open upward. 
 
 The length of this building is 60'. The bents 
 are spaced 12' from center to center. Hay is 
 put in through the upper windows. A track 
 could be attached to the rafters and hay taken in 
 by carrier at the end. 
 
 The floor-plan is shown in Fig. 183. The racks 
 are not stationary. Doors are provided at the 
 middle of each end, so that a team may pass 
 through when cleaning out manure. The racks 
 may be set aside from the middle bents during 
 this process. Water will flow through all the 
 troughs or be kept at a level by means of float- 
 valves. 
 
 A LAMBING BARN FOR THE SOUTH. 
 
 The lambing barn illustrated in Figs. 184, 185 
 and 186 has a joist frame but has no interior 
 posts, the width being but 20' and the joist- 
 
 183 — A SHEEP FEEDING SHED (FLOOB PLAN). 
 
 FIG. 184— A LAMBING BARN FOB THE SOUTH (FBONT ELEVATION). 
 
 bearers running crossways of the frame and made 
 of three pieces of 2" x 16" stuff and further sup- 
 ported by braces above and below. The upper 
 brace passes between two of these joist-bearers 
 and also between the two pieces of 2" x 8" (see 
 Fig. 185) that compose the posts which sustain 
 a good deal of weight, leaving the joist-bearers 
 only 10' of unsupported span. The floor joists 
 should be let in between these joist-bearers; that 
 is, cut just long enough to slip down and spike 
 fast at the ends, so there will be no waste of space 
 as would be by putting them on top. There is 
 no great weight to sustain. 
 
 The nail girts are simple 2" x 4" or 2" x 6" 
 spiked on. A track runs the length of the barn 
 under the peak. The building is three parts of 
 a hollow square, enclosing a court open to the 
 
SHEEP BABNS AND "SHEDS. 
 
 109 
 
 sky 60' x 80' (Fig 186). In this will be a tank, 
 preferably of cement, into which the roof water 
 is led and maybe a spring made to pour through 
 
 FIG. 185— A LAMBING BARN FOB THE SOUTH (CONSTRUCTION) 
 
 a pipe. Of course the open side is to the south. 
 On two sides are many small 4'x4' pens, in 
 which ewes may be confined at lambing time; 
 
 FIG. 186— A LAMBING BARN FOR THB SOUTH (GROUND PLAN). 
 
 these may be stationary or movable. Simple panels 
 4' long, two hinged together and provided with 
 hooks so as to be put together as nailed, is an 
 admirable arrangement, as it gives all the space 
 to the flock except when pens are needed. It 
 will be noted that there are many pens divided 
 
 off by the feed-racks, each opening by a wide 
 door to the yard, so that one can separate the 
 ewes according to his needs, or, turning the feed- 
 racks about, throw two or all of them together. 
 On one side is the creep for the winter lambs. 
 The doors are all on the court side and are double, 
 one opening as common doors and gates do, the 
 other swinging up as an awning swings, to let 
 in a little air or a great deal of the sun, as de- 
 sired. The court should be cemented or paved 
 so there will never be mud, and the gate to the 
 court should swing either way so sheep can never 
 crowd it shut and injure themselves. There 
 should be spouting along the court side of the 
 building to carry away the drip. This building 
 is nearly ideal for a Southern situation where the 
 ewes get a considerable part of their feed in the 
 fields yet require some forage, grain and shelter. 
 It does not hold enough forage for a far Northern 
 location but could be built wider and taller. 
 
 A LAMBING SHED. 
 
 While there is no doubt that lambs born in 
 winter are generally worth more than those born 
 later there is more or less risk in having them 
 appear in the ordinary ewe sheds. Good manage- 
 ment, therefore, dictates that there should be 
 provided a small building apart from the regu- 
 lar sheep barn where the most forward ewes may 
 be drafted and where they may go through the 
 ordeal of delivery with more attention and 
 greater quiet than can be had in the usual quar- 
 ters. There are times too when artificial heat is 
 essential. 
 
 The lambing-shed illustrated in Fig. 187 is 
 light, warm, easily ventilated, the feed is above 
 where enough hay is easily stored to carry the 
 stock below through the season, the access is con- 
 venient and the manure easily removed. Fur- 
 thermore, it is cheaply built. Reference to the 
 floor plan shows the arrangement of the pens. 
 The water is in half -barrels, all on the same level, 
 connected by means of iron pipe that is buried 
 in the ground and enters the tubs at the bottom. 
 This -arrangement insures against freezing and 
 each tub will have in it the same amount of 
 water. A float-valve in the supply pipe will 
 regulate the water in each. 
 
 The gates to the pens are so arranged that 
 when they open they hook across the passage, 
 thus closing it and making it easy to direct sheep 
 to any desired pen. The feed-racks are so ar- 
 ranged that lambs can not creep into or through 
 them. At one end there is a room finished off 
 nicely for the shepherd. The pen next to the 
 shepherd's room is completely separated from the 
 other pens by a tight partition reaching to the 
 ceiling, the other pens being merely separated bv 
 the feed-racks. Between the closed pen and the 
 
110 
 
 FABM BUILDINGS. 
 
 shepherd's room there is a sliding door next the 
 stove. One side of the door is covered with zinc. 
 There also is a sliding lath gate, so that by open- 
 ing the door and closing the gate the heat from 
 the stove will enter the pen. Entrance to this 
 
 it not being practicable to use machinery in so 
 small a building. 
 
 As this building should be free from draughts 
 it is well to build of good matched siding with 
 paper under it or of rough siding and plaster out- 
 
 
 
 — r 
 
 ■ 
 
 
 m 
 
 1 1 1 1 1 
 
 rtrtl 
 
 FFffl 
 
 FFffl 
 
 era 
 
 FRONT ELEVATION OF SHEEP HOSPITAL 
 
 SIDE ELEVATION 
 
 rip 
 
 o 
 
 uxia I || I 
 
 rEEOI.RACt 
 
 J>:::^:"« 
 
 TP 
 
 AUTIFOIAL HEAT V 
 IJUH 
 
 .' FEEDING ALLEY 
 
 
 SHEPHERDS 
 
 ROOM 
 
 ^ 
 
 TLOOR PLAN OF SHEEP HOSPITAL 
 FIG. 187— A LAMBING SHED. 
 
 pen is also secured by opening the little gate by 
 the stove. 
 
 Plenty of glass is provided so that the sun may 
 come in, and at the rear of each pen is a door out 
 of which the manure is thrown. Hay is pitched 
 into the loft by hand through the front windows, 
 
 side the lower story. The windows must face the 
 south or southeast and it may be built any de- 
 sired length, although if intended to be very long 
 part of it may well be turned in the form of an 
 L. As fast as the lambs" grow strong and able 
 to endure the cold they are drafted out. 
 
POULTRY HOUSES. 
 
 Too often, says Prof. G-. C. Watson in Bulletin 
 No. 41, United States Department of Agricul- 
 ture, the location of the poultry house is thought 
 to be of minor importance and consequently is 
 given less consideration than any other farm 
 building. Frequently the other buildings are 
 located first and the poultry house then placed 
 on the most convenient space, when it should 
 have received consideration before the larger 
 buildings were all located. 
 
 In caring for the various classes of live stock 
 the question of labor is always an important item, 
 and the class that requires the closest attention 
 to petty details as a rule requires the greatest 
 amount of labor. As poultry-keeping is wholly 
 a business of details the economy of labor in 
 performing the necessary work is of great im- 
 portance. Buildings not conveniently located 
 and arranged become expensive on account of 
 unnecessary labor. 
 
 As it is necessary to visit poultry houses several 
 times each day in the year convenience is of more 
 importance than in case of almost any other farm 
 building. The operations must be performed fre- 
 quently, so that any little inconvenience in the 
 arrangements of the buildings will cause not only 
 extra expense in the care but in many cases a 
 greater or less neglect of operations that ought 
 to be performed carefully each day. 
 
 Poultry houses are likely to be more or less 
 infested with rats and mice unless some means 
 are provided to exclude them, and this should be 
 taken into account in selecting a location. It is 
 generally best to locate the poultry house at some 
 distance from other farm buildings, especially if 
 grain is kept in the latter. Convenience of access 
 and freedom from vermin are two desirable points 
 to be secured, and they depend largely on the 
 location. Everything considered it is safest to 
 have the house quite isolated. 
 
 A dry, porous soil is always to be preferred as 
 a site for buildings and yards. Cleanliness and 
 freedom from moisture must be secured if the 
 greatest success is to be attained. Without doubt 
 filth and moisture are the causes, either directly 
 or indirectly, of the majority of poultry diseases, 
 and form the stumbling block which brings dis- 
 
 couragement and failure to many amateurs. It 
 must not be inferred that poultry cannot be suc- 
 cessfully reared and profitably kept on heavy 
 soils, for abundant proof to the contrary is readily 
 furnished by successful poultrymen who have to 
 contend with this kind of land. The necessity 
 for cleanliness, however, is not disputed by those 
 who have had extended experience in caring for 
 fowls, particularly the less hardy breeds. That 
 an open, porous soil can be kept comparatively 
 clean with much less labor than a clay soil will 
 be evident to those who are at all acquainted with 
 the habits of domesticated fowls. When the fowls 
 are confined in buildings and yards that part of 
 the yard nearest the buildings will become more 
 or less filthy from the droppings and continual 
 tramping to which it is subjected. A heavy or 
 clayey soil not only retains all of the manure on 
 the surface, but by retarding percolation at times 
 of frequent showers aids materially in giving to 
 the whole surface a complete coating of filth. If 
 a knoll or ridge can be selected where natural 
 drainage is perfect the ideal condition will be 
 nearly approached. Where natural favorable con- 
 ditions as to drainage do not exist thorough under 
 drainage will go a long way toward making the 
 necessary amends to insure success. 
 
 The material to be used in the construction and 
 the manner of building will necessarily be gov- 
 erned largely by the climatic conditions. In 
 general it may be said that the house should pro- 
 vide warm, dry, well lighted and well ventilated 
 quarters for the fowls. In order to meet these 
 requirements it will be necessary to provide a 
 good roof with side walls more or less impervious 
 to moisture and cold, suitable arrangements for 
 lighting and ventilating and some means for ex- 
 cluding the moisture from beneath. Where 
 permanent buildings are to be erected some pro- 
 vision should be made to exclude rats and mice, 
 and for this reason if for no other the structure 
 should be placed on cement walls with foundation 
 below the frost line. Cheap, efficient walls may 
 be made of small field stone in the following 
 manner: Dig trenches for the walls below the 
 frost line; drive two rows of stakes in the 
 trenches, one row at each side of the trench and 
 
112 
 
 FABM BUILDINGS. 
 
 board inside of the stakes. The boards simply 
 hold the stones and cement \& place until the 
 cement hardens. Eough and uneven boards will 
 answer every purpose except for the top ones, 
 which should have the upper edge straight and 
 be placed level to determine the top of the wall. 
 Place two or three layers of stone in the bottom 
 of the trench, put on cement mixed rather thin 
 and pound down; repeat this operation until the 
 desired height is obtained. The top of the wall 
 can be smoothed off with a trowel or ditching 
 spade and left until the cement becomes hard, 
 when it will be ready for the building. The 
 boards at the sides may be removed if desirable 
 at any time after the cement becomes hard. 
 
 For the colder latitudes a house with hollow or 
 double side walls is to be preferred on many ac- 
 counts, although a solid wall may prove quite 
 satisfactory, particularly if the building is in the 
 
 TIG. 188— SHOWING METHOD Or CONSTRUCTION. 
 
 hands of a skilled poultryman. Imperfect build- 
 ings and appliances when under the management 
 of skilled and experienced men are not the hin- 
 drances that they would be to the amateur. 
 Buildings with hollow side walls are warmer in 
 winter and cooler in summer, with less frost in 
 severe weather and less resulting moisture when 
 the temperature moderates sufficiently to melt 
 the frost from the walls and roof of the house. ' 
 A cheap efficient house may be made of two 
 thicknesses of rough inch lumber for the side and 
 end walls. This siding should be put on ver- 
 tically, with good quality of tarred building paper 
 between. In constructing a building of this kind 
 it is usually best to nail on the inner layer of 
 boards first, then put on the outside of this layer 
 the building paper in such a manner that the 
 whole surface is covered. Where the edges of the 
 
 paper meet a liberal lap should be given, the 
 object being to prevent as far as possible draughts 
 of air in severe weather. Nail the second thick- 
 ness of boa'rds on the building paper so as to 
 break joints in the two boardings. In select- 
 ing lumber for siding it is best to choose boards 
 of a uniform width to facilitate the breaking of 
 joints. 
 
 In constructing a roof for a house in the colder 
 latitudes one of two courses must be pursued: 
 either to ceil the inside with some material to 
 exclude draughts or to place the roof boards close 
 together and cover thoroughly with tarred paper 
 before shingling. The ordinary shingle roof is 
 too open for windy weather when the mercury 
 is at or below the zero mark. The fowls will 
 endure severe weather without suffering from 
 
 Tar Paper' 
 
 ri'HW^y^S- 
 
 
 FIG. 189— SHOWING HOLLOW WALLS AND FOUNDATION. 
 
 frosted combs or wattles if there are no draughts 
 of air. Hens will lay well during the winter 
 months if the houses are warm enough so that 
 the single-comb varieties do not suffer from frost 
 bite. Whenever the combs or wattles are frozen 
 the loss in decreased egg production cannot be 
 other than serious. 
 
 Figs. 188 and 189 represent a cheap and effi- 
 cient method of building a poultry-house with a 
 hollow side wall. The sill may be a 2" x 6" or 
 2" x 8" scantling, laid flat on the wall or founda- 
 tion ; a 2" x 2" strip is nailed at the outer edge 
 to give the size of the space between the boards 
 which constitute the side walls. A 2" x 3" 
 scantling set edgewise forms the plate and to this 
 the boards may be of rough lumber if economv 
 
POULTBY HOUSES. 
 
 113' 
 
 in building is desired. If so the inner boarding 
 should be nailed on first and covered with tarred 
 building paper on the side that will come within 
 the hollow wall when the building is completed. 
 This building paper is to be held in place with 
 laths or strips of thin boards. If only small nails 
 or tacks are used the paper will tear around 
 ' the nail heads when damp and will not stay in 
 place. 
 
 The cracks between the boards of the outside 
 boarding may be covered with inexpensive bat- 
 tens if they are nailed at frequent intervals with 
 small nails. Ordinary building laths will answer 
 this purpose admirably and will last many years, 
 although they are not so durable as heavier and 
 more expensive strips. The tarred paper on the 
 inside boarding and. the battens on the outside 
 make two walls, each impervious to wind, with 
 an air-space between them. 
 
 In preparing plans for a building one of the 
 first questions to be decided is the size and form 
 of the house. If the buildings are made with the 
 corners right angles there is no form so econom- 
 ical as a square building. This form will inclose 
 more square feet of floor space for a given amount 
 of lumber than any other, but for some reasons 
 a square building is not so well adapted for fowls 
 as one that is much longer than wide. Tt is 
 essential to have the. different pens or divisions in 
 the house so arranged that each one will receive 
 as much sunlight as possible, and to secure this 
 some sacrifice in economy of building must be 
 made. 
 
 Many poultrymen prefer a building one story 
 high and not less than 10 nor more than 14' wide 
 and as long as circumstances require. In most 
 cases a building 30' to 60' long meets all require- 
 ments. If this does not give room enough it is 
 better to construct other buildings than extend 
 one building more than 60'. It must' be remem- 
 bered that each pen in the building should have 
 a separate yard or run and that a pen should not 
 be made to accommodate more than 50 fowls, or 
 better 30 to 40. 
 
 The building should extend nearly east and 
 west in order that as much sunshine as possible 
 may be admitted through windows on the south 
 side. The windows should not be large nor more 
 than one to every 8' or 10' in length for a house 
 12' wide, and about 17" from the floor, or at 
 such height that as much sunshine as possible 
 will be thrown on the floor. The size and form 
 of the windows will determine quite largely their 
 location., In all poultry houses in cold latitudes 
 the windows should be placed in such position 
 that they will give the most sunlight on the floor 
 during the severe winter months. One of the 
 common mistakes is in putting in too many win- 
 dows. While a building that admits plenty of 
 
 sunlight in winter time is desirable a cold one is 
 equally undesirable and windows are a source of 
 radiation at night unless shutters or curtains are 
 provided. Sliding windows are preferred on 
 many accounts. They can be partially opened for 
 ventilation on warm days. The base or rail on 
 which the window slides should be made of sev- 
 eral pieces fastened an inch or so apart, through 
 which openings the dirt that is sure to accumulate 
 in poultry houses may drop and insure free move- 
 ment of the window. 
 
 Some means of ventilating the building should 
 be provided. A ventilator that can be opened and 
 closed at the will of the attendant will give good 
 results if given proper attention, and without 
 attention no ventilator will give best results. All 
 ventilators that are in continuous operation either 
 give too much ventilation at night or too little 
 during the warm parts of the day. Ventilators 
 are not needed in severe cold weather, but during 
 the first warm days of early spring and whenever 
 the temperature rises above the freezing point 
 during the winter months some ventilation should 
 be ' provided. Houses with single walls will 
 become quite frosty on the inside during severe 
 weather, which will cause considerable dampness 
 whenever the temperature rises sufficiently to 
 thaw out all the frost of the side walls and roof. 
 At this time a ventilator is most needed. 
 
 A ventilator in the highest part of the roof 
 that can be closed tightly by means of cords or 
 chains answers the purpose admirably and may 
 be constructed with little expense. The ease and 
 convenience of operation are important points 
 and should not be neglected when the building 
 is being constructed. It is a simple matter for 
 the attendant to open or close a ventilator as he 
 passes through the house if the appliances for 
 operating it are within easy reach. Fig. 188 rep- 
 resents an efficient and easily operated venti- 
 lator. 
 
 Perches should not be more than 2%' from the 
 floor and should be all of the same height. Many 
 fowls prefer to perch as far above the ground as 
 possible in order without doubt to be more secure 
 from their natural enemies; but when fowls are 
 protected artificially from skunks, minks and 
 foxes, a low perch is just as safe and a great deal 
 better for the heavy-bodied fowls. It must be 
 borne in mind that the distance given at which 
 perches should be placed from the floor applies 
 to all breeds of fowls. It is true that some of 
 the Mediterranean fowls would not in any way 
 be injured in flying to and from the perches, but 
 some of the heavy breeds would find it almost 
 impossible to reach high perches and would sus- 
 tain positive injuries in alighting on the floor 
 from any considerable elevation. Convenient 
 walks or ladders can be constructed which will 
 
114 
 
 FABM BV1LDINGIS. 
 
 enable the large fowls to approach the perches 
 without great effort, but there are always times 
 when even the most clumsy fowls will attempt 
 to fly from the perch to the floor and come down 
 with a heavy thud, which is often injurious. 
 And furthermore ladders or stairs for the easy 
 ascent of fowls are more or less of a nuisance in 
 the poultry house. The ideal interior arrange- 
 ment of the house is to have everything that is 
 needed in as simple a form as possible and not 
 to complicate the arrangement by any unneces- 
 sary apparatus. The fewer and simpler the 
 interior arrangements the easier the house can 
 be kept clean and the greater the floor space 
 available for the fowls. 
 
 There is no reason why all the perches should 
 not be placed near the floor. Movable perches 
 are to be preferred. A 2" x 3" scantling set edge- 
 wise with the upper corners rounded answers 
 
 the platform and perches need not be more than 
 6". The droppings should be removed every day. 
 
 A CONVENIENT POULTRY HOUSE. 
 
 Fig. 190 shows a very handy poultry house that 
 is 28' long and 20' wide with hall 4' wide run- 
 ning lengthways through the center. The house 
 is divided, into eight rooms, four on each side' 
 of the aisle, leaving a space 7' x 8' for each room. 
 The 6" x 6" sills can be used laid on stone or 
 blocks set in the ground. Use 4" x 4"s for up-and- 
 down studding spiked 2%' apart on top of the 
 sills. Use 2"x6"s for floor joists 20' long, spiked 
 to up-and-down posts. Floor with common inch- 
 flooring or cement. The center posts, 4" x 4"s, 
 are spiked on top of sills 4' apart each way, leav- 
 ing a 4' aisle through the center of house. The 
 plates on top of the posts and the rafters are 
 2" x4"s. Drop siding is best for the studding. 
 
 FIG. 190— A CONVENIENT POULTRY HOUSE. 
 
 every purpose and makes a satisfactory perch. 
 The perches should be firm and should not tip 
 or rock. The form of the scantling makes it easy 
 to secure them firmly and still have them remov- 
 able. 
 
 Underneath the perches should always be 
 placed a smooth platform to catch the droppings. 
 This is necessary for two reasons : the droppings 
 are valuable for fertilizing purposes and ought 
 not to be mixed with the litter on the floor ; then 
 too if the droppings are kept separate and in a 
 convenient place to remove it is much easier to 
 keep the house clean than when they are allowed 
 to become more or less scattered by the tramping 
 and scratching of fowls. The distance of the 
 platform from the perch will be governed some- 
 what 'by the means employed for removing the 
 droppings. If "a broad iron shovel with a toler- 
 ably straight handle is used the space between 
 
 The roof is sheeted and shingled. The inside of 
 the house should be plastered with cement plaster. 
 When plastered it is easy to exterminate lice or 
 mites and the plastering can be easily white- 
 washed and swept off clean. 
 
 The partitions and inside doors should all be 
 wire poultry-netting fastened on strong frames 
 so that all can be removed when the breeding 
 season is over and the whole house be used in one 
 or two parts one on each side. Roosts to perch 
 on are not generally used in this house where the 
 large breeds are kept. The floor covered with 
 straw three or four inches thick makes a good 
 roost for large breeds. It is claimed they will 
 do better and never have bumble foot. The straw 
 should be swept out once a week and fresh straw 
 supplied. 
 
 The windows may be of any suitable size. The 
 upper windows are half as large as the lower ones. 
 
PUUL1&Y HOUSES. 
 
 115 
 
 No more windows should be used than the dia- 
 gram shows, as too much glass light is said to be 
 injurious to poultry. 
 
 The yards outside should be 10' wide and at 
 least 100' long. To get four yards 10' on each 
 side of the house the corner pens must be brought 
 out G' on each corner of house. This leaves 4' 
 of the house for each of the outside pens. These 
 pens should also be bedded with straw or litter 
 of some kind from three to five inches deep and 
 all grain fed should be strewn, in this to make 
 the hens work most of their time. 
 
 A SUMMER HEN HOUSE. 
 
 A practice in some communities is to close up 
 the winter quarters of fowls and compel them to 
 
 constructed adjacent to the regular house or 
 apart from it and will serve the purpose of a 
 protection to the fowls during the night almost 
 as effectually as though they were shut in winter 
 quarters under lock and key, provided always 
 that the lock is also applied to the latter. 
 
 Its general plan of construction is shown quite 
 plainly in the halftone. It has a shed roof and 
 stands with an end to the other poultry house. 
 The back and the other end are sided with rough 
 lumber. The front is left almost entirely open 
 save for the covering of poultry netting, which 
 serves the purpose of a front and yet is perfectly 
 open to the air. There is also a door by which 
 the structure may be entered independently of 
 the regular house. The summer house should 
 
 FIG. 191— A SUMMER HEN HOUSE. 
 
 seek shelter elsewhere during the hot summer 
 weather, the object being to rid the house of 
 vermin, avoid further care of the fowls and give 
 the poultry a cooler roosting place. Those who 
 thus close the hen houses up and turn the poultry 
 out make the mistake of not providing other 
 quarters. The poultry will to some extent take 
 to the trees and this will teach the young fowls 
 to roost there, which not only exposes them to 
 danger during the night but renders it difficult 
 to accustom them to going into a house when 
 fall approaches. 
 
 A poultry house is illustrated in Fig. 191 that 
 has the advantage of being quickly and easily 
 
 include an exit other than the regular door for 
 the poultry. After such a house has served its 
 purpose for a summer shelter it still has a further 
 usefulness during the winter as a combination 
 scratching shed and sunning place for the poul- 
 try. If this is in view the shed should be closely 
 attached to the regular poultry house. Whether 
 the house is to be used for summer or for both 
 summer and winter it should have a water-tight 
 roof. 
 
 A FARM HEN HOUSE. 
 
 A cheap and convenient poultry house that can 
 be built by any farmer is illustrated in Fig. 
 
116 
 
 FABM BUILDINGS. 
 
 192. The building is 10' x 24' and should stand 
 facing the south. The sides and ends can be 
 made of rough boards and the cracks battened 
 with laths or strips inside and out, or matched 
 boards can be used and lined inside with building 
 paper. It can be made any height desired and 
 the roof can be made ofi shingles or matched and 
 grooved boards well painted. Fig. 192 gives an 
 end view of the inside. A partition should 
 extend the full length 4' from the north side. 
 This will make an entry (A) 6' x-24' and a room 
 (B) 4' x 24', which can be made in two pens 
 6' x 12' if desired. C is a movable floor with two 
 roosting poles attached. D is nest boxes, extend- 
 ing into the entry, with lids so eggs can be gath- 
 ered without going inside the pen. E is a eleated 
 board leading to the nests. The space F is made 
 of slats so fowls can reach through to the drink- 
 
 «f ffiltfrJJu il Alia i , „ , n | f] J I JlMilttS^^ 
 
 l^j^nl 
 
 MG. 192— A FABM HEN HOUSE. 
 
 ing trough G. H is a sliding door for the ingress 
 and egress of fowls which can be opened and 
 closed from entry by means of a cord. I J is a 
 door leading from the entry to the pen. 
 
 AN ILLINOIS POULTRY HOUSE. 
 
 The poultry house shown in Fig. 193 is 7' x 16' 
 and T high at the front side and 4' at the back, 
 with a shed roof. It may be built of 2" x 4"s for 
 frame, covered with common rough or dressed 
 boards and battened on the outside with planed 
 or rough battens. Shingles are better for roof 
 than tarred paper, which does not make a durable 
 roof. To make it warm the house should be lined 
 inside with tarred paper and should have at least 
 two 9" x 13" six-light windows in the south side 
 near the center of the building. A half-dozen flat 
 stones may be used for a foundation just set even 
 with the surface so as to allow the sills to clear 
 
 the ground. Gravel or cinders to the depth of 
 6" may be used for floor. All surface water in 
 winter and early spring should be kept out. The 
 gravel or cinders may be covered with sand so as 
 to make a smooth surface. 
 
 The roosts should be built 6n the north side 
 of inch boards cut into 4" strips and should have 
 the edges made rounding and set flat side down 
 in notches cut in brackets extending from the 
 back side of the coop. The perches are 2%' above 
 the floor and under them is suspended a platform 
 to receive the droppings, which can be easily 
 removed every morning or twice a week. The 
 floor can be kept clean by using a common garden 
 rake and raking up all the droppings that may 
 be scattered during the day. The material for 
 the house shown in Fig. 193 costs exclusive of 
 floor and paint about $12. 
 
 To build the yards connected with the house 
 
 FIG 193— AN ILLINOIS POULTRY HOUSE. 
 
 set posts 12' apart and board up 2' from the 
 ground with common rough 12" boards; then 
 above that use 2" mesh poultry netting 36" wide. 
 This makes a fence 5' high and no fowl except 
 some of the small breeds will ever fly over it. 
 The boards at the bottom are to keep cocks from 
 fighting through the fence. If desired this house 
 can be used for breeding fowls to accommodate 
 two yards of 12 fowls each by running a partition 
 through the center and having eaph yard connect 
 with one end of, the house. The yards should be 
 three rods wide and six rods long, north and 
 south, with the north end connecting with the 
 house. If a large number of fowls is to be kept 
 a number of these houses can be built in a row, 
 all facing the south, far enough apart to admit 
 of the runs or yards being built three rods wide. 
 In this case a tight fence can be built between 
 the houses on the north side to keep the cold 
 wind from the fowls. 
 
 DESIGN FOR A POULTRY HOUSE. 
 
 The poultry house shown in Fig. 194 has some 
 good points about it not generally used. It 
 accommodates 100 hens and is 20' long, 12' wide 
 
POULTRY HOUSES. 
 
 117 
 
 and 12' high at the back side. It has a dirt- 
 proof roosting floor running from the top of the 
 back side to near the bottom of the front. This 
 floor is made of cheap flooring boards and lacks 
 2' of being the full length of the building. This 
 space allows one to pass from the house proper 
 to the perches, which are placed along on the 
 upper side of this slanting floor far enough apart 
 to be perfectly clear of each other, the droppings 
 rolling down in front of and outside the build- 
 ing. Underneath the bottom of this floor is made 
 a run extending half-way across the width of the 
 building. The top of the run is intended for nests. 
 At the bottom of the back are two rows of secret 
 nests. Make a number of windows in the south 
 and at least two in the back. The perches should 
 not come nearer than 6" of the slanting floor 
 and should be easily removed for cleansing and 
 whitewashing as often as desired. All nests 
 should be movable, one at a time if wanted. An 
 earthen or cement floor may be used. At the 
 
 FIG. 194— DHSIGfl FOB A POULTRY HOUSE. 
 
 bottom of the perches lay a flat board on which 
 to walk. 
 
 The secret nests open on the inside but are 
 built on the outside. Chickens enter at the door 
 and a small open window which is made above 
 the slanting floor at the back end. The opening 
 at the bottom of the slanting floor is about 6" 
 in the clear. The building faces south and has 
 the door or entry way in the east. The double 
 row of secret nests is to the right. * Another row 
 
 of nests is made to the left. These nests are 
 built upon the run, which is open only under 
 the south side of the building. The upper half 
 of the south side is made chiefly of glass. 
 
 A G-OOD TYPE OF HEN HOUSE. 
 
 One of the essential characteristics of a model 
 poultry house is that it shall not be too expen- 
 sive to be within the reach of the average farmer. 
 Another essential is that it be warm and another 
 
 FIG. 195— A GOOD TYPE OF HEN HOUSE. 
 
 that it be well lighted. The illustration (Fig. 
 195) very nearly explains itself. The front of 
 the house should face the south. It is 10' high 
 in front and 6' in the rear. With a width of 12' 
 the house may be built of 16' boards without 
 waste. No frame is needed except the horizontal 
 girts. Braces should be cut and nailed diagonally 
 to stiffen the building. Put several windows in 
 the front to let in sunlight in winter. All roosts 
 should be on the same level or there will be end- 
 less rivalry for high perches. Along the front 
 put the nests. A is a hinged board that may 
 be lifted to gather the eggs. B is the alleyway 
 through which the hens pass to their nests. 
 
 The house may be built 12' x 20' for 100 hens. 
 Put in a cement floor. 
 
 HOUSE FOE 150 HENS. 
 
 The house shown in Fig. 196 for 150 hens may 
 be divided into five departments. A good width 
 is 15'. Make a scratching room where the exer- 
 cise will be had and the food given in deep, dry 
 litter 15' square. Next this is a roosting depart- 
 ment 5' x 15'. Then make another roosting-room 
 for the second pen, then another scratching room 
 and so on the length of the house, which in this 
 plan is 15' x 100'. Let the roof slope from front 
 to rear, the house 5' high at the rear and 8' in 
 front with glass at the scratching rooms to cover 
 at least a fourth of the space. Let- the sun in. 
 Have the glass in front of the scratching sheds 
 
118 
 
 FABM BUILDINGS. 
 
 100 PEET 
 
 --4 
 
 Scratching 
 room 
 
 Scratching 
 
 ROOM 
 
 Scratching 
 ROOM 
 
 Scratching 
 ROOM 
 
 Scratching 
 ROOM 
 
 FIG. 196— HOUSE ITOB 150 HENS. 
 
 so that the windows may open on hinges and the 
 fowls be restrained by wire. 
 
 Take the fonl air out by means of galvanized 
 iron pipes (with dampers) 6" in diameter run- 
 ning up through the roof and opening near the 
 ground to admit the colder and fouler air from 
 near the floer. Let the roosts be easily removable 
 and all on the same level. Turn the glass side 
 toward the sun. Make the house tight and warm 
 by double boarding and tarred paper. Put in a 
 cement floor. The partitions may be made of 
 wire. The doors should swing on double-acting 
 spring hinges so that one may go rapidly through 
 them in either direction. 
 
 POULTKY HOUSE FOR 250 HENS. 
 
 A roosting house to accommodate 250 hens at 
 night and with some 50 nests may be built 12' 
 wide and 40' long with six roosts through it, 
 
 FIG. 197— POULTRY HOUSE FOB 250 HENS (END ELEVATION). 
 
 which will give 240' of roosting space. (See 
 Pigs. 197, 198 and 199.) The roosts will be 
 
 PIG. 193— POULTRY HOU5E »ns 250 HBN3 (FRONT ELEVATION). 
 
 square 2" x 2" sticks, not fastened down, laid on 
 trestles 2' high. The whole thing is easily taken 
 out to be cleaned and disinfected. There ought 
 
 to be some galvanized pipe ventilators going out 
 through the roof, taking their air from near the 
 floor. Make the sides tight and warm with tarred 
 building paper. Turn the front to the south. 
 Make the back wall 5' high, the front wall 8' or 
 
 * 
 
 
 1 
 
 
 
 
 
 ^^^~ 
 
 
 
 
 
 KtH&MXy*i 
 
 
 
 
 
 
 
 
 
 
 i 
 
 
 
 
 
 l 
 
 
 
 250 HEHS PA, SS AQ f 4 WIDE 
 
 
 NEST BOXES 
 
 
 
 
 
 PIG. 199— POULTRY HOUSE FOR 250 HENS (GROUND PLAN). 
 
 9', use 16' rafters, provide a great deal of wire- 
 netting covered window in the front, which 
 should also have tight-closing wooden doors that 
 may be opened in mild or summer weather and 
 closed in cold weather. 
 
 A SIMPLE AND PEACTICAL HEN 
 HOUSE. 
 
 The poultry house shown in Fig. 200 has a 
 shed roof and faces the south. This house may 
 be 10' wide and as long as desired to accommo- 
 
 / 
 
 
 
 
 
 
 
 
 
 
 
 
 iin » 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 1 ^ 
 
 
 |IL 
 
 
 PIG. 200— SIMPLE AND PRACTICAL HEN HOUSE. 
 
 date the number of chickens kept. The scratch- 
 ing shed is in the center of the building and 
 communicates with each room by means of doors, 
 which may be locked at night, thus allowing the 
 chickens to be confined at night. 
 
 The roof projects over the south, east and west 
 sides 1' and is raised 5" higher than the -siding, 
 allowing free -ventilation. Two very large win- 
 dows admit light and warmth. Extending the 
 
POULTBY HOUSES. 
 
 119 
 
 entire length of each, room is a laying-box, 
 divided into compartments and covered with a 
 hinged lid, allowing the eggs to be gathered by 
 simply raising the lid and passing along on the 
 outside. Two rooms, built in this way, are much 
 better than one, because very often one class of 
 fowls should be separate from the rest. The floor 
 should be tight and be cleaned weekly. The 
 inner side of walls should be whitewashed fre- 
 quently, as the lime will cause vermin to seek 
 other quarters. 
 
 FARM POULTRY HOUSE. 
 
 This building (Fig. 201) will accommodate 
 from 50 to 75 fowls. Face it to the south to 
 
 «' 
 
 
 12' 
 
 li' 
 
 
 I2'x 16' 
 
 - SCRATCHING " 
 SHED 
 
 
 
 ROOSTS 
 
 8'XI2' 
 
 
 
 
 
 03 
 
 FIG. 201— FARM POULTRY HOUSE. 
 
 admit the sun ; make the sleeping quarters warm ; 
 provide an open wire-enclosed front for the 
 scratching shed when built in the Corn-belt or 
 further south ; make the floors of earth and keep 
 them well littered ; make the roosts moyable'and 
 not to touch the walls. Farm poultry should not 
 be confined except occasionally; the scratching 
 
 FIG. 301. 
 
120 
 
 FARM BUILDINGS. 
 
 shied affords opportunity for occasional confine- 
 ment. 
 
 CONVENIENT SMALL HEN HOUSE. 
 
 Fig. 202 represents the south side and west 
 end of a hen house 10' wide and 20' long, divided 
 into two rooms by a partition of wire netting. 
 This building serves two yards, as the middle 
 fence between the two yards joins up to the cen- 
 ter of the building at the front and back. 
 
 Fig. 203 represents the platform and perches 
 removed from the house to the outside, in order 
 to get a good view of it. It stands on the outside 
 in the same position as if in use on the inside. 
 
 Fig. 204 represents the perches as raised up 
 against the wall in cleaning, to a perpendicular 
 position. 
 
 Fig. 205 represents the percbes and platform 
 raised to a perpendicular position for the pur- 
 pose of cleaning out the trough. 
 
 MISCELLANEOUS. 
 
 SILOS. 
 
 LOCATION OF A SILO. 
 
 When possible the silo should be located in the 
 feeding barn, since it not only brings the cost of 
 building within the reach of every one who is 
 really in need of a silo, but greatly facilitates 
 the handling of the silage when feeding it out. 
 Depth in a silo is always preferable to breadth, 
 so that in the case of basement barns it is advis- 
 able to let the silo reach from the top of barn 
 posts to the ground floor of the basement; a door 
 or opening can then be made from the silo 
 directly into the basement where the silage is to 
 be fed. The next best location is adjoining the 
 feeding stable. In most dairy stables the cows 
 are stanchioned in two long rows facing each 
 other and whenever it is possible it should be 
 arranged so that the silo can be entered from the 
 end of this feeding alley. A wooden track can 
 be laid along the center of the feed-way and 
 into the silo, upon which a low-wheeled car can 
 be operated to distribute the feed. If the silo 
 building is located entirely separate it should be 
 planned to load the silage into a cart,, which can 
 be driven into the feeding barn, thus delivering 
 the silage with little labor directly to the stock. 
 The idea of convenience should not be lost sight 
 of, for by exercising a little thought and judg- 
 ment the labor. of waiting on the stock through 
 the long feeding season can be greatly reduced. 
 
 FILLING SILOS. 
 
 The cost of putting corn into the silo depends 
 largely on the advantage taken of all the little 
 devices that are calculated to lighten and reduce 
 the labor of harvesting and drawing to the silo. 
 By the use of the corn binder for cutting in the 
 
 field and conveniently equipped wagons for haul- 
 ing there will be no more hard work connected 
 with securing the fodder for filling the silo than 
 there would be in harvesting a clover or grass 
 crop. Many farms are supplied with low-wheeled 
 wagons or trucks. A very simple and practical 
 way of equiping the ordinary high- wheeled farm 
 wagon is shown in Fig. 206. This rack is made 
 of 2" x 8" plank, 16' long, one end of each being 
 placed on top of the forward bolster; the other 
 ends pass under the rear axle and are chained or 
 bolted up tight to it; these two pieces make the 
 foundation of the -rack. The wagon is coupled 
 out as far as these planks will allow. On top of 
 the plank are placed four cross-pieces, equally 
 distant from each other, as shown in the figure. 
 These cross-pieces are 2" x 4" and should be 
 about 7' long; upon these are laid inch boards 
 parallel with the wagon. The load is of course 
 placed wholly in front of the rear wheels, but the 
 rack is sufficiently large and low enough to enable 
 a man to put on a ton of green corn from the 
 ground without having to climb up on the load 
 or hand it to a second person to deposit. 
 
 While it is true that silage cut fine may pack 
 somewhat closer than that cut long, it is doubtful 
 whether there is any material gain in the opera- 
 
 FIG. 20e— RACK FOB DRAWING FODDER CORN. 
 
 tion; by cutting fine more of the inner parts of 
 the stalks are exposed to the air, and perhaps 
 more fermentation induced than with 'longer 
 cuts. There is nothing gained by cutting fodder 
 
MltiVELLANEO US. 
 
 121 
 
 fine instead of coarse, provided stock eats it 
 equally well in both cases; the gain in cutting, 
 which is often very great, comes mainly from 
 getting consumed that which would otherwise be 
 wasted. In the case of silage, there being no 
 necessity for cutting the fodder in order to have 
 it eaten, the length of the cut appears to turn 
 upon somewhat closer packing on the one side 
 and extra expense of fine cutting on the other. 
 With ample power and a modern feed-cutter a 
 silo can be filled in about half the time taken 
 by the old methods. 
 
 When corn has reached the proper stage of 
 maturity it is not necessary that it be wilted 
 before putting into the silo in order to make the 
 so-called sweet silage; only the immature fodder 
 needs wilting; such should be wilted from 
 twenty-four to forty-eight hours, if possible, 
 before cutting into the silo. Varieties that 
 mature, if left until the ears begin to glaze, can 
 be put into the silo immediately after being cut 
 with satisfactory results, provided there is no 
 outside moisture on the corn as it goes into the 
 silo; nor is it necessary to -suspend operations 
 every other day in order to let the silage in the 
 silo reach a certain temperature before filling 
 can be continued. If the corn is sufficiently 
 mature, and is put into the silo without rain or 
 dew, there need be no fears about the quality 
 of the silage, whether put in slowly or rapidly. 
 There is a limit to putting dry or excessively 
 wilted corn into the silo beyond which we dare 
 not go. When the corn has lost enough water 
 to cause the leaves to rustle and break in han- 
 dling it does not pack closely enough in the silo 
 to exclude the air, and on opening the pit it will 
 be found that the silage is fire-fanged and per- 
 meated all through with a white mould. There 
 is another reason why the corn should not be 
 allowed to become so dry even if there were no 
 trouble about its keeping in the silo: when dry 
 corn is put into the silo we have lost the succu- 
 lent quality of the silage that makes it especially 
 desirable. Having once commenced to fill the 
 silo the work can be crowded right along by 
 observing the conditions mentioned. In case of 
 an accident or break-down it will do no harm to 
 suspend work for a day or two, but if left longer 
 than this the silage to a depth of two or three 
 inches usually begins to mould. When filling is 
 completed a fobt and one-half of chaffed straw, 
 marsh hay or cornstalks will make a sufficient 
 covering. The use of weights is now obsolete. 
 The silo should be examined daily for a couple 
 of weeks and the covering pressed down until 
 the settling has ceased. 
 
 The question is often asked if one crop can be 
 placed on top of another in the silo, provided that 
 the first has only partially filled it. Most cer- 
 
 tainly; if one crop, as clover, for example, only 
 partly fills the silo, when the corn crop has 
 matured the covering of the clover can be 
 removed or left on, as desired, and the other 
 crop placed on top of it. By filling at different 
 times much more can be got into the silo than if 
 a single crop is placed therein by rapid filling. 
 Even with the slow filling silage settles consider- 
 ably after the silo is closed up; with very rapid 
 filling it may settle as much as two-fifths or even 
 one-half. Under any system it is well to allow 
 two or three days' settling at the last and filling 
 up again so as to get in all the feed possible. 
 
 CONSTRUCTION AND TYPE OF ILLINOIS 
 SILO. 
 
 The well-known Illinois dairyman, H. B. G-ur- 
 ler, thus describes several types of silos and their 
 construction : My first silo was built over twenty 
 years ago. It was rectangular in form, 20' deep 
 and sheeted inside the studding with a single 
 sheeting of first-class matched %" pine. A few 
 years later I built another silo with three com- 
 partments and double^sheeted the inside walls,, 
 using paper between the two courses of lumber. 
 In about seven years these double walls began 
 to show decay and at the end of ten years I was 
 compelled to tear them out and put round silos 
 in their place. A double wooden wall is the 
 last kind of a silo I would build if I were to 
 build another, as the moisture gets between the 
 two layers of wood and does not dry, causing 
 decay, and the walls are decayed beyond useful- 
 ness in a few years. If one will persist in using 
 wood let it be of but one thickness and of a 
 quality that will be sound and make as near an 
 air-tight wall as possible. 
 
 Five years ago I built my first round cemented 
 silos, building three that season. The following 
 year I built one 38' in diameter, which I con- 
 sider too large, as I am compelled to feed about 
 200 head of cattle when it is opened to keep 
 ahead of decay. If I am feeding less than that 
 number there is danger of the silage being 
 exposed so long that decay will begin and then 
 trouble begins, especially if it is being fed to 
 cows that are milking. Twenty feet in diameter 
 is a convenient size and I would not build with 
 my present knowledge any larger in diameter, 
 but build as deep as I could conveniently in our 
 prairie country. ( See Pig. 207. ) Three of mine 
 are 38' deep and three are 24' deep. I prefer the 
 deeper ones. With five years' experience I am 
 confident that the round cemented silo is the 
 most economical kind to build that I know any- 
 thing about. The cement preserves the silage 
 and also preserves the wood, as it prevents mois- 
 ture from reaching the wood from the silage. In 
 case the cement cracks (I have had very little 
 
122 
 
 FABM BUILDINGS. 
 
 E 
 
 FT 5T«Nir 
 
 si - 
 
 
 SI 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 II E 
 
 
 
 
 
 i 
 
 
 II 
 
 
 
 
 
 
 — 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 \ 'tiftim V/tOD. HO 
 
 
 mil. 
 
 i 
 
 
 
 
 
 
 
 
 
 
 OUjllJu. 
 - '±* u. rs S. 
 
 
 
 
 
 
 
 
 
 
 1 I'll 
 
 ! 
 
 
 
 
 • M.il 
 
 i 
 
 
 1 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 |. ..<•!,„, - - 
 
 
 
 
 i 
 
 
 111 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 t 
 
 
 
 ■ 
 
 ■1 ni 
 
 i 
 
 
 I 
 
 
 
 
 
 
 
 
 
 I'L.uU'l 
 
 WW 
 
 
 
 /a 
 
 5-» 
 
 ■2? 
 
 W 
 
 
 
 
 
 ([III < 1" 
 
 
 .III! 
 
 !i 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 I'MI ■' 
 
 .,!., 
 
 "1 
 
 
 III 
 
 
 
 
 
 
 
 M 
 
 
 
 
 
 
 
 
 
 
 
 1 
 
 I 
 
 
 
 
 
 
 .'!; <M 
 
 ill 
 
 1 1 
 
 '"'<• 4 
 
 ssbsf 
 
 ."> 
 
 ._..*. 
 
 ••Cl 
 
 "OF 
 
 C 3 
 
 l-D 
 
 LI 
 
 L^ 
 
 [.". D 
 
 c:j 
 
 l::"j 
 
 ELi EVADOM 
 
 
 Zif/Vllk. 
 
 isM.ijf'"' ^° r ^l 
 
 7"Hff BoflWS WRE TO BE /*MD£ A/W "frW T ff 
 
 I T/ve HOOPS **E MADS TWO THlGHtiB-ss & STUFF. 
 
 ' STUDS &ri»"ffT y JiOHb- AffD 8£ *" OM END rf r-0» 0T- EACH 67*H££) 
 I EACH ONe-V ; i*M(i^ 7"0 Tfi*>. AMD THC tt S TAJ?r A!-<orH£K-S GT. 
 
 Ct>»c.»mTE -Foi,nn»r/an _ 
 
 FIG. 207— CONSTRUCTION AND TYPE OT ILLINOIS SILO. 
 
 trouble in that way) go over it with a wash of 
 cement the same as a cistern is repaired when it 
 cracks. I find this to fill all cracks perfectly, so 
 that one would not know that there had ever been 
 cracks. A cemented silo cannot be built as 
 cheaply as a wood one if the first cost alone is 
 considered, but if the matter of durability is 
 
 taken into consideration I fully believe they are 
 the most economical to build. I believe my 
 cemented silos can be kept in perfect condition 
 for 50 years at the simple expense of once in 
 about three years giving them a coating of cement 
 wash. This we do as we fill them, applying as 
 high as we can reach from the ground and when 
 
MISCELLANEOUS. 
 
 123 
 
 we have them filled nearly to this point put the 
 wash on to another section and so on to the top. 
 
 The silo that I built in 1898 on which I put 
 no roof cost me 12^ cents per square foot of 
 surface wall. To illustrate : A silo 20' in diam- 
 eter is 63' in circumference and if 38' deep or 
 high it has 2,400 surface feet, which at 12 x /£ 
 cents per foot would cost $300, and it would hold 
 250 tons. Some would figure it to hold 300 tons. 
 This does not include the cost of a roof, which 
 after three years' experience I am confident is 
 more a matter of convenience than of necessity. 
 I do not believe it adds a dollar to the value of 
 the contents of the silo. I do know that the roof 
 is very much in the way when we reach the top 
 in 'filling, as a man six feet tall is constantly 
 bumping his head against the roof. 
 
 , My silos all have clay floors and the silage 
 keeps as well on clay as on cement. If you need 
 to keep the rats out cement the bottom. The 
 foundation may be of stone, brick or cement 
 (grout) to a proper distance above ground. I 
 used 2" x 4" studding, 12 in centers, but I am 
 certain that they might have been put 15 to 16 
 in centers just as well, as all the object of the 
 studding is to hold the lumber together, as there 
 no lateral pressure can reach the studding unless 
 the lumber sheeting is first pulled in two by the 
 pressure, and the pressure required to break this 
 circular sheeting is something surprising. The 
 inside sheeting was secured by taking 6" fencing 
 and having it resawed, making the material a 
 little less tiian J4" thick. On this were put laths 
 made from the same material, the laths being 
 made with beveled edges so that when nailed 
 onto the sheeting horizontally the same as the 
 sheeting is put on we have a dovetailed joint 
 between the laths to receive the cement, prevent- 
 ing its loosening until it is broken. The patent 
 grooved laths might be used, but they cannot be 
 sprung to a 20' circle. 
 
 The first three circular silos that I built were 
 put in a row and inclosed with a frame building 
 like a barn. This obviated the need of sheeting 
 outside the studding. Not being certain that I 
 had sufficient resistance to the lateral pressure 
 in the inside sheeting, laths and cement, I put 
 wooden hoops outside the studding, using the 
 same material that I did for the inside sheeting, 
 putting it on double and breaking joints. I 
 learned that I could secure more resistance for 
 the money in wood than I could in any form of 
 iron hoops and where protected from the weather 
 they were all right. For outside sheeting I used 
 in one case the same material that was used for 
 sheeting inside. This acts as weather-boarding 
 and also helps to resist the lateral pressure. For 
 the cement work use none but the best (I used 
 the Portland) and mixed it one part cement and 
 
 two parts clean sand. Be careful not to have any 
 clay or loam in it. 
 
 A SILO OF WOOD, CEMENT, PLASTER AND 
 SHINGLES. 
 
 According to Joseph E. Wing this is the cheap- 
 est and perhaps the most economical silo yet 
 devised. He thus explains the method of con- 
 struction : 
 
 Begin by digging a trench as narrow as you can 
 with your post hole diggers and 3' deep, widen- 
 ing it at the bottom. This trench will be cir- 
 cular, of the diameter you wish your silo, 12', 14'' 
 or 16'. I would not build wider than 16' with 
 this form of construction. Fill the trench with 
 good cement concrete, ramming it hard, and 
 extend it up above ground 2'. It should be made 
 8" thick above ground. To build this make a 
 form of thin boards bent in a circle like a cheese 
 box. Make the top of the concrete exactly level. 
 Procure common rough barn siding or fencing; 
 for a silo of small diameter 6" fencing will be 
 good j for a wide silo the stuff may be wider. 
 Make two hoops of boards %" x 6", 5" larger 
 than the inside circle .of the concrete foundation. 
 Treble the i£" boards, breaking joints. Lay 
 these hoops on the wall and take a piece of sid- 
 ing, set it up inside the circle and nail fast, see- 
 ing that it is vertical. Set up four of these 
 boards about the wall, then plumb them carefully 
 and brace them, raising up the other circle and 
 nail it at the top. If you wish to go higher let 
 the upper hoop extend above the top of the boards 
 .3". It will then serve to catch the lower ends 
 of the second set of boards. Now nail on all the 
 boards, siding as though siding a barn. Nail bar- 
 rel staves lightly at the middle to hold in place. 
 Leave an open strip 3' wide where the doors will 
 come. You now have a big barrel made of 1" 
 boards and nothing whatever yet to give strength 
 or tightness. 
 
 The bottom of the lower door should be 7' up 
 from the ground ; side up to that point. At the 
 side of the doors, on the inside, nail 2" x 6" 
 studding, flat-ways, directly to the boards to 
 strengthen them there and make a finish. Pro- 
 vide stuff y 2 " or %" thick 3" wide and begin to 
 put it on horizontally around the outside of silo, 
 spacing 3" apart. Nail it well and break joints. 
 On this shingle the wall. Let the stuff go across 
 the doors and be especially careful to select good 
 material there and to place it judiciously. Doors 
 need not be closer than 4' to each other. It is 
 easy to lift silage 2' and then to dig down 2' to 
 a lower door. It will add to strength to make 
 them 6' between. 
 
 If one length of the boards can not be obtained 
 set up another set on top of the first. It is just 
 as well to do this in any case. A silo should be 
 
124 
 
 FABM BUILDINGS. 
 
 at least 30' deep. You may use 16' stuff for 
 bottom set and 14' for the top. That with the wall 
 gives a 32' silo. Run a few strips of strap iron 
 up the siding to hold the two sections together 
 in a cyclone. When all is stripped with the 
 y 2 " x3" stuff you have a wall that can not be 
 rent asunder. The tensile strength of wood is 
 enormous. Cheap elm or green oak will bend 
 easily and make good material for this stripping. 
 
 Lath the inside with common plastering laths 
 but space them 1" apart. Nail a row of them 
 right around, then another row right on top of 
 the first, breaking joints and allowing the second 
 lath to project above the under one }4". thus giv- 
 ing a secure hold for the plaster. These plaster- 
 ing laths alone would hold the silo from spread- 
 ing. Plaster with best Portland cement into 
 which sufficient fibrous gypsum has been mixed 
 to make it adhesive. Now and then whitewash 
 it with pure cement after being used or coat it 
 with pitch to preserve it from the acid of the 
 silage in that when it settles will leave> the silo 
 ful of the silage will be good. Bevel the 2" x 6"s 
 that form the door jambs to receive the doors. 
 
 This silo has had tests in Michigan and else- 
 where and has enthusiastic adherents. It should 
 endure for many years and has the advantage 
 of the stave silo in that it will never blow down 
 nor collapse. In roofing it at the top bend around 
 and nail five thicknesses of the %" stuff to make 
 a plate. Get 2" x 12" plank long enough for 
 rafters and rip them diagonally from corner to 
 corner. This should be done in a mill, where it 
 is done very rapidly. Set them up with points, 
 together and toe-nail together, then shingle. This 
 makes a sightly conical roof. Make it steep ; it 
 looks better and enables you to blow a mound of 
 silage. Leave the earthen floor and every spoon- 
 nearly full. 
 
 THE WING CEMENT SILO. 
 
 This silo built by Joseph E. Wing has a wall 
 6" thick at the base thinning to 4" at top. It is 
 16' in diameter and 30' high. (See Fig. 208.) 
 
 Mr. Wing thus tells how it is built: We 
 bought a quantity of 2" x 7" hemlock staves to 
 form the inner core of the form. In erecting 
 this core we nail a %" strip 6" wide horizontally 
 about the staves on the inside as we set them up; 
 this keeps them in place, and is easily torn off 
 when taking down the wood. The staves we 
 beveled slightly as silo staves are beveled. I think 
 now that to have grooved them and put in the 
 grooves short metal tongues at three or four points 
 along. the length so that they would have been 
 unable to move against each other would have 
 been wise; they could have been set up more 
 rapidly. We set them up much as you would set 
 up any wooden silo, a 16' length first, using a 
 
 wooden hoop 2" x 6" built of i/ 2 " stufE as a form 
 to build against, this hoop being on the inside of 
 the silo. Each stave was spiked to this hoop; 
 when the lower section was finished the spikes 
 were withdrawn and the hoop raised up for the 
 second form. 
 
 The outer wall of the form was of Vfe" °& 
 stuff, 8" wide, the boards running about the silo 
 horizontally and held in place by 2" x 4" stud- 
 ding set about 2" apart. To hold these studding 
 at the right distance from the inner core they 
 were wired in three -places with No. 12 wire, 
 
 TIG. 208 — THE WING CEMENT SILO. 
 
 boring through the staves of the inner form for 
 this and passing the wires through these holes 
 and fastening by letting the loop pass about a big 
 nail. The wires we learned should be twisted to 
 get the slack all out of them. They pass through 
 the wall and are left in. 
 
 In beginning we dug a circular trench 2' deep, 
 widening it at the bottom to give a good bearing 
 and filling it first. The concrete was raised by 
 means of a pole derrick, which should be about 
 6' higher than the silo is designed. This derrick 
 is easily revolved and is guyed in four or six 
 directions with long and heavy guy wires. Scaf- 
 folding is carried up as you go. Concrete mortar 
 is lifted up by horse power, swung in place 
 rapidly and deposited in the forms with shovels. 
 After one knows how, silos may be very rapidly 
 built in this manner. Our men were all our 
 
MI8CELLANJH0 US. 
 
 125 
 
 regular farm laborers. We think this silo will 
 be a permanent thing. 
 
 The thinness of the walls forbids putting much 
 if any dependence in their strength to resist 
 bursting. The bursting pressure of silage at 30' 
 depth is 330 pounds per square foot, according 
 to King. If your silo is 16' in diameter it must 
 therefore have strength to resist 2,640 pounds 
 pressure for each foot in height. As you go up 
 the pressure decreases, of course. Concrete 
 should have a tensile strength of about 200 to 500 
 pounds per square inch. We imbed wires or rods 
 directly in the mortar to hold the strain. Iro. 
 hoops designed to hold wooden silos may be put 
 in. Wire is rather cheaper and more easily han- 
 dled. Get No. 00 wire. It is hard to handle, 
 so reel it out across the field and rig a lever of a 
 6" sapling about 20' long and put a team on it 
 across a stump and stretch it till it lies straight. 
 Then cut it into lengths long enough to reach 
 around the silo and 6' longer. At each board lay 
 in a wire or two before you put in cement, wrap 
 the ends about each other and turn them back; 
 the cement will not let them slip when it is hard. 
 These encircling wires should be in the middle 
 of the thickness of the wall, so insert upright 
 wires in the wall about 3' apart; they will also 
 prevent cracks and will hold the horizontal wires 
 in place. No. 00 wire has a tensile strength of 
 about 7,000 pounds. If the silo is to be 30' deep 
 begin by putting one at the ground level, then 
 up 8" put in another and at each 8" board. This 
 is a little stronger than is absolutely needed, but 
 I do like a thing to be safe and wire is not 
 very costly. It will not rust in the cement. At 
 the doors, which need not be closer to each other 
 than 6' and should not be nearer the ground 
 than 7', place upright rods 1" in diameter on 
 each side and loop the wires about them. Across 
 the bottom and top of the doors pass similar iron 
 5' long with ends turned up 2" and curving as 
 the curve of the wall. 
 
 We mixed our concrete .at a strength of one 
 barrel of cement to a yard of gravel. It seems 
 to be very hard. We washed the wall with a 
 brush with a wash of nearly pure cement, water 
 and a little sand. We put a roof on, as the silo 
 may hold silage until summer time some years 
 and roofs are not very costly. The floor is of 
 clay, which it seems is better than anything else. 
 It is not excavated at all. The pole may be sawed 
 in sections and thrown out of the window or left 
 in the silo until it is fed out and sawed off then. 
 
 If you are building of a different dimension 
 remember the rule for calculating the pressure 
 on your walls is to assume the normal pressure 
 at a depth of 30' to be 330 pounds per square 
 foot and to multiply this by one-half the diameter 
 of your silo wall. Be sure you put in enough and 
 
 put no dependence in the cement for resisting 
 bursting strain. The thin wall is very much 
 cheaper than the thick one and just as good, if 
 the steel is there. 
 
 The oak stuff that makes the outside of the 
 form warps and cannot readily be used again for 
 silo building, though it is useful in a hundred 
 other ways; the inner shell is practically unin- 
 jured by the use made of it. 
 
 All concrete work should be' moderately wet 
 down, never made sloppy, and rammed hard in 
 the mould until moisture rises on top. If it is 
 made very wet it is nearly ruined. It should not 
 be wet until just as it is ready to use. 
 
 I think a 4" wall is right and just as good as 
 one 18" thick, barring possible freezing. I insist 
 that abundant steel must be used and advise 
 coating the inside with hot pitch to make it acid 
 and air-proof. 
 
 It is not necessary to use a complete form for 
 the entire silo. We set up first a 16' length of 
 inner staves, afterward another 16' length on 
 these, thus needing as much timber for this inner 
 form as is needed to build a complete wooden silo. 
 We now think this a mistake. These staves can 
 as well be in 8' lengths and after two sets are 
 up the lower set is as well taken away and moved 
 up, next the second set moved up, thus proceed- 
 ing until the silo is tall enough. These staves 
 should be all accurately fitted together before 
 work is begun. There should be three dowels or 
 pins in each stave and holes exactly correspond- 
 ing on the other side. These dowels should be 
 made of Y^" steel. They should fit tightly on 
 the one side and the holes to engage them should 
 be large enough to allow them to enter and 
 remove easily. Thus equipped the staves are very 
 rapidly set up, as each one supports the one next 
 to it, and the dowels prevent them crowding in 
 when the concrete is tamped behind them. A 
 set of these staves will last for many years. The 
 first year's use of this silo disclosed less than 10 
 pounds of spoiled silage. 
 
 A SILO OF CONCRETE BLOCKS. 
 
 A silo built of concrete blocks has been 
 designed by Joseph E. Wing. He says the blocks 
 are easy to make and will lay without mortar 
 under them or at the ends and make an air-tight 
 and water-tight job. There will be no need for a 
 skilled mason in laying them. They are made 
 just right in length and curve to make the wall, 
 and where windows come they can be sawed in 
 two or shorter ones made to fit the openings. 
 Joints are broken just as in any stone work and 
 the effect is pleasing. 
 
 The block is made in a wooden mould and after 
 being set the mould is taken off and the block 
 hardened before being used, as any artificial stone 
 
126 
 
 FABM BUILDINGS. 
 
 blocks are made. It consists of two pieces, each 
 2" thick, 8" high and of convenient length, say 
 3'. These pieces are curved to fit the desired 
 diameter of the silo and are spaced 2" from each 
 other. They are held together by square loops 
 of steel wire, large size, such as No. 4. This wire 
 is bent in a form into the desired shape and two 
 pieces are put in each block. Being very large 
 stiff wire the blocks keep their position exactly 
 when made even, though they do not at any part 
 touch each other. This forms a stone block 6" 
 wide (it may be made 8" if desired) and with a 
 hollow clear through its length of 2". These 
 blocks may also be easily made in two parts; in 
 one part is moulded two bolts 6" from each end; 
 they are bolts y^" x 7". In the inner block, the 
 mate, two holes corresponding with these bolts 
 would be moulded with a %" depression in the 
 inner surface of the block. After they were hard 
 the two parts would be fitted together, nuts put 
 
 FIG. 209— A SILO OF CONCRETE BLOCKS (CROSS SECTION). 
 
 on, the depression making the nut flush with the 
 inside of the wall, then the double block laid in 
 the wall and the channel filled as described. 
 Afterward the projecting bolt ends would be 
 smoothly clipped off. The bolts would not show 
 on the outside at all. This block would present 
 no difficulties in manufacture whatever and when 
 once completed the two original blocks and 
 the core would be inseparably united. The foun- 
 dation is made below ground in a narrow trench 
 in which ordinary concrete is rammed. Level it 
 and lay the first course of hollow blocks. Fill 
 the channel with rather thin concrete, lay in a 
 No. 4 wire to hold the wall from spreading and 
 lay the next course, breaking the joints carefully. 
 Again fill the channel with cement, lay down 
 
 another wire and another layer of blocks and so 
 on up to the windows. At the windows (and the 
 lower one should be up T and the next one up 
 6' higher) one can fit in a good wooden frame 
 against which to build and there should be iron 
 rods run up vertically through the channel to 
 make it extra solid there, while the wires will 
 loop about these rods and their tops and bottoms 
 be fastened together, so that there will be no 
 danger of the silo bursting at this point. There 
 should be abundant steel put into this wall, so 
 that all bursting strains would be resisted by the 
 concrete. Eeference to the diagram (Pig. 209) 
 will make plain the idea. The section of silo 
 shows a course of blocks laid with the continu- 
 ous channel open and ready to be filled with 
 cement. It is actually a form of concrete and is 
 left there when filled instead of being taken away 
 as a wooden form would be. The block construc- 
 tion is clearly shown and the bit of heavy wire 
 bent into shape to be inserted in the form and 
 built into the block to hold the parallel sides in 
 place. This idea, by the way, is applicable to 
 straight walls for houses or any kind of build- 
 ings. 
 
 The wood mould is made with a curve to fit the 
 silo and of any convenient length, as 3', and as 
 wide as the wall is thick, say 6". A depth of 8" 
 will lay very well. Clamps hold the bottom of 
 the mould to the ends and sides. A curved 
 wooden block 2" thick fills the central portion of 
 the mould to make the hollow in the stone and 
 this block must be made a trifle tapering to be 
 readily taken out and in three parts divided ver- 
 tically, so that the cross wires will not hold it. 
 These cross wires are held in place by the central 
 block and cement, poured in and gently rammed 
 about them. 
 
 In making these cement stones gravel is not 
 used but coarse sand instead. In erecting a silo 
 after this manner only scaffolding timber would 
 be needed and the scaffold would be inside the 
 silo, though hoisting ^would be by pole and der- 
 rick, as in any silo, the arm simply swinging 
 material over the wall to the scaffold. 
 
 Silage has a bursting-pressure at a depth of 
 30' of 330 pounds per square foot. At 20' depth 
 the pressure is 220 pounds. To calculate the 
 bursting-pressure per vertical foot in a round silo 
 multiply the pressure per square foot by half the 
 diameter of the silo. Thus in a 16' silo 30' deep 
 the bursting-stress at the bottom is 8x330 
 =2,640 pounds for the vertical foot, decreasing 
 as you get higher. 
 
 A STONE SILO. 
 The silo shown in Pig. 210 has a capacity of 
 about 650 tons. Its walls are 2' thick and are 
 lined with cement. It is of a somewhat different 
 
MliSCELLA NEO VS. 
 
 127 
 
 type from most silos, being wider and not so high. 
 This silo is built cylmdrically and largely of 
 stone. Where they are lined with cement one 
 
 -STONE SILO. 
 
 seldom if ever has moldy silage around the edges. 
 Silos built like this one are expensive of course 
 to build, but are economical in the long run. 
 
 CRIBS, GRANARIES AND WORK SHOPS. 
 
 Perhaps the cheapest building for a crib or 
 granary is square, of capacity enough for the 
 grain produce on the farm. But as corn is 
 stored when not entirely dry it can be cured bet- 
 ter in narrow cribs. On this theory are designed 
 two cribs set parallel under one roof and 12' 
 apart. (Pig. 212.) This gives a driveway of 
 sufficient size to store reaper, mower and all 
 implements of the farm if necessary to store them 
 here. If this driveway should be used for imple- 
 ment room care should be taken not to let any 
 of the tools or implements come near enough to 
 the sides of the crib to give rats a chance to gnaw 
 their way in. 
 
 The cribs are each 6' x 36' at the bottom and 
 8' x 36' at the top. The object of this is to give 
 the sides of the cribs an outward slope, which 
 senses two or three valuable purposes. First, it 
 prevents rats climbing up the sides; second, it 
 prevents rain driving into corn and third, makes 
 it easier scooping corn from wagon. Rats will 
 climb up the perpendicular sides of a crib to an 
 open window or even to the top of the crib. To 
 prevent their going over top of crib place a board 
 extending 6" over the edge of the ties and plate 
 to which the slats are nailed. The windows must 
 not be left open after the corn is put in. 
 
 The bottom of each crib is 6" x 36' and rests 
 on stone foundation 3' in ground. (Pig. 211.) 
 The sills are 8' x 10" by 36', and the joists are 
 
 PIG. 211— CORN CRIB (FOUNDATION P.LAN). 
 
 2" x 10" by 6'. The sills rest on the stone piers 
 18" thick iy 2 ' above ground. This gives thor- 
 ough ventilation. 
 
 There are three windows on each side of drive- 
 way for receiving corn when the cribs are filled. 
 These windows are 4' x 4' and are fastened by a 
 strong wooden button. After the crib is filled 
 to middle of these windows the corn is thrown 
 ovei the top. With top of crib 8' x 36' there can 
 be stored after the crib proper is full to the 
 square one-third more corn. 
 
 The framework consists of three bents 12' each. 
 The space over the driveway out 12' at each end 
 is floored over and gives room for several hun- 
 dred bushels of corn or 1,000 bushels of wheat. 
 This crib and granary are absolutely rat-proof if 
 the doors and windows are not left open longer 
 than when used to put in or take out corn, and 
 if one is careful not to set boards or tools against 
 the cribs for resting places for rats to gnaw their 
 way in. 
 
 The slats on the outside and inside of the cribs 
 are oak, 3" x l 1 ^" and y 2 " apart. Care should 
 be taken not to use any slats with sappy or wavy 
 edges. 
 
 It will be noticed that the size of the ties may 
 seem heavy, but the fact is they are not too heavy, 
 
 ^= 
 
 s^ 
 
 
 
 
 
 
 
 
 ITO. 212— CORN CRIB (END VIEW). 
 
 nor are the posts too heavy to prevent springing 
 when the crib is loaded. The rafters are pine 
 2" x 6" and the sheathing is fencing 1" x 6" ; the 
 gables are weatherboarded with poplar. The 
 
128 
 
 FABM BUILDINGS. 
 
 posts are 12' long, 6" x 8". Ties are 12' long, 
 4" x 8", three to a post. There are four ties 
 G" x 6" 26' long which are tenoned into the out- 
 side posts and receive in a mortise the inside 
 posts. This makes the inside of each crib one 
 foot lower than the plate on which the rafters rest 
 and makes it easier to fill the crib. If the crop is 
 heavy set a board on edge, making the inside of 
 crib as high as the outside. The driveway is 
 closed by sliding doors, which locked makes a 
 safe store for the corn crop. The narrow slatted 
 cribs have also perpendicular ventilators placed 
 in front of each receiving window where corn 
 is likely to pack and mold if at any place in the 
 crib. These ventilators extend from floor to roof. 
 While the narrow crib is needed in moist East- 
 ern climates farther West this crib may very well 
 be widened to 8' or even 10' at the bottom. It 
 is worthy of note that when pine lumber must 
 be used and rat-proofing 'is desired it may be 
 secured by lining the inside of the crib with 
 wire netting of about i/ 2 " mesh. This is not 
 expensive. 
 
 TOOL HOUSE AND WORK SHOP. 
 
 A model tool house should be of generous size, 
 so that machines may be put away without much 
 labor; it ought to be as easy to unhitch in the 
 
 Ktihint 5w- Cft a > Sj^niflR. 
 
 c? 
 
 FIG. 213— TOOL HOUSE AND WOBKSHOP (CONSTRUCTION). 
 
 w 
 
 ELEVATION 'TOOL SHED 30'QO ft. 
 
 mux not cum smh. 
 
 WUTI LUNBCRMOH » WW BOM UM 
 
 w 
 
 WO. 214— TOOL HOUSE AND WORKSHOP. 
 
 shed as out of doors, else men will be apt to leave 
 machines out. The shed illustrated in Pigs. 213 
 and 214 is merely a great umbrella with posts 
 
 one wav 30' apart, the other way- 12' or 16', no 
 side to "it at all, so that there is nothing in the 
 way of driving into it at any point. Putting the 
 main machinery in the inner parts leaves the 
 over-hanging roof 10' wide for wagons and as it 
 is 10' high there is no difficulty in driving under 
 to unhitch. Buggies may be sheltered on the 
 shady side and if it is feared that snow would 
 drift into them one or two sides may be boarded 
 up. This is not designed for a house for fine 
 carriages, which should of course have a tight 
 dust-proof building. 
 
 The work-room above will hold a lot of smaller 
 tools, be a good place in which to mend harness, 
 make gates,' repair machinery or store seed grain. 
 By putting the truss above it with an inch truss- 
 rod coming down to the cross-beam there is given 
 a clear span of 30' in the shed below. The whole 
 thing is built in joint construction, posts 2" x 8", 
 in two pieces, built up solid below the cross-beam, 
 this made of three pieces of 2" x 12", spaced 2" 
 apart, box plates of 2" x 10", bridge truss of 
 6" x 6", rafters of 2" x 4" or 2" x 6", according 
 to whether they are ever to hold much weight. 
 
 The work-room should have a bridge stairway 
 wide enough and sloping enough to take up a 
 vehicle if necessary for repairs or painting. This 
 may be in any bent that is most convenient. The 
 floor may be of hard earth or cement; the posts 
 rest on stone pillars. Put on a shingle roof* that 
 will not be too hot in summer. If there is too 
 much room in this upper story finish off a room 
 for an extra hand to use now and then. 
 
 A CONVENIENT TOOL SHED. 
 
 It is difficult to, keep things in their places 
 unless one has provided places for them. On any 
 ordinary farm there is a great collection of 
 
 TOOL SHCDMXAI 
 
 FIG. 215— A CONVENIENT TOOL SHED. 
 
 machinery, wagons, plows, harrows, drills, rakes, 
 mowers, binders and what not which are gener- 
 ally supposed to be stored on the barn floor or in 
 odd corners of other buildings. Too often they 
 are left out under the sky. Yet it is not difficult 
 to keep them sheltered and in a place where they 
 will be convenient of access, not in the way and 
 easily put in their places. Pig. 215 shows such 
 
MISCELLANEOUS. 
 
 129 
 
 a building. It has no sides but is simply a roof 
 of pyramid shape, projecting on each side 10' 
 beyond the posts, being 56' square over all. 
 Under these projecting eaves the farm wagons 
 may stand and in the middle spaces the 
 machinery may be stored. Any machine may be 
 driven to any part, as there is nothing to inter- 
 fere with driving through in any direction. 
 There is much satisfaction in storing machines 
 in a building by themselves ; they are not in the 
 way, nor are they in danger of injury from con- 
 tact of animals ot wagons. There is no danger 
 of fire in such a building as this. Protection 
 from sun and rain alone is needed. The posts 
 are 6" x 6", set on stone; the roof is of shingles. 
 
 A TWO-STOKT nOTJBLE COBN-CKIB. 
 
 The double crib with two stories and two drive- 
 ways shown in Fig. 216 is about 30' wide, each 
 crib being about 10' wide and 20' deep and 60' 
 long. Built of these dimensions it will hold 
 
 PIG. 216— A TW 0-STORY DOUBLE CORN CRIB. 
 
 about 7,000 bushels of corn on each side of the 
 driveway, but on most Western farms it will be 
 built 12' wide rather than 10', which will con- 
 siderably increase the capacity, without adding 
 materially to the expense. 
 
 JOIST FRAME HAY BARRACKS. 
 
 Where hay is to be stored under roof and no 
 stock to be provided for this simple frame (Fig. 
 217), which is easily made all of 2" stuff or of 
 part round poles if desired, commends itself as 
 being simple, strong and cheap. There should be 
 braces running the long way of the building at 
 the same angle shown in the eut to protect 
 against winds. The artist fails to show all the 
 details of the curb roof, which must be tied 
 together by collar-beams at the peak and effect- 
 ually tied at the angles of the rafters. Reference 
 to roofs of barns shown in more detail will 
 explain the roof and how the plates are put on. 
 
 CEMENT AND CONCRETE, WORK. 
 
 There is no material for floors in stables, cel- 
 lars and out-houses comparable- with cement. It 
 is cheaper and cleaner than wood and properly 
 
 made will last forever. Failures in the use of 
 cement have come from the employment of 
 inferior materials or from ignorance of the 
 process of making it. To make a cement floor in 
 the stable remove enough top soil to get down to 
 where it is firm. A layer of coarse gravel or 
 broken stone should be applied and rammed 
 down. This serves for drainage and keeps frost 
 from affecting the cement. The concrete may 
 now be prepared. Concrete is made of finely- 
 broken stone, sand, gravel and cement. If you 
 do not have the broken stone, gravel will answer. 
 Take five bucketfuls of gravel and one bucketful 
 of cement and build up the contents in a conical 
 pile on the floor. Shovel it over carefully three 
 or four times to mix it thoroughly • while dry. 
 Continue mixing it in this way and sprinkle it 
 slowly with water. Mix it until it is moist but 
 not sloppy. It is now ready to use. Spread it 
 down and with a heavy rammer pack it thoif- 
 oughly. The better it is packed the better the 
 floor will be. 
 
 The thickness of the concrete will depend on 
 the use to which the floor is to be put. From 
 three to six inches will usually be satisfactory. 
 Where the floor comes against the side of the 
 trench or manure ditch there should be a plank 
 placed at the side and braced solidly to hold the 
 material in place. A loose two-inch plank may 
 
 TIG. 217— JOIST FRAME HAT BARRACKS. 
 
 be used between the restraining plank and the 
 concrete, which, after ramming the latter, may 
 be taken out, leaving the surface finish to form 
 the face of the offset. The material used in 
 making this surface finish consists of two parts 
 of clean sharp sand and one part of cement mixed' 
 thoroughly while dry and then wet carefully, 
 
130 
 
 FABM BV1LDTNGS. 
 
 rammed again until it is solid and then smoothed 
 with the trowel. If of the proper consistency it 
 will appear rather dry when laid down but will 
 be moist after it is rammed and troweled down 
 smoothly. After it has been troweled it may 
 be sprinkled with coarse sand to make the sur- 
 face rough. If it is desired to make it rougher 
 shallow grooves may be made by pressing down 
 with a short piece of fork or hoe handle. The 
 thickness of the finishing layer should be from 
 one to two inches. 
 
 Foundations and pillars for buildings may be 
 made of cement; walls for sheltering barnyards, 
 floors of porches, walks and even entire barn- 
 yards are somtimes covered with it in order to 
 avoid the mud that frequently is found in such 
 places. Cement should be used quickly after it 
 
 had with coarser mesh. This woven wire comes 
 in rolls. It is put over the wall of the building, 
 spaced y 2 " away, or if a very warm wall is 
 desired, %", and stretched tight. The best way 
 to put it on is to unroll and hang it as wall paper 
 is hung, fastening the top first, then one edge, 
 then by using 6 or 8-penny nails, starting them 
 slanting in the edge of the netting, it may be 
 stretched sideways. This stuff can not be 
 stretched lengthways but may easily be stretched 
 taut sideways. It. is kept away from the wall by 
 the use of laths running vertically, 2' apart. light 
 staples 1" long hold it in place and if it should 
 pucker anywhere it is held down by a staple. 
 Screws 1" long are used to hold it away from 
 the building; the mesh-wires are placed in the 
 slot of the screws ; the staple holds- them there 
 
 FIG. 218— A PLASTERED HOUSE. 
 
 is wet and not be disturbed while drying. It 
 should always be of best quality. To prevent it 
 from becoming too dry while "setting," especially 
 if exposed to sun, sprinkle it several tianes. 
 
 THE USE OF OUTSIDE PLASTERING. 
 
 To put plaster on outside walls with common 
 laths one must have first a solid backing of some 
 rough lumber; any dry stuff will serve but pine 
 is to be preferred, as it is not apt to warp. Space 
 the laths out from the side of the building about 
 %". Nail them on iy 2 " apart. 
 
 The best way to plaster the outside of build- 
 ings is to use common poultry netting, that of an 
 inch mesh being best, although good results are 
 
 and a tap of the hammer drives it down right. 
 The netting is put on rapidly and is cheap. Being 
 galvanized it is very durable, especially when 
 incased in plaster. 
 
 The plaster should be made of good fresh lime 
 and sharp sand. It should be made up in large 
 amount before the plastering is begun so that all 
 colors will be alike. It should not be rich in 
 lime but should be made as though for mason's 
 mortar. It is put on as over laths. It is best 
 to apply two coats, the first barely hiding the 
 wire and a thin coat over that before it is thor- 
 oughly dry. This will fill and hide all small 
 cracks. When it is completed the wire is 
 imbedded in the middle of the thickness of the 
 
M1SGELLANE0 US. 
 
 131 
 
 plaster. It can not crack ; it can not peel off, for 
 the wire being firmly stapled to the wall holds it 
 solidly in place. As time goes on and the wall 
 gets wet and dry again the mortar becomes harder 
 and harder until it is like stone. It is warm in 
 winter and cool in summer. 
 
 There is yet another use for outside plaster. 
 That is for covering out-buildings; poultry 
 houses plastered outside and in are warm, sightly, 
 easily kept free from vermin and cheap. There 
 need be but one thickness of boards and the wire 
 stretched over it on each side or common laths 
 may be used for the inside. The cost of this sort 
 of plastering is about double the cost of painting 
 once. A better plaster is made of Portland 
 cement ,one 'part, clean sand two parts. This 
 hardens into a cement impervious to moisture. 
 Fig. 218 shows a farm cottage plastered accord- 
 ing to the foregoing directions. 
 
 CEMENT FLOOH IN HOG HOUSE. 
 
 Fig. 219 shows the cross section of a hog house 
 24' x 60' with a cement floor. The floor is made 
 in two levels, 1' lower in the middle than at the 
 sides. By tbis means a dry clean feeding floor 
 in front and a dry clean sleeping floor back are 
 insured with a space in the middle to collect all 
 droppings and moisture. Bedding should be used 
 and absorbents. The trough should extend along 
 the front and be of cement 10" deep and the front 
 
 CROSS SECTION HOG HOUSE 
 
 24' WIDE 
 CEMENT FLOOR AND TROUGH 
 
 FIG. 219— CEMENT FLOOR AND HOG HOUSE. 
 
 by the trough should be hinged so as to open in- 
 wardly enough to lock at the front side of the 
 trough, thus shutting the swine away from the 
 trough while it is being cleaned and food put in. 
 The trough should be divided at intervals of about 
 16' so that liquid feed cannot run away. The 
 cement should extend upward 1' to form the 
 foundation wall and the superstructure of wood 
 anchored to it by %" bolts imbedded in the 
 cement. 
 
 CONCRETE FLOOR FOR HOG HOUSE. 
 
 The bottom to receive concrete should be solid, 
 so that it will not settle in holes nor out of the 
 original level. It must be so that no water can 
 stand under it, as it will freeze in winter and 
 
 heave up the floor, of course cracking the concrete. 
 It is best to remove a few inches of top soil and 
 tamp well the surface that is to receive the ce- 
 ment. The general way is to excavate eight to 
 twelve inches and fill with gravel. But if the 
 floor is protected from water getting under it the 
 gravel is not necessary. 
 
 The best concrete is made from broken stone, 
 gravel and coarse sand. Mix dry 13 parts gravel, 
 6 parts sand, 6 parts Portland cement, then when 
 thoroughly mixed, add water to make a stiff 
 paste. Then take 27 parts broken stone, thor- 
 oughly drenched with water, so that all fine dust 
 may be washed out and mix the crushed stone 
 with the other until all is incorporated with the 
 cement. 
 
 In laying cement it is best to divide the floor 
 into squares of 4' or 5' with 2" x 4" pieces firmly 
 staked down. Fill every alternate square with 
 the mortar well tamped down until the fine ce- 
 ment begins to come to the top. After it has 
 stood a short time but before it is dry apply a 
 finishing coat of half or three-quarters of an inch 
 made of two parts sifted sand to one part of ce- 
 ment, smoothing down with a trowel. After set- 
 ting it so as to be fairly firm remove the 2" x 4"s 
 and fill the other squares in the same way. If 
 made in too large squares shrinkage cracks will 
 occur. 
 
 To make concrete without the broken stone 
 coarse gravel may be used but it will need more 
 cement, say six or seven parts of sand and gravel 
 to one of cement. There seems to be no hard and 
 fast rule as to this. Only as much should be 
 mixed at one time as can be immediately used. 
 
 After completion the floor should be sprinkled 
 daily with water, which is necessary to complete 
 hardening of the concrete. It is best to leave 
 the studding around the outside for a long while. 
 As to the comparative cost of wood and concrete 
 much depends on the cost of the materials. In 
 most places the concrete will cost from a quarter 
 to a half more than wood but the concrete is for 
 all time and is certainly more sanitary and easier 
 to clean and keep clean. 
 
 CEMENT FEEDING FLOOR FOR HOGS. 
 
 A cement feeding floor for hogs may be built 
 12' wide, as long as desired, with a slope of 1" 
 
 FIG. 820— CEMENT FEEDING FLOOR FOR HOGS. 
 
 in 12" and preferably with a drop at the lower 
 side and a cement trough at the upper side. A 
 
132 
 
 FABM BUILDINGS. 
 
 cross-section of the ideal feeding floor is shown in 
 Pig. 220. Let the floor be in plain uninterrupted 
 sunlight, as sun is a sure destroyer of disease 
 germs. 
 
 In the cut T is the trough and over it is a 
 section of swinging fence that will close it from 
 the hogs while the slop or feed is put in; L is line 
 of level ; F fence of woven wire to prevent hogs 
 from crowding each other over the bank ; S slope 
 over which cobs and manure descend. 
 
 CEMENT EOOES. 
 
 Joseph E. Wing, who has used cement roofs for 
 several years with success, says of their construc- 
 tion: 
 
 First the roof needs to be strong and the roof 
 boards should be well nailed down. The weight 
 is a little more than that of slate, as the cement 
 is put on about %" thick. It must be put on a 
 month before freezing weather. The manner of 
 doing it is first to spread down a thin layer of 
 cement mortar in a strip about 3" or 4" wide 
 up and down the roof. Before this strip is much 
 set unroll upon it a strip of galvanized woven 
 wire poultry fencing, l 1 /^" mesh, spread it out 
 and staple it down only as much as is needed to 
 make it lie flat. Now spread another layer of 
 cement over this, hiding the wire, and trowel it 
 down smooth. Continue until the roof is covered. 
 It should not be of steep pitch, though cement 
 may be applied over old shingles on ordinary 
 roofs. When it begins to dry sprinkle it fre- 
 quently. A layer of straw or chaff 2" thick will 
 serve to keep it moist and it is better if it dries 
 out very slowly; if sprinkled well every day for 
 a week all the better. After it is set there will 
 appear some small cracks; these may be filled 
 by sprinkling the surface with equal parts of 
 cement and fine sand, about %" thick all over, 
 brushing it with a broom to get it in the cracks, 
 then sprinkling with water and spreading with 
 a whitewash brush. Use the best Portland ce- 
 ment for this work — one part of cement and two 
 parts of very clean sand. It makes a cheap roof 
 for cattle sheds, poultry houses and the like and 
 is a cheap way of repairing old shingled roofs. 
 Should it crack a little the second year it may be 
 washed over with a trifle of pure cement which 
 will stop that. Further test is needed before it 
 is to be recommended for dwellings or main barn 
 roofs. 
 
 CEMENT WATERING TROUGH. 
 
 Cement or concrete watering troughs are fast 
 supplanting the fast- decaying and ever-ready- 
 to-leak troughs. Of the former two types are 
 shown in the accompanying illustrations. Fences, 
 walls, floors, troughs and well coverings all decay. 
 Therefore the coming of good cement at a low 
 price is doubly welcome to the farmer. It seems 
 
 now that he may do things so well that they 
 will stay done through several generations and at 
 slightly greater expense than the temporary 
 makeshifts to which he has been accustomed. 
 ■ Use the best cement. Cheap cements are not 
 worth the using. Get clean, sharp sand and 
 gravel. If there is earth or loam in it it will not 
 make good cement. Broken stone is excellent but 
 it needs a proportion of sharp sand or finely- 
 crushed stone to fill the interstices of the broken 
 stone. The stone and cement or gravel and ce- 
 ment must be mixed in right proportions. There 
 should be just ■ ©nought cemexit to fill all inter- 
 stices in the sand and gravel; a very little more 
 to allow for poor mixing is safe. The amount 
 needed may be ascertained by the water test. 
 Taking a measure of dry material, such as 
 
 
 
 
 
 
 
 
 
 HHp^WwB*?SP 
 
 ji 
 
 
 
 BBB%^*y f »jl 
 
 
 
 
 BBf" - im^wi^h 
 
 Mt^ 
 
 
 
 
 
 
 
 
 
 - 
 
 
 
 
 5^S5B 
 
 
 sl^^^S 
 
 ^^1 
 
 Sp.-WKIV * '"■ 
 
 
 
 
 B^** 
 
 ^^ ~* *- 
 
 
 ■ :i 
 
 
 
 
 
 
 JTIG. 821— CEMENT WATERING TROUGH. 
 
 crushed stone, sand or gravel and another mea- 
 sure of same size filled with water, pour the 
 water into the stone until it will absorb no more. 
 Note what proportion of the measure is emptied 
 of water. Use a little more cement than you have 
 water and the proportions will be proper. 
 
 For watering troughs use good clean gravel 
 with a natural sand admixture, one cubic yard 
 to one barrel of cement. For street work, curb- 
 stones and the like, % of a barrel of cement are 
 used to a yard of gravel. 
 
 Mix the materials thoroughly while dry. Have 
 a long mortar box. Shovel the mass of gravel 
 and cement into a pile, as narrow and high as it 
 will lie. Beginning to take it away from the 
 bottom, shovel it over again, taking each shovel- 
 ful from the floor and placing it carefully on the 
 very apex of the new pile. Thus it rolls down 
 evenly on each side and secures quite intimate 
 mixture. Shovel it back and forth three or four 
 times before adding any water. The better the 
 mixture the better the concrete will be. In wet- 
 ting it down use a large sprinkling can for adding 
 water and do not wet it enough to make it run; 
 stir as water is added and stop when it is wet 
 enough to be merely well moistened but not 
 sloppy. When it is hard-rammed in the mould 
 a little moisture should rise to the surface. The 
 
MISCELLANEOUS. 
 
 133 
 
 harder the ramming the better the work will be. 
 Use the material as soon as wet. If any stands 
 till it becomes somewhat set throw it away or 
 use it for some -unimportant job. Wetting again 
 will not restore the life of set cement. 
 
 To build a watering trough, remove the top 
 soil down to where it is firm, say 8". Build a 
 box the size of the outside of the trough, say 4' 
 x 13' and 3' high. Make it strong to resist pres- 
 sure when cement is rammed against it, setting 
 stakes at the sides and tieing across the top. 
 Put in the bottom a layer of concrete about 4" 
 thick and through it insert a drain pipe, and an 
 inlet pipe. Make the drain pipe lyi' with coup- 
 
 FIG. 283— CEMEHT WATERING TROUGH. 
 
 ling, coming just flush' with the floor of cement. 
 Into this coupling screw a short standpipe, so that 
 into this the overflow will discharge and when 
 it is unscrewed the whole tank will be emptied. 
 Make this short standpipe to screw in easily and 
 keep the threads greased. (See Figs. 221 and 
 222.) 
 
 Do not try to fill up the tank with concrete 
 high enough to allow stock to drink out all the 
 water. Water is the cheapest material with which 
 to fill the bottom of a trough. Make an inner 
 form with sloping sides so that the wall will be 
 6" thick at the top and 16" thick at the bottom; 
 put in place and fill with concrete and pound 
 it down as hard as possible. Do this before the 
 bottom has become thoroughly hard. When it 
 has set a day or two take off the wood carefully 
 and wash trough well with a mixture of equal 
 parts pure cement and pure sand, using a fairly 
 fine clean sand, or cement alone. Put it on with 
 a whitewash brush. Sprinkle the work twice a 
 day and when a little hard carefully fill it with 
 water. 
 
 FEED PACKS AND TROUGHS. 
 
 A PRACTICAL FEED RACK FOE SHEEP. 
 
 Cheapness, simplicity and effectiveness are the 
 three strong points of this rack. Fig. 223 shows 
 the construction. The end pieces are of 2" x 6" 
 
 pine, the bottom boards are of 1" x 12" and the 
 top boards are set at an angle and leave a wide 
 opening through which the hay descends and 
 plenty of room for the sheep to thrust their 
 heads in to eat. This form of rack gives the 
 animals easy access to every bit of the feed and 
 prevents any waste of consequence, for when 
 
 2X6" PLANK 
 
 2X6" PLANK 
 
 FIG. 883— A PRACTICAL FEED RACK FOR SHEEP. 
 
 sheep can thrust their heads in they let them 
 remain there and eat without drawing the hay 
 out and trampling it under foot. In general this 
 rack is built without a bottom, though if it is 
 desired to feed grain in it there may be provided 
 a tight bottom, putting it about midway of the 
 bottom board. It is better to provide separate 
 troughs for feeding grain. 
 
 GOOD IDEA IN FEED RACKS. 
 
 The cuts Figs. 224 and .225 are self-explana- 
 tory. By hitching a team on one end of this 
 unique rack it can be moved very easily. The 
 18' ark holds 1,000 pounds of hay or one ton of 
 sorghum. The frame-work is made mostly out 
 of 2" x 4" except the runners, which are 2" x 6". 
 The rack ib 18' long, as shown in Fig. 225. 
 
 A SELF-FEEDING MANGER AND STALL. 
 
 This stall-manger plan can be used in nearly any 
 form of building. The stalls being only 3' to 3' 
 
134 
 
 FARM BUILDINGS. 
 
 '-*-''"'■'■ "-^SiswalS" - **? 
 
 HO. 384— GOOD IDEA IN PEED RACK (CONSTRUCTION). 
 
 
 PIG. 325— GOOD IDEA IN PEED RACK. 
 
 4", as may be preferred, in width and coming 
 out 2' from the manger, the front edge of stall 
 being perpendicular as shown in Pig. 226, there 
 is no danger of animals getting hemmed in or 
 injured in any way. 
 
 On the outside of the building above the top of 
 the manger there is an opening in the siding for 
 feeding silage, ground grain, bran, cottonseed- 
 
 meal and the like. This is closed by a shutter 
 turning up or down as desired. The stalls should 
 be braced from near the end of the 2" x 4" sup- 
 port of manger to near the middle of manger 
 and closed between the brace and side of the stall 
 so that stock can not get their feet fastened. Fig. 
 226 is thus described : A, A, hay chute 2' wide, 
 continuous with building. B, outer door to feed 
 
MISCELLANEOUS. 
 
 135 
 
 silage or grain of any sort without disturbing be moved more easily. The troughs should be &' 
 cattle; track hung out from siding may carry wide and have a space of 1%" at the bottom of 
 
 feeder for the corn to run out into the tro-ughs. 
 
 H-hVl. Still FttA. AWgtr" 
 
 FIG. 326— A SELF-FEEDING MANGER AND STALL. 
 
 A SELF-FEEDER FOB CATTLE. 
 
 oar to distribute silage. C, wooden partition be- _, „,, ... . ,. ., . , , , „, , 
 
 tween stalls; partitions 36" to 42" between cen- The ,2 ' x 4' pieces on the side should be 8 apart 
 
 ten, 44" from hay chute to outside of partition; at tbe ^P and 4 at the bottom ' s0 the Sldes Wl11 
 
 r be slanting. 
 
 A GOOD SELF-FEEDER. 
 
 The self-feeder for cattle shown in Fig. 229 
 is for an open feed-lot or pasture. When cattle 
 are made to put their heads through spaces like 
 
 FEEDING TROUGH FOB CATTLE. 
 
 outer piece of partition should be 2" x 6" firmly 
 fastened to stub-post set in ground. D, two 
 boards 1" x 6" to brace the upper part of parti- 
 tions. 
 
 SELF-FEEDER FOE CATTLE. 
 
 Herewith is a diagram (Fig. 228) of a self- 
 feeder for cattle that can be built on posts or 
 built on runners of 4" x 8" pieces, so that it can 
 
 FIG. 329— A GOOD SELF-FEEDER. 
 
 this to eat their food much outside wastage is 
 saved. The dimensions of this feeder are about 
 right for cattle weighing, say, 1,000 pounds. In 
 making it use bolts freely. 
 
 A SHEEP BACK. 
 
 The sheep rack shown in Fig. 230 has been 
 used with satisfaction at the Iowa Experiment 
 Station. The rack is 8' long, 18" wide and 38" 
 
 A 
 
 i ii innnnnnnnnnt 
 
 / 
 
 / 
 / 
 1 
 
 1 
 
 1 
 
 1/^"- 
 
 \b 
 c 
 
 1 
 
 \ 
 
 \ 
 
 s 
 
 
 F 
 
 FIG. 830— SHEEP BACK. 
 
1^6 
 
 FABM BUILDINGS. 
 
 . high. This size is found convenient for small 
 \pens, but any size may be used to suit the require- 
 ments. Economy of time and material may be 
 :' gained by making the rack a little wider and 
 [ feeding from both sides. Fig. 230 on left gives ,i 
 'side view of the rack as used for feeding hay, on 
 
 A WISCONSIN HAY SELF-FEEDER FOR SHEEP. 
 
 right an end view, showing . operation of grain 
 trough and explaining method of construction. 
 
 The bottom of the rack (0) is 14" from the 
 ground floor. The front is boarded tight from A 
 to B, a distance of 14" and slopes inward, mak- 
 ing B 4" inside of the perpendicular line A, C. 
 A 3" strip extends across the front joining onto 
 the bottom to prevent the chaff and seeds from 
 being worked out. The space from C to B (8") 
 gives the sheep access to the hay, and is separated 
 into 3" spaces by narrow cleats, as shown on left. 
 The grain is fed in a trough consisting of 
 two boards joined together, as shown in end view. 
 
 one being 6" and the other 12" in width and both 
 of the same length as the rack. The trough is 
 attached by hinges to the front of the rack at a 
 point midway between A and C and can be low- 
 
 POBTABLE FEED BACK. 
 
 ered for grain-feeding and fastened up out of 
 the way when the grain is eaten, as shown in 
 Fig. 230. All lumber used should be planed on 
 one side at least and the grain trough should be 
 planed on both sides. The hay-rack of itself is 
 a good one and gives good satisfaction used alone. 
 The grain-feeding attachment is easily and 
 cheaply made, occupies no room when not in use 
 and makes the rack complete. 
 
 SHEEP-FEEDING RACK. 
 
 Into the rack shown in Fig. 231 hay falls to 
 the sheep as they eat it and they do not nose 
 
 SHED FOB HAT FEEDING. 
 
MISCELLANEOUS. 
 
 137 
 
 it all over, and lambs may run there without 
 being on top of the hay all the time. This rack 
 is to a certain extent a self-feeder, and though 
 it is not recommended to feed sheep in any other 
 way than what they will eat at one time it is 
 an advantage to have a little hay left for the 
 
 FLG. 231— SHEEP-FEEDING BACK. 
 
 weaker ones. They waste very little hay with 
 this rack and as it has no> bottom it can be raised 
 and then moved by one man. The frame is made 
 of 2" x 6"s edgewise; for the block at the bottom 
 saw 2" x 6"s diagonally; nail 12" hoard along the 
 
 SELF-FEEDER FOB SHELLED CORN, MIXED GRAINS OR 
 GROUND FEED. 
 
 bottom lengthwise, then take three 10" boards 
 and nail up the front; set the bottom 10" level 
 with the 12" or about 1" higher; make the 
 rack with a frame about every 4', omitting cross 
 piece except at the center, and this is not neces- 
 sary unless the rack is to be moved about. For 
 rack to feed only one side make 18" between 
 studs. The sides may be made separate and set 
 against light posts. Do not nail, but wire so 
 they can be raised. 
 
 A HAT SELF-FEEDEE. 
 
 This is a combined feeder and windbreak. The 
 hay ought in any event to be covered and a little 
 additional roof covers the cattle as well. A cross 
 section of the feeder is shown in Fig. 232. Corn 
 or bran or any ground feed may also be fed 
 in the bottom on the tight floor. The posts are 
 set in the ground. Galvanized steel corrugated 
 roofing is used. Such a feeder and windbreak 
 
 along the cold side of the yard would be useful 
 on many a farm to hold bright straw, shredded 
 fodder or hay. 
 
 CATTLE YABD AND SELF-FEEDER FOE HAT. 
 
 The feeding of cattle in open yards is com- 
 monly practiced, yet shelter pays well. Small 
 
 FIG 232— A HAT SELF-FEEDEH. 
 
 yards too are recommended and they may be 
 paved to advantage. (See Fig. 233.) 
 
 The hay feeder shown in Fig. 234 holds two 
 loads of hay which is all eaten without waste. 
 
 J 
 
 u a n 
 
 /tAYEEEDEff 6'VIM 
 
 1 c 
 1 C 
 
 c 
 
 OPE/tSMED ISXb" 
 
 c 
 
 OPCN SHCO 
 12X64 
 
 OPE/V YA/90 
 
 
 
 
 
 | VIATCff | 
 
 
 
 
 
 
 
 FIG. 233— CATTLE TARD AND SELF-FEEDER FOR HAT (PLAN). 
 
 Corn boxes are set under the roof, leaving room 
 to drive between them and the hay feeder. The 
 
138 
 
 FARM BUILDINGS. 
 
 yard need not be more than large enough to com- 
 plete the square, then all manure is saved and 
 less litter needed to keep it dry. 
 
 COMBINED HAT AND GRAIN BACK. 
 
 The cross section of this rack, shown in Fig. 
 235, explains its construction. It is a corn box, 
 
 times corralled in enclosures made of tenting. 
 Afterwards came the stone fence, the picket fence 
 and the zigzag rail fence that are now relics of 
 the past. 
 
 The three kinds of fences that are m general 
 use today are the board fence, the barbed-wire 
 ^fence and the woven wire fence. Barbed- wire 
 has been used quite extensively but it is no doubt 
 Hearing its end of service, since at the present 
 time the woven wire fence either alone or in 
 combination with the barbed-wire is coming more 
 
 CROSS SECT/ON 
 FEEDINQSHED 
 
 FIG. 834— CATTLE YARD AND SELF-FEEDER TOR HAT (SECTION) 
 
 very strongly made to resist the pushing of big 
 cattle, with added hay slats spaced 4" apart to 
 hold hay. What is pulled through mostly drops 
 
 and more into use. The woven wire is proving 
 to be a very substantial fence and one best suited 
 for ordinary farm fields. 
 
 FENCE POSTS. 
 
 Corresponding to the foundation of a building 
 are the posts which are necessary in the construc- 
 tion of all fences. The cost as compared with 
 the durability of the post is the thing to be con- 
 sidered when making the selection of posts. 
 / Of the wood posts red cedar gives the best 
 service. Good cedar posts cost from 15 to 20 
 .While oak posts are cheaper they 
 
 cents apiece 
 
 38. IN. 
 
 
 
 ifl\\ //pr 
 
 
 
 
 
 
 
 
 
 
 
 Ttjht 0otf*.> 
 
 
 °3 
 
 FIG. 235— COMBINED HAY AND GRAIN RACK. 
 
 in the boxes and is consumed or may be thrown 
 back into the rack. The tight bottom admits of 
 the feeding of any kiiid of grain. 
 
 FARM FENCES. 
 
 Fences have been used in one form or other 
 ever since men engaged in the pursuit of stock 
 raising. In ancient times the sheep were some- 
 
 no. 237. 
 
 are shorter lived than cedar and are disagreeable 
 to work with because they are so hard. In parts 
 of the country where stone can be quarried, 
 stone posts are often used. They cost from 25 
 to 50 cents and are very heavy to handle but 
 when once in the ground they are there to stay. 
 
 Wooden fence posts are becoming more and 
 more scarce as the timber of the country, is cut, 
 arid the price is constantly increasing. A sub- 
 stitute for wooden posts is now being introduced 
 in the form of cement posts. It is the same 
 material used in cement sidewalks. The claims 
 made for these posts are that they surpass in 
 smoothness of wear and freedom of cleavage 
 
MISCELLANEOUS. 
 
 139 
 
 by frost or breaking by blows, as in the ease of 
 building stones. The posts are also claimed to 
 be fire, rot, frost and rust-proof, much stronger 
 than wood and to improve instead of degenerate 
 with age. There are several different patterns of 
 these poets on the market. The weight of the 
 
 posts prohibits long shipments, but a farmer can 
 make his own posts with the least possible out- 
 lay. One or two moulds and a level piece of 
 ground covered with sand two or three inches 
 thick comprise the necessary machinery. 
 
 The moulds made of cypress will cost about 
 
 $3 each aud those made 'of pine will cost about 
 half as much. One style of these posts is 4%" 
 square at the ground line and tapers on three 
 sides to 3" square at the top and 3y 2 " square at 
 the bottom, and also makes a small truss of the 
 four wires which run lengthwise through the 
 post. The post can be made any length desired, 
 a 6' post weighing about 50 pounds when cured. 
 The approximate cost is about as follows: l^/fc 
 pounds No. 8 wire at $1.80 per cwt.,2.7 cents, 
 and 8 pounds cement at 60 cents per cwt., 4.8 
 cents, (gravel and labor not included in the cost) 
 would be per 6' post 7.5 cents. A 6J^' post at 
 this rate would cost 8.25 cents. 
 
 Small holes are moulded through the post par- 
 allel to the fence and in the direction which the 
 
 i ii i — i — i — i — * — i — i — t- 
 
 t i t * f 
 
 FIG. 840. 
 
 fence runs. Through these holes a short wire is 
 run and wrapped around the wire of the fence 
 at each side of the post ; in the same way boards - 
 can be attached. The posts are claimed to be 
 very strong. No. 8 wire is capable of holding a 
 weight of 1,800 pounds. With four of them 
 in the post it makes it almost indestructible. 
 Also the holes through the post are behind the 
 front wires so that should the cement be knocked 
 off in front the wire would still hold. 
 
 The posts are composed of three parts sand and 
 one part cement mixed thoroughly dry first and 
 then wet enough to pound into the mould with- 
 out becoming sloppy. Enough of the wet mixture 
 is placed in the mould to make about l 1 /^" in 
 
 26 IN. 
 
 FIG. 339. 
 
140 
 
 FAEM BUILDINGS. 
 
 depth. Then it is pounded down. Two of the 
 long wires with hooks on each end are placed in 
 lengthwise with the cross wires to make the 
 holes through which the tie wires pass. Next fill 
 the mould to within 1" of the top, place in two 
 more longitudinal wires and tamp. Pill up 
 the mould a little more than level and tamp 
 again; smooth off and turn the post out on the 
 wet sand floor to cure. They are moulded face 
 downward and a groove runs through the cen- 
 ter of the face in which can be placed a wire for 
 lightning arrester. Keep posts moist for four 
 days by sprinkling. 
 
 SETTING FENCE POSTS. 
 
 Next to the material is the manner of setting 
 the posts. In building a fence it must be remem- 
 bered that the end posts are the mainstay of the 
 whole fence. These should be about 3" greater 
 in diameter and about 2' longer than the inter- 
 mediate posts. The hole for the end posts should 
 be at least 4' deep, if 5' is to be above the ground, 
 
 will pull some of the staples. The wire should 
 always be fastened on the side of the posts 
 towards the field where the stock is kept. 
 
 Figs. 247 and 248 show the two very popular 
 methods of bracing end or corner posts. 
 
 Figs. 236, 237 and 238 show cuts of woven wire 
 fences constructed from galvanized wire. These 
 fences are very "serviceable and are sufficiently 
 strong, and woven in a manner as to enclose cat- 
 tle, horses, shegp or hogs. Some farmers prefer 
 a combination fence as shown in Figs. 239 and 
 241. This is a good kind of fence for a hog pas- 
 ture and will turn any kind of stock. In Fig. 239 
 is shown a combination woven and barbed-wire 
 fence. This makes a cheaper fence than an all 
 woven one of the same height, since the 26" 
 space covered by the three barbed-wires does not 
 cost as much as woven wire 26" high. Even 
 with an all ' woven wire fence it is often ad- 
 visable to have a barbed-wire on top, so horses 
 will not reach over and bend down the wire on 
 top of the woven wire. 
 
 i ^ 
 
 I 4 !■ 
 
 L 
 
 -t h- 
 
 I I 
 
 -* 1- 
 
 i i i i ii ' iii ii i — t i f — t t i — t — n 
 
 t— y- 
 
 m 
 
 i 
 
 I 
 
 wi — 
 
 FIG. 341. 
 
 Il»»"ll 
 
 7 
 
 and should be 3' square. In the side of the wood- 
 en post toward the end of the fence and about 7" 
 from the bottom end of the post a piece 2"x6" and 
 30" long should bef spiked and fastened into a 
 notch in the post cut for it. If for a corner an- 
 other piece should be fastened above it and at 
 right angles to the first. About 10' from the end 
 post in line with the fence another post about 
 the same size should be set at the same depth. 
 About a foot from the top of the end post and to 
 a few inches above the ground on the other should 
 be extended diagonally a wooden brace 4"x4", 
 being fitted into notches cut in the posts. 
 Another brace of twisted wire should extend from 
 near the top of the brace post to the bottom of 
 the end post. The intermediate posts should be 
 about 7' long and 4" to 6" in diameter and 
 should be placed 2y 2 ' or 3' in the ground and 
 about a rod apart. All posts must be in perfect 
 line from top to bottom, otherwise the tension 
 
 The old-fashioned board fence is rapidly going 
 out of use and is now only seen around yards 
 and short stretches near buildings where it is 
 often better than wire. One hundred rods of 
 the old board fence would cost $85 for the boards 
 alone. It takes twice as many posts and is much 
 more tedious to build, since the posts have to be 
 set in in such a manner as to let the boards 
 meet. This kind of fence completed would cost 
 about $1.20 per rod. This puts it out of compe- 
 tition with the woven wire fence, since the best 
 54" woven wire fence can be purchased for 65 
 cents or less per rod and is more sightly and ser- 
 viceable. 
 
 Figs. 243, 244 and 245 show a strong hurdle 
 fence composed entirely of ordinary fence boards. 
 The triangular frames which serve as posts are 
 each of two pieces of 1" boards crossed and 
 braced as shown in Fig. 244. The panels, Fig. 
 243, are 16' long, each composed of four boards; 
 
MISCELLANEOUS. 
 
 141 
 
 in setting up the fence each, triangular frame 
 supports the ends of the panels. The upper and. 
 lower boards of each panel interlock with the 
 
 nt 
 
 :fc 
 
 * 
 
 tt 
 
 no. 247. 
 
 frame, as shown in Pig. 245, making a very 
 strong fence. This is a very handy fence for 
 fencing temporary pastures and is often used 
 to divide a pasture from tilled land. 
 
 Fig. 249 is a windbreak and is used to enclose 
 the barnyard or feed-lot. The fence is generally 
 8' high but some prefer 6'. The boards should 
 be on the side next to the feed-lot so that the 
 stock by rubbing cannot knock the boards off. 
 Although primarily this fence is a windbreak it 
 is very valuable in that it hides the manure piles 
 and general disorder of the feed-lot. 
 
 Pig. 246 represents another style, a very neat 
 farm fence, rather preferable to the old straight 
 fence. It saves one board to each length and by 
 
 nailing on the two upper boards as shown in the 
 illustration great additional strength is given. 
 These boards not only act as braces but as ties 
 
 FIG. 249. 
 
 also, and a fence built on well-set posts and thor- 
 oughly nailed will never sag or get out of line 
 until the posts rot off. 
 
 STONE ANCHOR-WALLS FOR FENCE. 
 
 Mrs. Virginia C. Meredith of Indiana submits 
 the accompanying photographs that illustrate 
 stone-anchor walls used with wire fence. These 
 walls are built of boulders laid in cement; they 
 are 8' long, 2' wide, 4' 6" above ground, and 
 3' under ground. In building them it was the 
 intention to get something that would endure, 
 that would stand plumb and at the same time be 
 not unsightly. The expense is greater than that 
 of putting in the best red cedar posts and braces, 
 but on the other hand there is every reason to 
 think that these walls will not only stand plumb 
 but that they will last indefinitely. On a home 
 farm it is worth while to make permanent 
 improvements. To make the holes through which 
 the wires pass (see Pig. 251) the stonemason in 
 building laid gas pipe on a level at the required 
 distances apart and before the cement hardened 
 withdrew the pipe. 
 
 The fence shown in the pictures is of four 
 barbed-wires, the top one being 50" from the 
 ground, the bottom one 16" from the ground. 
 The fence is an outside one and' intended to 
 
142 
 
 FABM BUILDINGS. 
 
 FIG. 250— STONE ANCHOR-WALLS FOR FENCE. 
 
 enclose cattle and horses upon a permanent pas- 
 ture. To fence an entire farm for hogs seems a 
 needless expense. The wire is fastened only at 
 the two ends at the anchor-walls. It is fastened, 
 after passing through the holes, to a stretcher or 
 
 raehet by means of which it may be stretched as 
 tight as desired. Between the end stone anchor- 
 walls small red cedar posts are set 50' apart or 
 less, according to the surface of the ground. 
 Upon the cedar posts are iron insulators through 
 
 FIG. 251— STONE ANCHOR-WALLS FOR FENCE. 
 
MISCELLA NEOUS. 
 
 143 
 
 which, the wires pass but are not fastened. 
 Between the cedar posts the wires axe held in 
 place by steel stays at distances of about 10'. 
 In a short line of fence, 100 rods or less, the wire 
 is attached to the rachet or stretcher at one end 
 only while at the other end it is wrapped around 
 a vertical piece, of gas pipe, asi may be plainly 
 seen in the anchor-walls at the gateway (Fig. 
 250). 
 
 Three things are necessary to a good fence — 
 strength, elasticity and light weight. By using 
 barbed-wire one gets the very great advantage 
 of the cable in stretching as well as extra 
 strength, while by using but four wires one cer- 
 tainly secures a fence of light weight. The barb 
 itself on a tight wire is a harmless but effective 
 warning to cattle and horses to let the fence 
 alone. Barbed-wire, used after this plan of not 
 stapling it to the post, is elastic enough to with- 
 stand any ordinary shock, such as a falling tree, 
 because the force of the impact is distributed 
 along the entire line of fence between the end 
 anchor-walls. 
 
 A gate is always a source of weakness to a 
 fence and a cause of care to the farm owner. The 
 stone posts to which the gate is hung (Fig. 250) 
 are 2' 6" square. The hinges as well as the latch 
 piece were set in the cement as the posts were 
 being built. 
 
 Mrs. Meredith says : "We are greatly indebted 
 to the pure breeds for animals with little of the 
 scrub propensity for jumping fences, conse- 
 quently a fence 4' 2" high is ample safeguard 
 for the stock usually kept on a farm. I have 
 used a fence of the style here described for more 
 than twenty years and with entire satisfaction. 
 We seem not yet to have learned how to build 
 farm' fences. A ride through any section of the 
 country reveals a succession of poor fences con- 
 structed after the vagaries of each particular 
 owner. Hardly ever does one find a fence that 
 stands plumb. With plank fences the great 
 weight inevitably forces them to- lean; with 
 woven wire fences, in many cases, the wire used 
 is so light and so poorly galvanized that in a 
 short time it yields to the rubbing of stock and 
 shows holes or else is borne to the ground. The 
 usual barbed-wire fence seems to inspire in its 
 owner a disinclination to replace a staple or mend 
 a broken wire. The very best fence ever con- 
 structed was the - old time split rail Virginia 
 worm fence; it would stand plumb and would 
 turn hogs as well as horses, but it is a luxury of 
 the past, too expensive for modern farm econ- 
 omy." 
 
 A CONVENIENT POETABLE FENCE. 
 
 It is often desirable to have a fence that may 
 be quickly erected and as quickly removed. The 
 
 fence shown in Fig. 252 is very cheap, strong and 
 convenient. It is built of pine, 1" x 6" for the 
 bottom rail and 1" x 4" for the top rails. The 
 braces that hold it upright are of 2" x 4" and the 
 base or cross piece is 2" x 6". The base is notched 
 2" and the bottom boards notched as much, which 
 makes a secure lock. This fence is easily made 
 and is erected when needed as fast as the panels 
 and braces can be taken from the wagon. As 
 the base piece of the brace is apt to decay first 
 it might well be made of oak and if set on two 
 bricks or small fiat stones it would be less 
 affected by moisture of the soil. These panels 
 
 PIG. 252— A CONVENIENT PORTABLE PENCE. 
 
 must not be too long or they will warp out of 
 shape, 12' being long enough. Pine is better 
 than oak because of the warping tendency of hard 
 woods. 
 
 PORTABLE HOG AND SHEEP FENCING. 
 
 The cut (Fig. 253) shows a good type of a 
 portable hog and' sheep fence. It should be built 
 of good material that will not warp nor rot read- 
 ily. Put together with long wire nails, clinched, 
 painted or treated with a wood preservative it 
 will endure for years and form a ready means of 
 enclosing a patch of rape or clover pasture. 
 
 PORTABLE HOG AND SHEEP PENCE. 
 
 The panels in the portable hog fence shown 
 in Fig. 254 are made of 4" fencing, 14' long, with 
 6" spaces between the boards — thus making a 
 fence 3' high by allowing the cleats to project 2". 
 If the fence is to be used for pigs the lower space 
 
144 
 
 FABM BUILDINGS. 
 
 1 . 
 
 
 "J| 
 
 
 IS, 
 
 • 
 
 
 •1 r 
 
 
 li « w 
 
 <° - 
 
 1 . 
 
 
 • 1" 
 
 
 *. 
 
 1 
 
 1 . 
 
 43 
 
 '« 
 
 f2P 
 
 -PORTABLE HOG AND SHEEP PENCING. 
 
 may be reduced to 4" and the upper one increased 
 to 8". This makes a better division for all pur- 
 poses. The fence is held in place by triangular 
 frames, as indicated in the drawing. The ends 
 
 PIG. 254— PORTABLE HOG AND SHEEP FENCE. 
 
 of the panels overlap about 6" and fit into notches 
 for the top and bottom boards. The brace should 
 be on the outside of the lot. This style of fence 
 is very satisfactory for sheep and will serve the 
 purpose of a temporary fence for hogs, though 
 it is sometimes necessary to stake it at the braces. 
 
 Another portable fence (see Fig. 255) is thus 
 described : 
 
 The panels are made of 6" pine fencing 12' 
 long, with 4" and 5" spaces between the boards, 
 as shown in the illustration. This makes a fence 
 4' high. The planks are nailed at each end to a 
 2" x 4" scantling 4' long, which has two holes 1" 
 
 PIG. 255— PORTABLE HOG AND SHEEP PENCE. 
 
 in diameter for the purpose of putting the fence 
 together, with a brace between the panels, as 
 shown. In the center of each panel is a brace 
 made of 4" fencing. The main braces are made 
 of the same; they are 6' long; the top brace is 
 bolted to the other at the ground. The extra 
 holes in the upper brace are to regulate the posi- 
 tion of the fence on a hillside. The braces may 
 be put on either side; they are usually put both 
 ways. Iron pins 18" long, with an "f" hook at 
 
 one end, are used by driving into the ground with 
 the hook over the brace. Wooden pins are used 
 to hold the fence together, running through the 
 braces. 
 
 PORTABLE HOG FENCE. 
 
 For a portable hog fence the combination of 
 wire and wood serves well ; it is light, cheap and 
 if good wood be used is durable. Timber should 
 be used that will not warp or twist. Hemlock 
 will serve and 1" x 6" stuff is heavy enough, 
 though if it is to have much hard use 2" x 6" will 
 be better. The illustration (Fig. 256) shows 
 
 PIG. 256— PORTABLE HOG PENCE. 
 
 clearly how it is put together, with long nails 
 clinching, or bolts. Wire fencing, cut into 
 suitable lengths, leaving ends long enough to pass 
 clear around the end pieces and tie, is used. Tie 
 the wire also to the horizontal pieces at intervals. 
 Except for special purposes it is better to buy 
 woven wire hog fencing, stretch it about the land 
 to be pastured off, support it by stakes and when 
 through with it roll it up again and take it away. 
 
 ENGLISH HURDLES FOR SHEEP. 
 
 English hurdles for sheep are made so light 
 that the shepherd can move them on his back. 
 The drawing (Fig. 257) is of a good hurdle made 
 
 I D 
 
 PIG. 257— ENGLISH HURDLE POR SHEEP. 
 
 of hard wood iy 2 " x2" 4' long; sharpen one 
 end; band the other end with a strip of hoop 
 iron so it cannot split or wrap it a few turns tight 
 with No. 12 wire; put on four bars of light. 
 
MISCELLANEOUS. 
 
 145 
 
 straight wood, pine is best; these bars are 1" x 3" 
 and 10' long. There must be a bar to make holes 
 in the ground for inserting the posts, which then 
 get a tap or two with the sledge to make them 
 solid. A metal band slips over and holds the 
 tops together. Heavy wire will serve or light 
 wire for that matter. 
 
 BRACING A WIEE FENCE. 
 
 The general principle of bracing a wire fence 
 is shown in Fig. 258. This brace is a rod of %" 
 iron, nutted and threaded at each end, passing 
 through a 3' length of 6" x 6" stuff. If the iron 
 rod is not at hand a cable of six twisted wires 
 
 JW_ 
 
 FIG. 258-*RACING A WIRE FENCE. 
 
 may be used. This brace is cheap> — will hold the 
 post down instead of pulling or pushing it up. 
 It also is immovable and frost or wet does not 
 affect it. It is not generally desirable, however, 
 to have a brace extending out beyond the end of 
 the fence. When it is not desirable to have such 
 a brace the difficulty in obviated by the brace 
 shown in Fig. 260. Take half of this illustration, 
 
 PIG. 259— BRACING A WIRE FENCE. 
 
 which shows a gateway in the line of fence, make 
 the end of the wire cable, C, or rod, as the case 
 may be, and make it fast to the "dead-man," D ; 
 this gives an end that will allow any strain with- 
 out getting out of plumb or moving the post in 
 the least. If a wire oable is used at C it is well 
 to make it large and tightly twisted and short 
 enough to make the posts B incline towards each 
 other at the top a very little before the wire is 
 strained, so that when all tine slack is out they 
 will be perpendicular. With an iron rod nutted 
 at the up'per end this is not necessary, for any 
 obliquity can be remedied by a few turns with the 
 
 wrench. When a gateway in the line of fence is 
 required the plan shown in Fig. 260 has been 
 found very satisfactory. The cable or rod passes 
 under the block D, which should be a good dura- 
 ble stick of oak, 6" x 6" and about 4' long. The 
 fence will not lift it. 
 
 Fig. 259 illustrates the bracing of a post when 
 it is desired that no brace should appear to view, 
 as in the case of a lawn or yard fence. C is a rod 
 of %" iron passing through the lower end of the 
 
 l~ 
 
 
 1 -f] 
 
 1 ^\^ a 
 
 
 
 
 \^ / 
 
 FIG. 260— BRACING A WIRE FENCE. 
 
 post and the end of the brace, B. There is also 
 a block of 2" x 6" on the front of the end of the 
 post to keep it from moving forward or lifting 
 up. The short post is not fastened to the brace, 
 which merely rests on it. Braced in this manner 
 the post will remain perpendicular unless strain 
 is brought on it sufficient to bend it. It should 
 ibe of 8" x 6" stuff. The brace B should be of 
 6" x6" stuff and about 6' long. 
 
 A GOOD CHEAP FENCE. 
 
 L. N. Bonham of Ohio, a few years ago con- 
 tributed the subjoined article to The Breeder's 
 Gazette: I have completed 110 rods of wire 
 fence that has every appearance of giving good 
 service. We" have in the township more than 40 
 varieties of wire and wood fences, but few of 
 them combine cheapness and efficiency enough 
 to commend them. The farm was originally 
 refenced with good locust posts and the best pine 
 fencing for the majority of road and field fences. 
 I used the old fence material found on the farm 
 for slat fences, which have done good service, as 
 some of them are good yet and will last several 
 years longer. 
 
 I have always claimed that the well-made fence 
 is the most economical. The wire fence I 
 describe replaces a division fence that was built 
 from the second grade of lumber and posts. I 
 bought lumber and posts by the carload and as 
 I hauled the lumber and posts to the farm I 
 sorted each into three grades. This was on the 
 theory that a fence, like a chain, is no stronger 
 than its weakest link. 
 
 It does not pay to put sappy or cross-knotted 
 boards into the same panel with strong, sound 
 lumber. The lines of fence built with the three 
 different grades of posts and boards are lasting 
 in proportion to the quality of material used. 
 The fence made of third-grade boards and poets 
 had to be repaired several years ago and was later 
 
146 
 
 FABM BV1LDINQS. 
 
 removed. I am now replacing division fences. I 
 hope the wire fence will last as long as did my 
 third-grade pine and locust fence. The posts I 
 have used in the wire fence are made from old 
 locust trees which the borers had damaged, so 
 the posts are not first-class and would not do for 
 a board fence, even if I could get as good fencing 
 as I purchased 25 years ago. 
 
 The new fence has a post every rod set 36" in 
 the ground. There are 10 strands of No. 10 
 galvanized wire, each double and twisted into a 
 cable as the fence is made. For stays between 
 the posts I have a crimped No. 9 wire that is put 
 in every 15" as the weaving progresses, and these 
 stays- are gripped by the cable so firmly that 
 neither cables nor stays can be displaced without 
 force enough to break one or both. The fence is 
 hog-tight and bull strong. In the line of 110 
 rods I have three anchor posts 9' long (butt cuts 
 of whiteoak) squared to 12" above ground. They 
 are set 4' in the ground and braced and anchored 
 
 FIG. 261— A GOOD CHEAP FENCE. 
 
 as shown in Fig. 261. A is an oak timber buried 
 horizontally 3' under ground and at right angles 
 with the fence. Around the middle of this "dead 
 man" are four strands of No. 9 galvanized wire 
 E that pass around the anchor post B and are 
 twisted into a cable. Another cable of the same 
 size and material passes around anchor post B 
 near the ground and post C near the top. After 
 the brace is put in place this cable is twisted tight 
 enough to hold the second post firmly against it. 
 Each end of the line of fence has the same 
 arrangement of anchor posts, braces and cables, 
 and in the middle of the line (55 rods from each 
 end) is another anchor post similarly braced, 
 except the cable is attached to an extra strong 
 fence post instead of a "dead man." 
 
 The anchor posts are painted with oil and 
 mineral paint and the tops covered with tin 
 painted on both sides. The wires pass through 
 the center of the anchor posts to ratchets. I 
 think the twisted strands of wire will be less 
 affected by changes of temperature than plain 
 wire. I had the fence built in hot weather in 
 preference to freezing or cold weather, as my 
 
 experience is that wire and slat or paling fences 
 keep in place better when put together in dry, 
 hot weather than when built early in the spring 
 or late in the fall. 
 
 I see many failures in wire fences from lack 
 of well-constructed anchor posts and stays and 
 from placing the posts too far apart and not deep 
 enough. The most common form of bracing is 
 to set one end of the brace near the top of the 
 anchor post and at the foot of the next post in 
 the line, and it is no uncommon sight to see the 
 anchor post rise enough during the first winter 
 to ruin the fence. I can no longer afford board 
 fences. Wire fences have many objections, but 
 their cheapness, neatness as well as ease of con- 
 struction and keeping clean commend them. 
 Before setting this fence I plowed a head land 
 10' wide, harrowed it well and sowed grass and 
 clover seed. Such a fencerow is free from weeds, 
 furnishes good pasture and gives increased height 
 and better drainage to the fence. 
 
 FARM GATES. 
 
 Every fence must have its gate. Where gates 
 are opened and shut several times every day it 
 is very important that the gate move easily and 
 quickiy. There are two gates that are in com- 
 mon use. The first is the common board gate 
 which slides part way open on two wooden pegs 
 before it swings. The second is the hinge gate. 
 The first has the advantage of being easier on 
 the posts. There is also an iron gate manufac- 
 tured on the same principles, but instead of 
 sliding it is provided with rollers. The hinge 
 gate is quickly and easily swung. The greatest 
 trouble is in keeping the gate posts in position 
 so that the end of the gate will not drag. If the 
 ground is not firm the post hole should be 
 tamped full of small rocks against the back side 
 of the post at the bottom of the hole and another 
 at the top on the front side. 
 
 A still better way is to set a permanent gate 
 post in cement. Gates are sometimes hung so 
 that the top hinge is set back about 2" so as 
 to raise the gate as it swings open. If the swing- 
 ing end of the gate is set on a block when the 
 gate is open or shut, the strain on the gate post 
 will be greatly relieved. The board gate of course 
 is the cheapest. 
 
 Of the iron gates the prices on 14' gates are 
 from $8 to $9, according to height. There are 
 several forms of patent opening gates on the 
 market costing more. Some of them are quite 
 satisfactory, though none of them meets all the 
 requirements. 
 
 Thorp is nothing on the farm that adds more 
 to the appearance of the place than a good fence. 
 There may be some choice as to the kind of 
 fence one would want to use but there is no choice 
 
MISCELLANEOUS. 
 
 147 
 
 as to the way it should be. built. Every fence 
 should be carefully built; it will last longer and 
 increase actual value of the farm. The late Jere- 
 miah M. Eusk said: "Show me the farmer's 
 fences and I will tell you the kind of farmer he 
 is." 
 
 This gate (Fig. 262) is horse-high, bull-strong 
 and pig-tight, besides being light and easily 
 opened and closed. It swings both ways, hangs 
 on common iron hinges and an iron cable fastened 
 from the outermost end to the swinging post. 
 This cable may be tightened as the gate sags by 
 means of a turn buckle. When the gate is closed 
 
 FLATTENS 1 SURFACE OF LD^DlJBtn^ UNOERNEAWMTE I 
 IMG. 268— FARM GATE. 
 
 it stands 2" above a sill; the sill is made by im- 
 bedding a log, flattened on the upper-side, di- 
 rectly underneath the gate. The imbedded log 
 is not level with the surrounding ground but is 
 raised several inches and the ground leveled off 
 to a gentle slope so as to make the approach to 
 the sill gradual. This makes the gate swing more 
 than half a foot above the ground when opening 
 or closing and it can clearly be seen that this 
 would help considerably to make easy the use of 
 the gate during heavy snows. The latch is simply 
 
 Pig. 263 shows a farm gate that is hung to 
 swing clear in and out and is constructed of the 
 best yellow pine or hard wood. The advantage 
 claimed for it is that it swings clear either in or 
 out, is easily opened by one on horseback from 
 either side, is self-fastening and does not sag. 
 The materials necessary in construction include 
 one post 8"x8" and 15' long; one post 6" x 6" 
 and 8' long; one piece 4" x 4" and 10' long, main 
 standard; seven pieces 1" x 4" and 14' long, hori- 
 
 B'lG. 264. 
 
 zontal strips; two pieces 1" x 3" and 17' long, 
 braces; two pieces 1" x 4" and 6' long, end stand- 
 ards; one piece l"x3" and 4' long, latch; one 
 piece 1" x 2" and 3%' long, handle bar; one piece 
 of y 2 " galvanized rod 3' long; three pounds 10- 
 penny wire nails and 20' of wire for another 
 brace. 
 
 FIG. 265. 
 
 a. sliding 4" stick with notches cut in it so as to 
 keep the latch in place when open or closed. 
 
 The latch is hung with No. 24 copper wire, 
 swings clear and has no friction. The lower end 
 of the handle bar passes through a staple 4" wide 
 driven through the latch. The catch is made of 
 2" x 3" hard wood 8" long and is gained in flush 
 
148 
 
 FARM BUILDINGS. 
 
 on post. The gate rests on a 6" x 6" block set 2' 
 in the ground. Pit the thimble skein over the 
 top of the main standard, bend y%' rod as shown 
 and staple to the post. In the bottom of the 
 standard insert an iron pin 4" long to fit in a 
 hole in the bottom block. 
 
 A gate that gives general satisfaction is con- 
 structed as follows: Set two posts 20' apart, 
 take a piece of strong timber 20' long, mortise 
 and tenon down on top of the posts and bore a 
 2" hole in the center of the cross-piece. The 
 gate posts should be high enough to allow a load 
 of hay to pass under this cross-piece without the 
 latter dragging off the driver; take two pieces 
 of iron 2' or 3' long, an old wagon tire will do, 
 drill three holes in each piece large enough to 
 receive a %" bolt, hammer one end of one 
 piece round to go through the 2" hole in the 
 cross-piece overhead and hammer one end of the 
 other piece of iron to an abrupt bevel to fit into 
 an iron socket near the ground, which is the axis 
 or pivot upon which the gate is to turn. Take 
 two 2" x 4" scantlings, bore three holes in each 
 end of each one to match the holes in the irons, 
 put the irons between the scantlings and bolt 
 securely; leave enough of the iron projecting to 
 go through the hole in the cross-piece, as shown 
 in Pig. 265, and enough projecting at the other 
 end to go into the socket near the ground. We 
 now have up the two gate posts, the cross-girder 
 and upright pivotal piece upon which the gate is 
 to turn. (Pig. 264.) The gate may be built to 
 suit one's personal taste. When completed there 
 are two gates or two driveways 10' wide when 
 the gate is open, ' so that two teams may pass 
 through the gate at the same time. 
 
 Pig. 265 shows the gate closed. In the frame 
 work 2" x4"s are used and the upright or picket 
 pieces are 1" x 4" ; the latch is 3' long made of an 
 old buggy tire fastened to the gate at the distal 
 end with a loose bolt, having a hole in it 6" from 
 the end next to the gate post; one end of a small 
 rope is passed through the hole in the latch and 
 the other end of the rope through a hole in the 
 lower end of the lever and a latch receiver on 
 each post beveled on both sides makes it a self- 
 latcher when the gate is opened from either side 
 or turned round and round either way; it will 
 latch every time the latch comes to either post. 
 One can ride up to the gate, pull down the lever, 
 push the gate open, ride through, swing his horse 
 half round and close the gate behind or push it 
 forward until the latch catches in the receiver 
 at the opposite post. 
 
 The post for a farm gate is an all-important 
 thing. A good, strong, immovable post helps 
 to keep the gate in shape. Where practicable, 
 permanent posts of cement are recommended, 
 
 with 3' below the surface. As to the gate shown 
 in Pig. 266, an iron runs through the post 6" 
 from the ground and another 4' above this. 
 These rods project far enough from the posts 
 with bolt holes through the ends to form butts 
 for hinges on one side and on the other to screw 
 on a piece of timber, to which the fence is at- 
 tached. This gives a permanent and immovable 
 post, both for gate and fence. The posts have 
 square sockets in the upper end, in which can 
 be inserted wooden poets to construct an arch 
 over the gate if so desired. The posts are not 
 less than 15' apart on the inside and are con- 
 nected by a beam overhead 8' from the ground. 
 The gate is not less than 15' wide, and, instead 
 of being hung on hinges in the ordinary way, it 
 revolves on a center post. This gives two spaces 
 7\' wide when the gate is open, amply wide for 
 all ordinary farm purposes. The gate being 
 light can easily be lifted out of its holdings 
 for heavy machinery and wagons of hay to pass. 
 The upper beam can also be removed for the 
 higher loads. The gate itself is thus con- 
 structed: Pour slats 16' long, 1" thick and 4" 
 wide; two pieces of scantling 4' long, 4" wide 
 and 2" thick. Por a 15' gate saw one foot off 
 two of the slats and bolt them on the ends of the 
 scantling with 4" bolts running down into the 
 
 fflG. 266. 
 
 stile. The other two slats are used as bent braces 
 in such a way as to form two arohes bolted 
 together in the middle. Weave the wire of No. 9 
 and No. 15 and while it is still tight nail it fast 
 to the frame work. This makes a light, strong 
 gate through which no pig can squeeze and which 
 will defy larger stock. 
 
 The frame work is made fast to the revolving 
 post with three bolts with hooked ends. These 
 are put under the top and bottom slats and the 
 center of the brace boards, going entirely through 
 the revolving post. This post has an iron spur 
 at each end and a good ring fitted over the end 
 to keep it from splitting out. The bottom spur 
 is 1\" long and the top one 3". The bottom 
 revolves on a cedar or locust post in the ground 
 flush with the surface, and the top one in a hole 
 in the cross beam. The top one is long enough 
 to allow the bottom to be lifted out of socket 
 when necessary. The weight of the gate will keep 
 it in place. 
 
 To keep the gate from sagging put wooden 
 braces from each end up to the center post or 
 twist in a doubled No. 9 wire, which perhaps is 
 
MISCELLA NEO VS. 
 
 149 
 
 better. In this way are secured two short, strong 
 gates in one that can not possibly sag. There 
 are no hinges to be getting out of order. Use 
 lag bolts freely of various sizes. When used for 
 spurs to the revolving post, screw them up as 
 close as required and then cut off the heads. This 
 gives a good tight pin. 
 
 The gate can be constructed at a cost for 
 materials of about $1. It can be built by any- 
 one who is handy with tools for less than that 
 amount. When the gate is put in place it looks 
 neat and gives good satisfaction. 
 
 The gate illustrated in Pig. 267 is 5' high and 
 11' wide. It requires eight 16' boards. Hard 
 pine, dressed on two sides and 5" wide has given 
 satisfaction. A child can open and close it. Prop- 
 erly put up and with posts braced there is no sag 
 or twisting out of shape. One of these gates made 
 from rough pine fencing has been swinging 
 eighteen years and is still good, and has been 
 opened and closed as often as 20 times daily. 
 
 DIG 267. 
 
 The latch is placed in the gate between the 
 brace boards, which are double, one on each side 
 of gate, as also are the end and center 'pieces. 
 Use two bolts in each board as shown in the cut. 
 It holds the gate in place better than when one 
 bolt is used. Porty-eight 3£"x§" bolts are re- 
 quired. The cost is about $6 for painting, build- 
 ing and lumber. 
 
 The type of gate shown in Pig. 268 for 
 pastures and fields may be 12' to 14' by 4£' high. 
 
 Make a frame of five pieces, two 2"x4" and one 
 2" x 6", as shown in illustration. Cut as many 
 pieces of No. 9 wire as are desired about 2' 
 longer than twice the length of the gate; fasten 
 the ends of the wire to 2"x6" after passing 
 around the out end. Creases should be cut in 
 the 2"x4" and 2"x6" pieces just deep enough 
 to imbed the wire. The wires being in place, nail 
 two l"xl2" pieces 5£' long, one on each side of 
 the 2"x6" end piece, forming a strong gate head 
 to which to attach hinges; the 18" extending 
 
 above the top of the gate, receiving one end of 
 the brace or supporting wire, as seen in Pig. 268, 
 makes the support more effectual. Over the 2"x 
 4s" at the opposite end I nail a l"x6". Next 
 twist the wires evenly until all are drawn tight, 
 but not too tight, else they will warp the frame. 
 To prevent stock from rubbing against the 
 gate some farmers use barbed wire in place of 
 No. 9 smooth just above the center and some- 
 times put on cross wires, doubling them and 
 
 ffIG. 268. 
 
 twisting between the horizontal wires, thus hold- 
 ing the latter in place and preventing pigs from 
 squeezing through. The number of horizontal 
 wires used will depend on the kind of stock 
 fenced against. The brace or supporting wire is 
 last put on and should be twisted till it holds the 
 outer end of gate at its proper position. If the 
 gate sags at any time one or two twists will bring 
 it up. This is a strong, neat gate that any one 
 can make, and if the parts of the wood that will 
 not be accessible after the gate is finished are 
 well painted or coated with hot tar before putting 
 together and all exposed parts kept well painted 
 afterward it will be a gate for a lifetime. 
 
 The drawing (Pig. 269) shows a farm gate 
 10£' longxand 5' high. The material used may 
 be l"x4" hard pine or oak, dressed on both sides. 
 Paint the pieces before putting the gate together. 
 Use five upright pieces, two 'at each end and 
 one in the middle. On the side with the middle 
 piece use two short braces and on the other side 
 a long brace. If this is done the gate will never 
 sag. Use as many boards in this gate as desired. 
 The fewer boards the lighter the gate will be 
 and the less the wind will catch it. Use No. 9 
 wire. Wrap each end around the head of the 
 gate, running it back to the heel,' where it is cut 
 off and fastened to a f " bolt, which has had the 
 head part bent into the shape of a hook B in the 
 
150 
 
 FABM BUILDINGS. 
 
 illustration. Eun the bolt through, the two 
 upright pieces at the heel of the gate. Tightening 
 up the nuts on the bolts will stretch the wires. 
 Staple each wire to each piece of wood that it 
 crosses. Do not drive the staples in tight. 
 
 FIG. 269. 
 
 The most important thing is the hanging of 
 the gate. Many farmers contend that all gates 
 should be made to open both ways. This will 
 save many runaways besides being much more 
 convenient. Use strap and screw hinges. When 
 boring holes in the gate post for the screws 
 begin on the corner of the post and bore toward 
 the opposite corner. Fasten the hinges on the 
 bide of the gate that will permit of it being 
 opened both ways. 
 
 The plan of a gate that can be instantly ad- 
 justed to any height to swing over snowdrifts or 
 set high enough to allow sheep or pigs to pas? 
 beneath it and restrain cattle or horses is indi- 
 cated in the drawing. 
 
 This gate may be made of light, stiff material, 
 good pine being commonly employed. The 
 planks may be l£"x4", and any length up to 12'. 
 It is all put together with f" carriage bolts. 
 Pig. 270 shows the Fate with holes bored and 
 
 FIG. 270. 
 
 half the upright pieces in place. It will be 
 noted that the braces A B are bolted through 
 the rail next the bottom at C, and the other bolts 
 merely pass through the braces either above or 
 below the rails, as shown in the drawing. The 
 connecting pieces D must be just f" above the 
 
 top rail when the braces are vertical, as in 
 Fig. 270. 
 
 Fig. 271 shows the gate completed and the 
 braces pushed back to hold it square. These 
 braces must be put on loosely enough so that 
 
 PIG 271. 
 
 they will work easily back and forward, and 
 washers should be put between the braces and 
 rail at C. 
 
 Fig. 272 shows how the gate is raised up and 
 the braces pushed back to hold it to allow pigs 
 to run under it. It may be raised much higher 
 than this if desired. By pulling the brace for- 
 
 TIG. 272. 
 
 ward the end of the gate drops to the ground 
 and this serves to keep it open when desired. The 
 hinges are common strap and screw hinges, the 
 strap bent around as shown in Fig. 272 and 
 bolted to the vertical pieces: 
 
 To make the gate represented by Fig. 273 re- 
 quires eight 6" pine fencing boards 16' long. 
 
 FIG. 278. 
 
 Plane them smooth on both sides. From six of 
 the boards cut 5$', leaving them 10$' in length 
 for the bars of the gate. Take two of the 5f 
 pieces and use for battens for the back. Eip 2" 
 
MISCELLANEOUS. 
 
 151 
 
 off two .others and place them 3^' from the 
 front of the gate, one on each side of the bars. 
 Take another of these boards, rip it into two 3" 
 strips and use for battens for the front part. 
 Take the two remaining boards, cut them the 
 proper length to reach from the bottom of the 
 battens at the back to the top of the battens 
 which are placed 3|' from the front. Kip enough 
 off one side of these boards to make them 4" wide 
 at the top, leaving them 6" wide at the bottom. 
 To make this gate use f " bolts, placing a washer 
 under each nut. In hanging it the 12" hook 
 and strap hinges are the most satisfactory. Place 
 the latch just above the third bar from the top. 
 This makes it easy to be opened on horseback. 
 This is a neat, strong and substantial gate, and 
 can be built with but little waste of lumber. IE 
 kept well painted it will last many years. In 
 Jurying lumber make it a practice to select 
 enough good straight boards to keep material on 
 hand to make the necessary gates for the farm. 
 
 Fig. 274 shows a gate that has been used con- 
 stantly for the last 30 years. Probably the best 
 material out of which to make it is seasoned 
 
 
 white oak or black walnut. Use fencing boards 
 .1" thick, 6" wide and 12' long, and for an ordi- 
 nary gate five planks high is enough: Bolt the 
 gate together with \" bolts and washers ; leave the 
 upright boards where the hinges are fastened 6" 
 wide and the other uprights and braces 3" wide, 
 which is strong enough and much lighter. Let 
 the braces into the uprights top and bottom \" ■ 
 The posts should be 10' long for a five-plank gate. 
 Cut the tops slanting like a roof and nail on a 
 short board for top. The bottom of the posts 
 should go into the ground 4' deep in a hole made 
 large enough to contain a yard of small broken 
 stone or bats well rammed in from bottom to 
 top mixed with the dirt or clay. Set the posts 
 12'4" apart, 2" at each end of the gate space. 
 Set the gate 4" off the ground, level on top, and 
 leave 2" at the top so as to make it open upward 
 
 and hang shut when not fastened. Make the 
 hinges of heavy wagon-tire iron, four f " bolts to 
 each. 
 
 Fig. 274A shows a gate that is made of common 
 fence boards generally 16' long fastened together 
 with wire nails clinched, then hung on a cleat 
 between two posts set close together. One of 
 the posts should reach up about 2' above the gate 
 with pivot for the lever to turn on. No matter 
 
 
 
 n 
 
 
 
 
 
 
 
 
 
 
 
 
 II 
 
 
 
 
 
 
 
 
 
 !H' ; ■■! 
 
 
 
 
 
 
 
 
 
 
 
 1 1 
 
 
 
 
 
 
 
 
 
 
 II 
 
 
 
 
 
 
 
 
 
 
 II.. ■ 
 
 
 
 
 
 FIG. 371A. 
 
 what the heft of the gate is when finished the 
 lever can be weighted until a small child can 
 open or shut the gate with ease. This gate 
 swings only one way. 
 
 Fig. 275 shows a gate that never sags. When 
 made of walnut or any other hard wood and 
 bolted together it will last indefinitely. Gates 
 of this type put up ten years ago and made of 
 black walnut l"x4" are good today and swing 
 
 PIG. 275. 
 
 clear of the ground. A post to which to latch 
 the gate when open will be found convenient, 
 for when properly hung the gate will not stand 
 open unless held. 
 
 The art of hanging a farm gate is not gener- 
 ally understood, and this is! the reason why so 
 many gates have their "noses" in the ground. 
 It is useless to say that the hanging post must 
 be well secured, for if a man does not care 
 enough about the working of his gate to secure 
 
152 
 
 FABM BUILDINGS. 
 
 the post, a gate with its nose in the ground is 
 good enough for him. 
 
 Pig. 276 shows a gate braced, hung 'and latched 
 as a Virginia farmer has been successfully using 
 it for 25 years. A gate hung and latched like 
 this is easily opened on horseback and one need 
 not look back to see if it is going to latch. At N 
 are notches 2£" or 3" apart-in the top slat for a 
 bolt in the top of the braces to rest in; this 
 allows the gate to be adjusted as desired. At I 
 is a safe-pin to prevent hogs from raising the 
 
 gate. At L two strong pins are put in the post 
 with a \\" or 2" auger, with a I"x8"xl5" board 
 nailed on as shown, with the side next to the 
 gate dressed. The inner edge of the board is 
 about 1" from the gate and just far enough from 
 the post for the latch to pass behind it freely; 
 the outer edge of the board should be at such 
 an angle from the gate as will cause the latch to 
 strike it near the outer edge; this causes the 
 latch to swing back and glide in easily. 
 
 Fig. 277 explains how the gate is hung to in- 
 sure self -shutting. The posts are leaned from the 
 gate about 3" ; this causes the gate to rise as it 
 is opened and to descend as it is shut. The gate 
 comes down to the proper place when shut. To 
 make this plan of hanging plain, if the gate 
 
 FIG. 277. 
 
 stands east and west when shut and points south 
 when open the posts should lean north ; the more 
 they lean the higher the gate will rise when 
 open and the more heft it will have on going shut. 
 Posts should stand plumb east and west. To 
 obtain the same result in hanging gates to trees 
 or posts already set which are plumb the bottom 
 hook in the post should extend about 3" further 
 from the post than the top one. Hooks must be 
 
 put in side of the post as in Fig. 276. . At S, in 
 Fig. 277 is the stake behind to prevent the gate 
 from opening around further than is necessary. 
 The second and top slats should not be less than 
 l"x6", the braces l"x4". On several gates illus- 
 trated in this book the bottom hinge is shown to 
 be on the bottom slat. This will cause it to rot 
 loose quicker than if it were higher. In several 
 instances the braces are shown to extend to the 
 bottom, which will cause them to give way earlier 
 from decay. 
 
 Fig. 278 shows how by placing a stick of timber 
 a little below the surface of the ground solidly 
 from one post to the other the gate is prevented 
 from sagging down with the weight of the outer 
 end and the post must keep its upright position. 
 
 M 
 
 MG. 278. 
 
 It is not necessary that the sleeper should reach 
 clear to the second post, although it is better. The 
 earth will hold it if it is 6' long. At right 
 angles to this sleeper put another in the direc- 
 tion that the gate is to open and the post will 
 never sag in that direction either. 
 
 Fig. 279 shows a good strong gate that may 
 be very quickly nailed together and it is rigid 
 and retains its shape well with age and hard 
 usage. The two short braces make a better and 
 
 □C 7X~ '"A |~~- — , 
 
 stiff er gate than one long one would. Good pine, 
 l"x4", will answer for this gate, and about 12- 
 penny nails to put it together so that they may 
 clinch well will serve as well as bolts. 
 
 Fig. 280 shows a gate with a wire brace. When 
 there is much snow to obstruct gates it is some- 
 times desirable to raise them high enough to 
 allow them to swing over the drifts. The wire 
 looping around the gate and not fastened except 
 
MISCELLANEOUS. 
 
 153 
 
 at the upper corner may be slipped down as the 
 gate is raised to hold the outer end at any angle. 
 The wire brace ought not to come so low when 
 the gate is square as drawn; when slipped down 
 
 PIG. 881. 
 
 to position shown the gate should be in the same 
 shape as Pig. 281. This gate must be bolted to- 
 gether, one bolt at each intersection. 
 
 Fig. 282 shows a very strong and durable gate, 
 neat-looking and adapted to use along roadsides 
 where a neat gate is desirable. It is not expen- 
 sive to construct. The frame is of good pine, 
 2"x4", except the heel post, which is 4"x4". On 
 
 FIG. 282. 
 
 this frame, which is mortised together, is 
 stretched and stapled some sort of woven wire 
 fencing that will not be injured' by hard usage. 
 There are a number of varieties of wire fencing 
 that may be made right on the frame as wanted. 
 Large, strong hinges with screw bolts to go into 
 the post a good distance are advised for any kind 
 of gate. 
 
 Pig. 283 illustrates a form of gate that is in 
 extensive use in many localities. It is a 12' gate. 
 From upright A to upright B is 8' and from 
 upright B to C is 4'. The cut also shows a form 
 of home-made spring latch which will be found 
 very useful, especially when one wants to open 
 
 FIG. 283. 
 
 the gate from on horseback. 1, of course, is the 
 latch handle working on a bolt at K; 2 is the 
 latch proper; 3 is the latch spring fastened at H 
 and G with the upper end bolted to the end of 
 the latch. 
 
 The gate illustrated in Pig. 284 is made of 
 3" strips li" at one end and f " at the other. A 
 is made of 12" plank 1" thick. The strips are 
 nailed onto A. The ordinary hinge is used. The 
 top hinge is on one side and the bottom hinge 
 on the other side. The gate is hung plumb. The 
 
 FIG. 284. 
 
 bottom hinge must be put on the side where the 
 gate is to open. Make the gate, put on the 
 hinges and then plumb it. Mark where to bore 
 holes in the post while the gate is standing 
 propped up against the post. Any one can make 
 and hang such a gate. 
 
 A type of gate used a great deal in the South 
 
 FIG. 285. 
 
154 
 
 FARM BUILDINGS. 
 
 and shown in Fig. 285 usually is made of oak 
 timber and lasts remarkably well. It is light 
 and strong. The post A is set 3' in the ground. 
 F shows a .section of the post where the latch 
 strikes it. The latch slips into the mortise after 
 it is pushed back by sliding on the bevel. The 
 post B is set 4' in ground. The latch is sus- 
 pended by two pieces of No. 10 wire and the 
 whole gate is made of l"x3" oak strips. Eos. 8 
 and 10 wire nails clinched across the grain may 
 be used. They hold as well as bolts. 
 
 or else on the side of a barn or shed by bolts or 
 nails. The top length of the gate is 20' ; bottom 
 length 16' 6" ; height from ground 48". It is an 
 easy gate to open. 
 
 A Tennessee farm gate is presented in Fig. 
 286. It is light, cheap and durable. It can be 
 made as tall or as low as may be desired by using 
 
 FIG. 286. 
 
 many or few horizontal bars. The drawing shows 
 six bars which cut l"x4" and properly spaced 
 make the gate just 5' high. 
 
 The Minnesota farm gate shown in Fig. 287 
 will stand a good deal of rough usage. It is 
 made of four 2"x6" planks (hard pine pre- 
 ferred);, 6" apart, making it 42" in width, and 
 
 An Ohio farmer gives his views as follows on 
 farm gates : We have just finished overhauling 
 our gates which have had for ten years the rough 
 handling of tenants. We find the gates hung 
 with hinges made by our blacksmith with straps 
 2' long and hooks long enough to go through the 
 posts and with screw taps on the end all swing 
 clear, although made and hung many years ago. 
 On the other hand all gates hung with straps and 
 books that screw into the posts 5" to 6" are loose 
 and gates sagged and several of the hooks are out 
 and lost. The latter straps and screw-hooks with 
 bolts are furnished at hardware stores. They do 
 well for a few years, but are not as cheap in the 
 long run nor as satisfactory as the heavier black- 
 smith-made hinges. The latter are seldom used 
 now by farmers. The ready-made hinges are 
 neat and handy, but fail to give satisfactory 
 service as a rule. 
 
 We have three styles of gates. The cheapest 
 is placed where not often used and not along 
 the highway or near the houses and barns. Our 
 common slide gate is made 12' long and 4' high. 
 We use pine fencing boards 6" wide and 12' long, 
 of good quality, free from coarse knots. Six 
 boards are required for a gate five boards high. 
 The spaces between boards, beginning at the top, 
 are 9", 7" 5" and 3" respectively. The sixth 
 board, cut into three pieces 4' long, makes the 
 
 wig. 287 
 
 four l"x6" cross pieces. All are nailed together, 
 and also bolted by 5"xf" bolts except the rear- 
 end groove wheel, which is fastened on by a 
 6"x£" bolt.. A 6" pulley can be used for the 
 groove wheel. The front bottom wheel is a 6" 
 band wheel taken from any old machine. It is 
 bolted to the gate with strap-iron by 6"x£" bolts. 
 The cross pieces are on both sides of the planks. 
 At the bottom of two rear posts is a roller for the 
 gate to slide or roll in between. The upper rear 
 groove wheel B rolls on a beaded 2"x6" plank 
 which can be fastened' on the wire or board fence, 
 
 battens. One end batten is set back 6" from the 
 end of the gate; the other is set flush with the 
 end, and the third batten is in the middle of the 
 gate. The gate is put together with eight-penny 
 wire nails, clinched. We set two posts with sides 
 1-J" apart to receive the end of the gate up to 
 the batten. We next set a post 15" in from the 
 other end of the gate and another on the side to . 
 which the gate is to open and nearer to the end of 
 the gate, so as to allow the gate to come around 
 at right angles to the line of the fence. The gate 
 is to be supported on two cross strips nailed to 
 
MISCELLANEO US. 
 
 155 
 
 the two posts. The upper strips should be 6" 
 wide, coming under the top board, and the lower 
 strip 3" wide, coming under the second board 
 from the bottom, so that the gate is 3" from the 
 ground. Two strips of the same kind should be 
 put on the other posts, so as to carry the gate in 
 line with the fence. If these bottom strips are 
 3" wide, scant, they will fill the bottom space 
 at each end of the gate and prevent hogs from 
 lifting it. If now a 1" hole is boned in the third 
 board of the gate so a pin can pass through it 
 and between the two heel posts the gate cannot 
 be moved out of place until the pin is removed. 
 
 This land of a slip gate is very convenient for 
 division fences where there is not frequent pass- 
 ing through. The posts used with this gate 
 need not be heavy. We ■ find round posts, too 
 light for board fence, do admirably if straight 
 enough. The gate will last longer if the posts 
 are set as directed and there is only space enough 
 between the posts to allow the gate to pass freely 
 and not have much play when closed. It is a 
 cheap device, easily made, handier tihan bars or 
 slip gaps and will last 10 to 15 years with reason- 
 able care. We have never seen a sliding gate that 
 was equal to a hinged gate properly made and 
 well hung. It is miserable economy to go to the 
 expense for material for a gate and then neglect 
 to put it together in a substantial manner, or to 
 hang it with too light hinges to posts poorly set 
 or too light to carry the gate. 
 
 We have several swinging gates that were made 
 fifteen years ago and are good for several years to 
 come. Occasionally we find one of these gates with 
 a broken board or stem. It is but a small task to 
 loosen the screw bolts and put in a new piece and 
 the life of the gate is prolonged and it does its 
 work satisfactorily. It is very poor economy to 
 neglect the gates when they drag or are not in 
 condition to turn stock. Neglect to keep gates in 
 repair is even more expensive and dangerous than 
 to neglect fences. Either entails loss to stock and 
 induces bad habits that are troublesome and 
 costly in the end. The swinging gates are 12' 
 long by 52" high. This is 4" higher than a com- 
 mon board or paling fence. It is better to have 
 the gate higher than the fence, as stock will 
 naturally try to get out at the gate* before they 
 will try the fence. The gate yields to the pressure 
 more than the fence, and if a little higher than 
 the fence the animals are less apt to reach over 
 and press against it. To strengthen the top 
 board we have a strip 3"xl" nailed on the top. 
 This stiffens the top board and covers the ends 
 of the battens so the weather does not check the 
 ends nor rot wood around the bolts. 
 
 The swing gates are made of 6" fencing of 
 good quality put together with bolts 3|"xf ", with 
 washers under the tops. Ours are five boards 
 
 high and the spaces between the boards beginning 
 at the top are 8-J", 6", 4£" and 3", respectively. 
 The design is the same as shown in Fig. 288, hav- 
 ing the one long brace from the lower corner of 
 the end to which the hinges are attached to the 
 upper end of an upright 4' from the swinging 
 end. It pays to make the joints of the brace 
 neat and true and even to paint the ends of the 
 brace and battens to prevent decay. The lumber 
 should be fairly well seasoned and bolts well 
 drawn up. There is little danger of getting the 
 hinges too heavy, but much danger of getting 
 them too light. We find that where the bolt 
 nearest the hook is f " or less it breaks before 
 any other part of the gate. The most of the 
 hinges found in the stores take too small bolts. 
 If the heel bolts hold and the hooks that screw 
 into the post do not fail such a gate will last 
 longer than the average fence. The gate is 
 lighter if made with the brace and front battens 
 o"xX", and we find they do not give out. The 
 slide-latch is 3"xl", sides planed to move freely. 
 It enters a slot or mortise in the post. The 
 mortise should be 5" long and. 2" deep and a 
 full inch wide to admit the latch freely, yet 
 without much play. A handy man can make and 
 hang this gate in less than half a day. 
 
 We have another style of gate for along the 
 highway and near the barn, the grove, the car- 
 riage-house and other places where appearances 
 count something. The illustration (Fig. 288) 
 
 shows this gate. Gates of this style have beeu 
 painted every four years and those on the high- 
 way and grove and' near the carriage-house are 
 sound and swing as clear as they did 25 years 
 ago, and have .not cost a cent for repairs except 
 paint. The posts the gates are hung to are white- 
 oak, 9' long, butt cuts, squared to 10" at the 
 saw-mill half the length and left under cover 
 a year to dry out and not crack. The posts 
 were set 4' in the ground and are all good for 
 many years yet. The tops of the posts are 
 painted and covered with tin painted on 
 both sides. Such gates and posts are a solid 
 comfort, and considering the service and satis- 
 
156 
 
 FABM BUILDINGS. 
 
 faction given they are not more expensive than 
 some of the cheaper sorts that have given their 
 owners no satisfaction and been an endless 
 annoyance. In the building of farm gates and 
 fenoes that are to protect our crops and live 
 stock and make life endurable and less of a 
 burden it pays to build thoroughly well. 
 
 A GOOD LATCH FOE FARM GATES. 
 
 The latch shown in Figs. 289 and 290 is made 
 of a piece of 1" or %" round iron with a thread 
 cut on one end so that it may be screwed into the 
 
 PoSi 
 
 n 3/t/ Iron. 
 
 4a*e S*uf. 
 
 GOOD LATCH FOB FARM GATE. 
 
 Posf 
 
 ommiiwiiimmi 
 
 5/iu't'nJ 
 
 0— A GOOD LATCH FOB FABM GATE. 
 
 post and a %" hole drilled through the other 
 end in which is passed a piece of %" iron, or a 
 little larger, which is welded into a ring and then 
 bent into the shape shown in Fig. 289. This is 
 screwed into the post and the wooden latch or 
 one of the gate boards extends out to engage it 
 on the under side. A little loop of wire about 
 the raising part of the latch keeps it from flying 
 cleaT over when struck hard by the gate, or a pin 
 may be thrust through the stem of the latch. A 
 
 blacksmith can make one of these latches in a 
 quarter of an hour. 
 
 A FARM GATE HINGE. 
 
 The cut, Fig. 291, is of a hinge which, if 
 applied, will keep a gate shut without a latch 
 and permit it to swing either way. The gate 
 must be short enough so as to swing past the 
 post. When the gate is opened it will be farther 
 from the ground at the swing end than at the 
 post. When there is snow on the ground it will 
 rise over it instead of pushing it back. No. 1 
 is the hinge part for the post; No. 2, hinge part 
 for gate. The distance between the lugs (AA) is 
 
 R 
 
 J 
 
 
 
 HooV "■"> ^j" YW^j* 
 
 
 FIG. 291— A FABM GATE HINGE. 
 
 5". The greater this distance the higher the 
 end of the gate will rise as it opens. The shanks 
 (DD) of hinge parts Nos. 1 and 2 are driven into 
 the post and gate, respectively. When the gate 
 is hung the sockets (BB) bear against the lugs 
 (AA), one or the other of the lugs acting as 
 the pivot, according to the direction in which 
 the gate is f opened. Fig. 291 gives the position 
 of Nos. 1 and 2 when viewed from the post end, 
 I) being the shank which is driven into the post. 
 A hook-and-eye hinge is used at the top of the 
 gate. The nut on the shank of this hinge is 
 used in adjusting the gate so as to hang level. 
 
 WAGON EAOK AND STANCHION. 
 
 The plan illustrated in Figs. 292 and 293 is 
 of a cattle and hog rack. As a cattle rack it will 
 hold the most unruly and strongest cow or bull 
 in such a position that it cannot do any damage 
 to itself, "the driver or the wagon. The dimen- 
 sions are as follows: Use 1" lumber for rack 3' 
 high and 12' long; the top board is 9' 8" long, 
 lower board 12' long; there is a 6" space between 
 boards. The upright side pieces or slats are all 
 made of hardwood. Slats A, B and D are 3" 
 wide; slat C 1" wide; all double. Slat E is sin- 
 gle, placed outside, 3" wide, 2y 2 ' long. Slat F is 
 also single, placed inside, 2" wide and 16" long; 
 this slat is to rest on top edge of wagon-box to 
 hold front endgate when used as a hog rack. 
 
MISCELLANEOUS. 
 
 157 
 
 Slats are spaced apart as given in Fig. 293. 
 The cut-out board G, for placing on the wagon 
 seat, is slid in between double-slat D and bolted 
 to slats E and F. Nailed near the top on the 
 inside of rack and in front of slat C is a hard- 
 wood block (H) y 2 " x 18" ; it is used to prevent 
 the stanchion from being pulled down backward. 
 
 FIG. 293— WAGON BACK AND STANCHION (SHOWING STANCHION). 
 
 Ordinary endgates and end rods are used for the 
 rack in either end. 
 
 The movable stanchion (Fig. 292) is made 5' 
 high and 3' wide or inside width of wagon box. 
 Cross-pieces at the top and bottom are double; 
 bottom ones are of 10" planks and top ones are 
 
 of 6" planks. The uprights are 2" x 4". The 
 two middle uprights are movable sideways at 
 the top to open the stanchion and are locked by 
 sticking in ordinary iron pins between them. 
 For hauling cattle after the rack is on the wagon 
 place the stanchion crossways between the racks 
 in the wagon-box in front of block H. Bolt it 
 down with hook bolts (I), running the bolts 
 through the bottom of the wagon-box and wagon-, 
 box crosspiece underneath. Next bolt it side- 
 ways onto the rack with hook bolts at J. Hook 
 bolts are i/ 2 " 'thick, 12" long with 3" hooks, 
 threaded plentifully. To prevent the stanchion 
 from being pushed down forward use two stout 
 braces running upwards diagonally from the bot- 
 tom of front end of wagon-box to front of 
 stanchion against brace block at about point K 
 (Fig. 292). For ugly and dangerous animals 
 tie their heads downward, running the ropes 
 through the bottom of the wagon-box. 
 
 A VIRGINIA HOGPEN FRONT. 
 
 The drawing (Fig. 294) is of a pig pen front. 
 Posts are shown at each end, and constitute a 
 part of the fence. A is 1" x 6" top-board of gate, 
 and extends across posts. B B B are 1" x 6" 
 
 [FIG. 294— A VIRGINIA HOGPEN FRONT. 
 
 uprights and should be on the inside. C C C C 
 are 1" x 6". D is a small prop to hold the gate 
 back while feed is put in. E is a 1" x 2" cleat 
 nailed on front of post to keep A in place, cut 
 with slope on back side as shown at E, so that A 
 may have free play when the gate is pushed back. 
 F at left top is a strip of steel roofing nailed 
 down to posts and across A to keep pigs from 
 
 Stack JM% 
 
 PIG. 293— WAGON RACK AND STANCHION (SHOWING RACK). 
 
158 
 
 FARM BUILDINGS. 
 
 hoisting the gate. H is a spike driven in the post 
 behind A to keep the gate in place. I shows a 
 section of a board which should extend the full 
 length of the trough and stand 2" above the 
 trough. This board is used only in front to keep 
 the gate from going forward. The half-length 
 board J at left bottom is omitted in building the 
 gate. It is only added in the cut to show how 
 the gate appears when dropped ready for pigs 
 to eat The gate should be hung about 1" for- 
 ward at top. This will insure it to drop in place 
 when the prop is removed. 
 
 PREVENTING COWS FROM. SUCKING. 
 
 The device shown in Fig. 295 nine times out of 
 ten will cure cows from sucking themselves or 
 others. Put it in the cow's nose and with a pair 
 of large blacksmith pinchers close it enough to 
 
 PIG. 295— NOSE PIECE POR SUCKING COW. 
 
 prevent it coming out. To remove it run the han- 
 dles of the pinchers through the ring and spread 
 it. Smaller ones can be made for calves and 
 heifers. A blacksmith can make one of these 
 devices in a short time at small cost. 
 
 DEVICE FOR SELF-SUCKING COWS. 
 
 Cows addicted to the habit of sucking them- 
 selves should be taken in hand as soon as they 
 
 PIG. 296— DEVICE POB SELP-SUCKING COWS. 
 
 are known to be self-suckers. The longer the 
 habit remains unchecked the more difficult it 
 will be to effect a cure. The only cure is some 
 sort of a device to be worn by the cow. See 
 Pig. 296. C shows the form to make can- 
 
 vas bag. A piece of iron is riveted on front 
 belt to fit over back to keep harness from 
 slipping to one side. B shows snap at rear 
 end of canvas bag. A shows ring which is 
 fastened on front belt to hold bag forward 
 while milking in summer. Harness is made 
 of 1-inch leather straps. 
 
 ANCHORING A BARN TO GROUND. 
 
 To anchor a barn to the ground by means of 
 concrete blocks is quickly and cheaply done by 
 means of the wooden form, a frustum of a 
 pyramid, or a pyramid with the top cut off. It 
 may be IS" square on top, 24" square at the 
 bottom and 36" high, imbedded in the ground 
 according to the lay of the land about 24" ; holes 
 being dug at exactly the right places and to the 
 right depth the form is accurately placed (this 
 
 =1 
 
 TS 
 
 
 / " °|l \ 
 
 
 / !! * \ 
 
 / CD CD 1 
 
 
 / 
 
 l'iO 
 X 
 
 / CONCRETE 
 
 
 ZW. 
 
 
 PIG. 297— ANCHORING A BARN TO 
 
 THE GROUND. 
 
 is better done by the head carpenter) and the 
 block built by ramming in concrete. TWo bolts 
 are imbedded in the concrete; they may well be 
 flat strips with the lower ends turned over and 
 at the upper ends holes drilled to receive %" 
 bolts transversely. These iron strips must be 
 accurately placed to make easy work and when 
 the building is raised to place, the post rests 
 between them and transverse bolts hold it firmly 
 in place. See Fig. 297. 
 
 BREEDING-BOX FOR SWINE. 
 
 The dimensions of the box (Fig. 298) are: 
 length 5' 6", width 2' and height 3'. The length 
 of the short box, which may be made by moving 
 the end board j into the slot k, is 3' 6". The cor- 
 ner posts are 2" x 4" scantling and the sides 
 l"x4" strips; a a a are joists for nailing the 
 
MISCELLANEOUS. 
 
 159 
 
 1 ' a. 
 
 FIS. 298— BREEDING BOX FOR SWINE. 
 
 floor to ; b b extra boards to which the joists are 
 nailed to stiffen the sides of the box; c c are 
 boar supports which hold the boar's weight dur- 
 ing service. The one on the left is stationary, 
 while the one on the right is adjustable to the 
 size of the sow and should fit up tight against her 
 side; d is a piece used to adjust the right-hand 
 support; e is a pin which holds the support in 
 place; f is a strip to hold d in the groove or 
 mortise; the g's (of which there are six) are 
 pieces that hold the supports solid and are 13" 
 in length; h is a wooden screw to hold the front 
 end of the adjustable support in place; i is a 7 /s" 
 rod which is placed behind the sow to keep her 
 from backing out of the box ; j is a movable end 
 board which is used to adjust the box to different 
 length sows. When long sows are to be bred the 
 board is placed in the end of the box, as shown 
 in the diagram, and when short sows are bred the 
 board is removed and placed in the slotted board 
 k. LL are cleats which hold the bottom end 
 of the board j in place ; m is a platform used to 
 raise a small boar high enough to serve a large 
 sow. 
 
 A RACK FOR DEHORNING CATTLE AND 
 FOR RINGING HOGS. 
 
 The illustrations (Figs. 300 and 301) are of a 
 rack for dehorning cattle and ringing hogs. For 
 sills use three pieces 4' long and 4" x 4" mor- 
 tised for bottom of posts 8" each side of center 
 
 to allow the side and bottom boards to drop into 
 place. Four posts 4" x 4" and 5' 4" long and 
 two posts 4" x 4" and 5' 8" long are tenoned 
 to sills. Three cap pieces 2" x 4" and 4' 2" 
 long are mortised at ends to receive tops of posts. 
 The caps are of oak. One oak piece in front of 
 
 TIG. 300— A RACK FOR DEHORNING CATTLE AND TOR RINGING 
 HOGS (END VIEW). 
 
 the cap which holds the stanchion is 2" x 2" and 
 4' 2" long. The lower oak piece in front of stan- 
 chion is 2" x 4", 2' long. The lumber is 2" thick 
 and 7' long for sides. One board, 2" x 17", 7' long 
 is for the bottom. For stanchions in front one 
 board 2" x 10", 5' 6" ; one board 2" x 10", 5' 2". 
 
160 
 
 FABM BUILDINGS. 
 
 For back gate, two pieces 2" x 12", 4' 4" long, 
 cut sloping to fit frame. It is put on with hinges 
 as shown in the diagram. The gate is held up 
 by a piece of iron 1' long stapled to the upper 
 board at the side of frame to allow the cattle to 
 enter, and gate fastens when down with a forked 
 piece of iron as shown in Fig. 300. Stanchions 
 in front are bolted at the bottom between 2" x 4" 
 oak piece and sill, leaving a space up and down 
 in front 5" wide. Two and one-half feet from 
 the bottom of the stanchion slope out a place for 
 animal's neck. The 2" x 2" oak piece is bolted 
 to side of cap with blocks to allow the top of 
 stanchions to open and close and work with a 
 lever as shown in Fig. 301. The lever of wagon 
 
 FIG. 301— A BACK TOR DEHORNING CATTLE AND TOR RINGING 
 HOGS (SIDE AND FRONT VIEW). 
 
 tire is 5' 6" long. A %" hole is punched in top 
 of lever. The second hole is 13y 2 " from top hole 
 and the third hole 11" from second hole. This 
 lever is rounded at the lower part for a handle 
 and bent, being bolted between oak piece and cap 
 on corner of frame through middle hole of lever. 
 The upper hole is fastened to the left-hand 
 stanchion by two iron straps, one on each side 
 of stanchion. These straps. are 3' long, ^4" thick 
 and 114"' wide. The lower hole is fastened to 
 the right-hand stanchion with two pieces of strap 
 iron 14" long. When the stanchions are closed 
 bore one or two y 2 " holes in post back of lever, 
 in which use iron pin to open and close the 
 dehorner. Bore a hole outside of each post 1' 
 from the top to put rope around to hold the head. 
 Also spike two wedge-shaped pieces outside of 
 stanchions, as shown in diagram, to keep cattle 
 from getting their knees fastened. 
 
 The experience of most operators is that the 
 saw is the best implement to use in dehorning. 
 
 Unless the horns are taken off very close they 
 will bleed badly, and unless they are slanted with 
 the natural slope of the head there will be an 
 ugly square head, very unsightly to see. There 
 must be some skin removed from the upper side 
 of the horn. 
 
 A DEVICE FOR HOLDING HOGS. 
 
 The device shown in Fig. 299 for holding hogs 
 by the head while ringing is simple and cheap in 
 its construction and easy in its operation — so 
 simple, in fact, that the mere illustration fur- 
 nishes all the specifications necessary. The 
 uprights should be firmly set in the ground and 
 the upper piece of the stocks pinioned to the 
 upright on a pivot at A. By nailing boards to 
 
 
 
 PIG. 299— A DEVICE TOR HOLDING HOGS. 
 
 the uprights on both sides in the rear a small 
 chute may be formed by means of which the hogs 
 may easily be driven into the "trap." 
 
 BULL STOCKS. 
 
 The diagram (Fig.. 302) and description of 
 stocks for securing a bull so that his feet may 
 be trimmed or any other operation performed 
 are herewith presented. Probably most of the 
 stocks now in use at cattle breeding establish- 
 ments in the Central West were patterned after 
 the one built at Shadeland by the late Adams 
 Earl. Such stocks are a very great convenience 
 if not a necessity at all breeding establishments 
 where the bull is accorded proper care. 
 
 The timber is pine or hemlock, and the floor 
 the same, 3" or 4" thick. This gives a solid 
 foundation to stand on, and in some cases 
 the operator can trim the feet to advantage while 
 the animal is standing on the floor. The side 
 
MISCELLANEOUS. 
 
 161 
 
 timber D should be of oak; it extends beyond 
 the frame and there are three boles bored 
 through it. This is to bring the foot back as 
 follows : buckle a strap around the foot just above 
 the hoof (after the animal is drawn up), and 
 
 hoofs with a chisel. The tools commonly used 
 are a heavy mallet, an inch and a quarter chisel 
 and two crooked knives (right and left), such 
 as blacksmiths use. The bottom of the feet often 
 require attention and this can be done best by 
 
 FIG. 302— BULL STOCKS 
 
 bring the rope through one of these holes. This 
 will bring the foot on top of D, and it can be 
 tied there and the bottom of the foot pared off 
 as much as necessary. 
 
 In the octagon roller are hooks to which the 
 chains are fastened and two holes are bored in 
 the roller to hold iron rods used in turning the 
 roller and drawing the animal up. The chains 
 are ordinary trace chains, five on each side. The 
 belt is made with an iron rod on each end 1" 
 
 FIG. 305— POULTBY DRINKING FOUNTAIN. 
 
 in diameter, and the belt fastened around this 
 with chains, attached to rods. Use heavy leather. 
 The drawing shows the front of stocks. The round 
 sticks ZZ are removable from the top; usually 
 take out one until the animal is led in and placed 
 and then put the other one in, thus making the 
 head secure. There is only one timber across 
 the rear end of the stock, as shown by C. 
 
 It is a good idea to let the animal stand awhile 
 in the stocks before drawing him up> and the time 
 can be utilized in trimming off the ends of the 
 
 swinging the animal up and drawing the feet 
 back and using the crooked knives. The dimen- 
 sions of timbers are as follows: A — 6" x 6" by 
 7' 6" ; B— 6" x 6" by 9' iy 2 " ; C— 6" x 6" by 4' 
 10i/ 2 "; D— 4"x4" by 9' 1"; E— 6" x 6" by 6' 
 81/." ; F— 4" x 4" by 2'; X— Octagon roller, 6' 6" 
 long, 8" diameter; size of belt, 2' 11" by 5' 3"; 
 length of chains, 3' 5" (five chains) ; Z — Bound 
 oak sticks, 1%" in diameter by 3' 8" in length 
 (15" apart). Distance between D and B (base) 
 is 7". 
 
 POULTEY DRINKING FOUNTAIN. 
 
 A simple drinking fountain for poultry (see 
 Fig. 305) may be made as follows: Place an 
 ordinary milk-pan on a block or shallow box, the 
 top of which shall be 4" or 5" from the floor. 
 The water or milk to be drunk by the fowls is to 
 be placed in this pan. Over the pan is to be 
 placed a board cover supported on laths about 
 8" long, nailed to the cover so that they are about 
 2" apart, the lower ends resting upon the box 
 which forms the support of the pan. In order 
 to drink from the pan it will be necessary for the 
 fowls to insert their heads, between ihese laths. 
 The cover over the pan and the laths at the sides 
 prevent the birds from fouling the water in any 
 manner except in the act of drinking. .Where 
 drinking-pans of this kind are used it is very 
 easy to cleanse and scald them with hot water as 
 occasion demands. This arrangement can be car- 
 ried a little further by placing a pan or what 
 would be still better a long narrow dish, some- 
 thing like a tin bread-tray, on a, low shelf a few 
 inches from the floor, and hinge the cover to one 
 side of the poultry-house so that it can be tipped 
 up in front for the removal of the dish or for 
 filling it with water. Whatever device is used 
 
162 
 
 FARM BUILDINGS. 
 
 it must be easily cleaned and of free access to the 
 fowls at all times. 
 
 PENCE-BREAKING BULLS. 
 
 Herewith is produced an illustration of an 
 Australian device that is recommended by sev- 
 eral breeders in the "island continent." 
 
 A block of wood is screwed on to each horn 
 (see Pig. 303), and a wire stretched from block 
 
 tion is better than feeding by expressmen. A 
 neatly-built crate, a shipping tag bearing the 
 
 FIG. 303— FOB FEKCE-BBEAKING BOLLS. 
 
 to block and also to the nose ring, as shown. So 
 long as there is no pressure on the wires between 
 the ring and the horns the nose ring is simply 
 held upwards without any discomfort to the ani- 
 mal. Should the bull rush any other animal or 
 attempt to get through any fence, the pressure 
 pulls the nose ring upwards, causing considerable 
 pain. It requires very few experiences to teach 
 the animal that any misbehavior on his part is 
 attended by suffering to himself. In place of the 
 blocks on the horns the latter are sometimes bored 
 through near the point and the wires secured. 
 The blocks may also be put on in different ways, 
 the object being to bring the wires from the horns 
 to the nose away from the head and face. 
 
 A SHIPPING CRATE. 
 
 The illustration (Fig. 304) shows a strong 
 shipping crate for hogs. It should be well built 
 of pine or other light wood. Por sheep a similar 
 construction is good but %" lumber is heavy 
 enough. About 16" wide, 3%' to 4' long and 
 30" to 36" high are the right dimensions for a 
 sheep crate. If it is to go a long journey wire 
 in a small tin pail in one corner, so that the sheep 
 can be watered. One can put a lot of green 
 clover or grass in the crate at the beginning of 
 the journey. Do not try to feed much 'grain nor 
 to send a bag of it along unless a very dilute 
 chop, mostly of bran, for a short period of starva- 
 
 FIG. 304— A SHIPPING CBATB. 
 
 shipper's name and that of his farm will often 
 aid in selling stock. 
 
 DEVICE FOR COVERING STACKS. 
 
 A simple and inexpensive device for the pres- 
 ervation of hay put up in ricks or stacks (Fig- 
 
 FIG. 306— DEVICE FOB COVEBING STACKS. 
 
 306) is constructed as follows: Use common 
 boards 12' to 16' long, a foot or more wide,- put- 
 ting one on top of the rick first, then slipping 
 one on each side under the top one about two 
 inches and fastening by driving a common fence 
 staple over a No. 9 smooth wire just at the edge 
 of the upper board so as to make a sharp bend 
 in the wire over the edge of the upper board, 
 and so on down as far as wanted ; six to eight 
 boards on each side are generally enough; then 
 fasten a good-sized stone in the end of the wire 
 and the thing is finished. Use two wires to each 
 length of board about 2' from the ends and as 
 many sections as may be needed for the length 
 
M1SCELLA NEO VS. 
 
 163 
 
 of rick, putting the middle section on last with 
 the ends lapping over the next ones. In using 
 the hay a single section is taken off by drawing 
 out the staples and the rick cut down so as to 
 leave the cover over the remainder. Boards, and 
 wire can be used over and over again. 
 
 A PORTABLE HOG-LOADEB. 
 
 A device for loading hogs and sheep that is 
 very handy, light and strong is shown in Fig. 
 307. It can be moved readily or it can be backed 
 up to the wagon and by a rope or chain attached 
 to the wagon bed and hauled to the distant pen 
 or lot where hogs are to be loaded. It saves 
 moving the hogs from their feed-lot to some 
 strange place or corner, which always excites or 
 worries some of them. By the use of a hurdle 
 or two as many can be cut out from the drove 
 as will load the wagon, or the chute and wagon 
 can be backed up to the door of house or pen 
 and the hogs enter the wagon without any 
 worry. 
 
 PIG. 307— A PORTABLE HOG-LOADER. 
 
 The cut (Fig. 307) represents one side of the 
 chute set ready to load into the wagon. It is 
 easily made. The bottom is two 12" boards, 1" 
 thick and 10' long. Each side has one board of 
 the same dimensions and two boards 6" wide 
 and 1" thick, with spaces of 4". This makes 
 the side 2' 8" high. The two uprights are 2"x4" 
 with a mortise 4"xl" at top and bottom to 
 receive ties that are tightened by a draw pin. 
 The lower ties support the floor and are 16" 
 from the end of the floor boards, which also 
 rest on the axle of the old buggy wheels used 
 for moving the chute. A third or middle upright 
 has a slot cut in the lower end large enough to 
 drop down over the axle. By cutting the slot 4" 
 deep the ends extend below the axle 3" and a 40- 
 penny spike or wooden pin put through the up- 
 right just under the axle will keep it in place. The 
 chute is 2' in the clear and the bottom board of 
 the side is nailed to the floor, which helps to 
 stiffen floor and sides. 
 
 It will be more convenient to make the chute 
 without the middle uprights, and before locat- 
 
 ing them place one end of the chute in the 
 wagon bed and the other end on ground. Now 
 put the axle and wheels under the chute and 
 locate so the axle will be a support to the bot- 
 tom, and then drop the middle upright down 
 over the axle 'and nail to the side of the chute, 
 using care to have the axle at right angles to 
 the bottom, and put in the spike or pin to hold 
 the axle in the slot of the upright. Cleats 
 should be nailed in the bottom to keep stock 
 from slipping. Before loading put straw in 
 the wagon and down the chute, which makes the 
 hogs take more kindly to the chute. 
 
 In some oases a cast-off pair of buggy wheels 
 and axle have been used for the chute. Of 
 course the axle must be cut so the hubs fit neatly 
 against the middle uprights. 
 
 A FARM ICEHOUSE. 
 
 In building an icehouse one of the main 
 objects is to secure isolation of the ice and to 
 surround it with an adequate barrier of non-con- 
 
 ^-^IC^fV-y VfNTLLATION, 
 
 PIG. 308— A FARM ICEHOUSE (CROSS SECTION). 
 
 ducting materials. To do this a triple wall of 
 planks or boards must be made from 12" to 18" 
 apart and the spaces between each compactly 
 
164 
 
 FARM BUILDINGS. 
 
 filled with sawdust or straw. The bottom must 
 be equally well secured and a drain provided for 
 the escape of water, yet not for the admission of 
 air. The drain as shown; in Fig. 308 is one of 
 the cheapest and best that can be made. This 
 drain is made by digging a hole 3' deep and 4' 
 square; over this are laid logs say 5y 2 ' long, 1' 
 wide and 6" thick. This permits the water to 
 run off the ice, but this will not be the case if the 
 ice has~been securely and properly packed. In 
 addition to this drain is a box 17' long made of 
 6" boards in which can be applied whenever 
 necessary a pump to draw out water. Over this 
 box should be kept a lid so as to prevent the 
 entrance of warm air. The dotted lines in Fig. 
 309 show that between the plank wall and ice is 
 left a space 6" or 8" on all sides of the ice, which 
 
 12 FEET 
 
 9— A FARM ICEHOUSE FLOOB. 
 
 is packed in with straw or sawdust, all spaces or 
 cracks between the cakes of ice being also filled 
 in with sawdust. 
 
 When filling the house 5" or 6" of straw and 
 sawdust are put on the floor. The ice is packed 
 solidly on this. Experience proves that this sur- 
 rounding of sawdust on all sides will keep the ice 
 satisfactorily the entire summer. The wall on 
 which the frame work is built is l'in height and is 
 built of brick or stone. This icehouse is 12' x 12' 
 and 17' in height, not including roof. The house 
 is filled in front by a door 3' wide and 4' high. 
 About half of the middle (as drawn in Fig. 308) 
 of the ridge is a cut-out, leaving an opening 4" 
 or 5" wide, and over this is a cap, supported by 
 a saddle piece at each end of it, leaving an open- 
 ing on each side under it for ventilation. The 
 cap extends far enough over to keep out rain. 
 An icehouse of this kind will cost from $25 to 
 
 $50. The entire house except the foundation is 
 made of pine lumber. 
 
 A COMMERCIAL ICEHOUSE. 
 
 The icehouse shown in Figs. 310 and 311 was 
 recently buiit in Iowa by W. M. Lambing to 
 supply a superior quality of ice to a limited num- 
 ber of consumers in a near-by city. It is 36' x 60' 
 and 22' to the plates, 6' of this height being below 
 ground and the remaining 16' above. The build- 
 ing holds about 1,400 tons of ice and cost about 
 $1,500. A stone wall 2' thick encloses the base- 
 
 FIG. 310— A COMMERCIAL ICEHOUSE (SHOWING MACHINERY). 
 
 
 
 s 
 
 flg^ ' &U- 
 
 ; 
 
 ^^ 
 
 ^H&— 1# 
 
 t 
 
 
 ■ -. - 
 
 ■W* 1 *-•'••«*■ 
 
 FIG. 311— COMMERCIAL ICEHOUSE (END VIEW). 
 
 ment. The studding used is 2" x 10'?, placed 2' 
 apart. Tar paper is placed on each side of the 
 studding, forming a 10" dead air space. The 
 floor is made of cinders spread 4" deep and a 4" 
 tile drain leads out from one corner, which is 
 lower than the other corners. The inside lining 
 consists of 8" flooring put on diagonally and the 
 outside is covered with 8" drop siding nailed on 
 diagonally, as shown in the engravings. The 
 building attached to the icehouse contains a 
 6-horse power gasoline engine which hoists 4.500 
 
MISCELLANEOUS. 
 
 165 
 
 pounds of ice per minute with the elevator showrj 
 standing in a lake. 
 
 THE VENTILATION OF STABLES. 
 
 Climates differ so widely that it is not possible 
 to lay down a rule of building that will be per- 
 fectly adapted to all situations. So also do breeds 
 differ in their requirements. The dairy cow should 
 be kept fairly warm, yet she needs abundance of 
 pure air ; the beef steer, heavily fed, cares little 
 for temperatures, so he is dry and out of the 
 wind. Horses need especially to have plenty of 
 fresh air. 
 
 Sheep can hardly have too much air. Being of 
 an essentially delicate organization they suffer 
 
 FIG. 312— VENTILATION OE STABLES. 
 
 severely from the poison of each other's breath. 
 A good way to ventilate the sheep barn is to have 
 on two sides or more a continuous series of doors ; 
 that is, make all the siding into doors and hang 
 on hinges. This costs little more than to side up 
 as it is usually done and is profitable from many 
 standpoints. Let the doors be cut in two hori- 
 zontally, the lower part about 3%' high swinging 
 as a gate swings, the upper part hinged at its 
 upper edge and lifting upwards like a box lid so 
 that it is supported by ropes with rings, or by 
 little braces hung on hinges. It is advisable to 
 put three strong hinges on the upper doors to 
 keep them in shape, and as they will be exposed 
 more or less they should be of good material. 
 When the weather is suitable all these upper 
 doors may be open, permitting a free circulation 
 of air through the barn, making it practically' a 
 covered yard; and when storms blow one side or 
 
 the other may be closed and only the lee-side left 
 open. 
 
 An architect and builder of stables says that 
 "if possible there should be a continuous but 
 narrow opening high up so arranged that the 
 stablemen cannot conveniently close it." This 
 should not be on the north or west side, but on 
 sheltered sides. Draughts on the horses are sources 
 of trouble, yet in some way provision should be 
 made for the ingress of a great abundance of air. 
 Windows, 2' x 3', put as high as the story will 
 allow, each one hinged at the middle of the sash 
 and controlled by a greenhouse adjuster, which 
 can manage several windows, provide the most 
 ready means of letting in fresh air. The hay 
 chutes may carry off more or less impure air and 
 should be boxed tight, with doors to open for 
 throwing in hay. There must be provision for 
 the escape of the air at the roof. 
 
 Milking cows seem to be of a nervous and sus- 
 ceptible temperament, making it necessary for 
 
 EIQ. 313— VENTILATION OF STABLES. 
 
 them to be kept much warmer than other farm an- 
 imals, so the supplying of fresh air and the re- 
 moval of that which is impure is a most important 
 matter. What is known as the King system works 
 very effectively. It is the building of the stable to 
 be as warm and as nearly air-tight as possible, 
 using two or more layers of wood with building 
 paper between. (See Pigs. 312 and 313.) A 
 covering of plaster on the outside would be of 
 advantage in this connection and save the wood 
 from weather as well. Unless the stable is nearly 
 air-tight the ventilators will not work well. 
 
 Ingress of fresh air is provided above the cows. 
 Prof. King says there should be an opening of 
 2' x 2' for 20 cows. It would perhaps be better 
 to provide more than one opening and of some- 
 what greater capacity than that. Cow stables 
 in cold climates should not be above 8' in height, 
 as the warm air raises out of reach of the animal, 
 and her body is to warm the stable. The ingress 
 of air is through a box that starts 2' or 3' below 
 the ceiling, rises and enters at the ceiling level. 
 This rise is to prevent the thing working the 
 wrong way and to permit the warm air to escape 
 at that point. The doors and windows should 
 fit well and there should be no leakage of cold 
 air from beneath the doors. The air escapes from 
 
166 
 
 FABM BUILDINGS. 
 
 the stable through flues starting close to the floor 
 level. These flues are better if they run straight 
 up through the roof to the level of the peak. They 
 may, however, be curved to follow the underside 
 of the roof and escape at the peak through a 
 cupola. These boxes in a cold climate should be 
 of wood, else they may fill with frost in very 
 severe weather from the condensation of the 
 cows' breath. The size of the flues should be in 
 excess of the size of the intakes; that is, for 20 
 cows there should be flues of a capacity of over 
 24" x 24" inside diameter ; for 40 cows twice that 
 amount. Warm air is lighter than cold air ; the 
 column of air in the flues is much warmer than 
 the column outside, therefore it rises, cool air 
 enters over the cows, flows over them, diffuses, 
 sinks to the ground, enters the flues at that level 
 and goes out from the building. Carbon dioxide, 
 the poisonous product of breathing, is heavier 
 than air and tends to settle to the floor, even 
 though it is warm; it is thus drawn up and out. 
 Also the coldest air in the stable is that which 
 is drawn out. There should be, however, pro- 
 vision made for letting the air at the ceiling 
 escape directly into the ventilators when that it> 
 desired. Both openings should be provided with 
 valves that may be opened or closed at will. 
 
 DIPPING TANK CONSTRUCTION. 
 
 It behooves every stock owner to see that his 
 animals are free from skin parasites. Young 
 stock especially should receive attention in this 
 matter. The cold rains, sleet and snow of win- 
 ter are new experiences to many of them and 
 even if they are in perfect condition and free 
 from parasites the winter months tax their vital- 
 ity severely. Matters will be much worse if lice, 
 fleas, mites and ticks are robbing the young ani- 
 mals of the nourishment they need. Lousy ani- 
 mals may pull through the winter but the set- 
 back which they receive from the combined 
 effects of parasites and cold stormy weather 
 seriously impairs their usefulness. 
 
 As a means of correcting this condition, dip- 
 ping is a question that stockmen can well afford 
 to think about. It was not many years ago that 
 sheep were the only animals supposed to require 
 dipping, and the very suggestion of dipping hogs 
 or cattle would have been ridiculed. Why such 
 a sentiment should exist concerning the dipping 
 of hogs and cattle is not clear. The latter ani- 
 mals suffer just as much from parasites as sheep 
 do. Fortunately this prejudice is disappearing. 
 Dipping is now recognized as the easiest and 
 most satisfactory treatment of mange and other 
 skin diseases of cattle and the best swine breeders 
 of the country regard dipping as essential to 
 their success. No domestic animal can thrive 
 while it is being tormented by lice and the food 
 
 it eats is being stolen by myriads of parasites. 
 No manner of combating skin parasites and 
 diseases is equal to that of submerging the ani- 
 mal affected in a fluid capable of destroying the 
 pests, that is, dipping. 
 
 Of course it is essential that the fluid used 
 should not be injurious to .the animal itself. 
 Spraying or scrubbing or dusting with insect 
 powders or greasing with lard and sulphur will 
 furnish some relief to animals infested with 
 parasites, but there is nothing equal to a swim in 
 a good penetrating dip. The selection of an effi- 
 cient dip is essential, that is,one that will destroy 
 unfailingly the parasites and at the same time 
 have no bad effect upon the skin and hair or 
 fleece. Coal-tar carbolic dips are being recog- 
 nized as the most satisfactory preparations, 
 since they come nearest meeting these require- 
 ments. They are death to lice and mites and 
 other vermin, and at the same time their effect 
 upon the skin and hair is, stimulating and invig- 
 orating rather than otherwise. 
 
 The tank problem is one which puzzles many 
 farmers. The galvanized iron tank fills a long- 
 felt want for a light durable tank, without leaks 
 and easily transported from place to place. 
 Tanks of this description are manufactured in 
 the large cities and are becoming popular 
 throughout the country. Many regard a galvan- 
 ized iron tank rather too expensive, especially 
 where high freight charges must be added to 
 original cost. Many farmers would prefer to 
 construct a tank from materials that may be 
 obtained close at home, working at the job at 
 odd times and thus utilizing time which would 
 otherwise be of little value. For this reason many 
 will be glad to get plans and specifications for 
 home-made tanks. Here is a plan for a tank made 
 of lumber. The material should not cost more 
 than $4 or $5. The directions are given for. a 
 tank of the following dimensions with the idea 
 that they may be varied to suit the convenience 
 of each particular case: 
 
 Length 8'; depth 4'; width (at bottom) 16"; 
 width (at top) 20" ; capacity about 360 gallons. 
 These dimensions may easily be varied to suit the 
 builder. A bottom width of 12" or 14" is wide 
 enough for ordinary purposes ; 6' is long enough 
 for the smaller animals, but we prefer an 8' 
 length, and 10' is desirable for the larger ani- 
 mals. 
 
 The side pieces are of 2"x4" material, 4', 4" 
 in length. Make ten of these and mortise them 
 into the sills (which are also of 2"x4" material, 
 24" long) in the manner shown in Fig. 314 which 
 is a view from below. Fig. 314 will give a good 
 idea of one of the U-shaped frames. Set these 
 five fram.es upon a smooth level surface, 2' apart 
 and secure by temporary support. Be sure that 
 
MISCELLANEOUS. 
 
 167 
 
 all axe upright aJid true, then begin laying the 
 sides. The sides and ends are of %" tongued 
 flooring. The sides are laid first. Plane the 
 tongue from one piece of flooring and place this 
 upon edge on the sills, planed edge down. There 
 should be a small projection beyond each end- 
 post. When the sides are finished these ends 
 are sawed off leaving a smooth planed surface 
 for the end boards to cover. Paint the tongue 
 and groove ofeach board as it is laid. 
 
 After laying a few boards on one side build 
 the other side to an equal height. The bottom 
 can now be laid much more conveniently than 
 if this is postponed until the sides are entirely 
 enclosed. For the bottom use two 8' planks. 
 Bevel one side of each to the angle of the sides, 
 put the planks in place and draw down with 
 bolts through the sills. The bolts used in the 
 middle sill should be about 2," longer than the 
 others for the purpose of attaching the ladder 
 which is described later. The crack between the 
 two bottom planks should be covered with a thin 
 strip of batting or other light material. Fig. 315 
 illustrates the appearance of the tank at this 
 stage, except that one side is entirely boarded 
 up. The sides are now finished and the pro- 
 jecting ends sawed off. Much depends on this 
 job. If done properly the end boards when 
 nailed securely will make a water-tight joint.' 
 Give the entire box a good coat of paint inside 
 and outside. 
 
 A cement tank is easily and cheaply con- 
 structed and is very durable. It has the disad- 
 
 -ao „ 
 
 J. 
 
 -*1 m 
 
 JTG. 314— DIPPING TASK CONSTRUCTION. 
 
 FIG. 315— DIPPING TANK CONSTRUCTION. 
 
168 
 
 FARM BUILDINGS. 
 
 vantage of not being portable but otherwise is a 
 very satisfactory tank. Select a rather high, 
 well-drained spot where the earth is firm. If 
 the selection can be such that a drain pipe can 
 be laid from the bottom of the tank to the sur- 
 face of the ground some distance away so much 
 the better. Dig a pit of the following dimen- 
 
 ITG. 316— DIPPING TANK CONSTRUCTION. 
 
 sions: Length (at top) 10'; length (at bot- 
 tom) 5'; width (at bottom) 23"; width (at top) 
 28" ; depth 4'. See Fig. 316. Smooth the sides 
 of this pit and at the bottom place a 2" layer of 
 cinders, gravel or other material and tamp until 
 firm. 
 
 Make a frame of rough lumber 4" shorter and 
 8" narrower than the pit. This frame will then 
 have the following dimensions: Length (at 
 top) 9', 8"; length (at bottom) 4', 8"; width (at 
 bottom) 15"; width (at top) 20"; depth 4'. 
 This frame has no floor at the bottom or on the 
 
 PIG. 317— DIPPING TANK CONSTRUCTION. 
 
 slant end. Place the frame in the pit as indi- 
 cated in Fig. 317. This frame is of use only in 
 constructing the side walls and the vertical end 
 wall. The bottom and slant end are laid after 
 the frame is removed. 
 
 Mix good Portland cement with coarse sand 
 and gravel at the rate of one part cement to 
 six parts sand. Such a tank will require from 350 
 to 400 pounds of cement and something like a 
 ton of gravel and sand mixed. Fill in the sides 
 and straight end with cement, tamping well as 
 the rilling is done. Allow plenty of time for the 
 cement to set. Two weeks is not too long; if 
 the ground is damp a longer time should be 
 given. The pit should be covered by means of a 
 tent or water-tight roof of some kind during this 
 period, in order that chance showers may not 
 interfere with the setting of the cement. 
 
 After the sides and one end are hard, remove 
 the frame and lay the bottom and slant end with 
 a trowel. In the angle "where the bottom of the 
 tank joins the slant end, two bolts should be em- 
 
 bedded in the cement. The ends should project 
 about two inches above the surface of the cement. 
 These are for the attachment of a ladder to 
 assist the animals in getting out of the tank. 
 Pound the joints where the sides join the bottom. 
 If this is done properly and carefully there will 
 be no danger of leakage. When the bottom is 
 set the tank is ready for use. 
 
 A CATTLE DIPPING VAT. 
 
 The plan of the cattle-dipping plant illus- 
 trated in Fig. 318, is one that has been used in 
 Nebraska by Eiehards & Comstoek since they 
 built their first dipping tank, about seven years 
 ago, since which time they have made some slight 
 alterations, but practically are using today the 
 same vats they did before. 
 
 The dipping plant is thus described by the 
 builders: At the entrance of the vat is a trap, 
 as shown in the illustration, swinging on a pivot, 
 and when a steer goes onto this trap it would tip 
 up and precipitate the animal into the vat. We 
 found that this was not satisfactory, so changed 
 this trap to a slight incline, covering the incline 
 with a piece of sheet steel 8' in length. This 
 incline would have a drop of 8" or 10" in 6' and 
 by wetting it before the cattle go onto it it 
 becomes very slippery and acts as a toboggan 
 slide, so that when they go out on this incline 
 they slide off into the vat, completely submerging 
 themselves, as the solution in the vat is about 
 six feet deep. 
 
 This vat is made from 2" yellow pine, the vat 
 itself being set in the ground about 6' or 8'. The 
 ribs to hold the sides, as well as the bottom, 
 are 4"x4s" placed about 4' apart and bolted both 
 at the topi and bottom so as to form a complete 
 band around the tank. 
 
 We have one vat in which about 200,000 head 
 of cattle have been dipped and the only part 
 requiring any repairs is the incline where the 
 cattle come out of the vat and the dripping pen 
 floor. 
 
 The planks are beveled on the edges and the 
 cracks packed with oakum, which makes a 
 tighter joint than if they were tongued and 
 grooved. The cost of one of these plants without 
 boiler will average from $175 to $250, according 
 to the material, labor and point at which it is 
 constructed. 
 
 We have a man stand on the top of the vat 
 with a pole arranged with an iron fork to go 
 over the neck so as to crowd the steer under a 
 second time, so that in swimming the length of 
 the vat the animal is completely submerged 
 twice. 
 
 Originally we used entirely cold preparations, 
 but from careful observation as well as thorough 
 tests we find that it should be used hot, so we 
 
MISCELLANEO VS. 
 
 169 
 
 have installed 12-horse-power boilers at all of our 
 plants to heat the solution to a temperature of 
 105°. This we do by placing the boiler as close 
 to the dipping vat as possible, then running a 
 steam pipe, generally 114" size, down into the 
 corner of the vat by the entrance, then along the 
 bottom of the tank at one edge, and perforat- 
 ing the pipe with y s " holes about 18" apart and 
 leaving the end of the steam pipe open, so that 
 the steam is forced out from the pipe all along. 
 We find that this keeps the temperature of the 
 dip the same throughout the entire length of 
 the vat. 
 
 There is no doubt that any dip that is really 
 effective will kill germs and parasites much 
 quicker if heated than when cold. Laboratory 
 tests that one chemist reported to us show that 
 the parasites were killed instantly in a solution 
 at a temperature of 105°, while at a temperature 
 of 32° after five minutes' immersion they still 
 showed signs' of life. When put in sperm culture 
 after having been immersed for five minutes in 
 a cold solution about 25 per cent or them still 
 retained life. This shows beyond any doubt that 
 the hot application is the proper one to use. 
 
 Many have erroneously believed that one dip- 
 ping of an animal afflicted with lice or itch would 
 
 be sufficient. This is not true. The egg which 
 is laid by the parasite does not hatch out for some 
 time, generally from seven to ten days, . and any 
 
 39 
 
 B. FALSE. BACK. 
 A.A. HORIZONTAL BRACES. 
 
 m 
 
 -> — 1 — n 
 
 H !— ! FM 
 
 H 1 — i H 
 
 LJ^ 
 
 ■-*. . /6 _ 
 
 J— ^p^bo*"^- ■ Bottom of Vat. 
 -# /S' 4 24-'- ■ 
 
 SIDE VIEW. 
 
 Scale: < = Jo' 
 
 1TG. 318 — A CATTLE DIPPING VAT. 
 
170 
 
 FARM BUILDINGS. 
 
 preparation that is strong enough to kill these 
 eggs would be very disastrous to the animal, 
 so they require a second dipping from eight to 
 eleven days after the first. This is effective with 
 any good preparation provided the animals 
 dipped have been kept in a pen, yard or pasture 
 where there has been no infection, as the dipping 
 of cattle is not a preventive, but simply a cure, 
 and after dipping if they go; to a post, shed or 
 windmill tower or any similar thing or even lie 
 down where the post or ground is infected they 
 are very liable to become infected again. 
 
 . Those who have been most successful in exter- 
 minating this trouble from their herds have 
 adopted a system of dipping every week or ten 
 days each animal that shows any indication of it 
 until it is completely eradicated from the herd. 
 
 After dipping seven years we are pleased to say 
 that we consider it an unqualified success, which 
 every herdsman will have to adopt. 
 
 We dip all our cattle once a year to insure their 
 being free from trouble. No new purchases are 
 allowed to go onto our ranch until after they 
 have been dipped. 
 
 A DIPPING VAT FOR SHEEP. 
 
 The strongest argument for the dipping of 
 sheep lies in the fact that it is the best way of 
 freeing them from external parasites. Sheep are 
 very frequently troubled with red lice, which 
 can hardly be seen, and yet they cause the sheep 
 unlimited annoyance. Dipping will completely 
 destroy them. Ticks cause the farm flocks of 
 this country untold annoyance and for these dip- 
 ping is thoroughly effective. Ticks and red lice 
 do more damage than sheepmen are aware of, 
 because the evidences of the annoyance which 
 they give the sheep are not so marked as in 
 some other troubles, but they are none the less 
 a severe cheek to their well-doing. Dipping fol- 
 lowed faithfully each year will completely re- 
 move the baneful results from the presence of 
 these parasites. For the eradication of scab dip- 
 ping stands first among remedial measures. 
 
 While the destruction of these pests is usually 
 the mainly-accepted argument for dipping, yet 
 there are others that, grouped together, make a 
 more favorable endorsement for the operation. 
 Among these may be briefly mentioned cleansing 
 the skin, cleaning the wool and particularly en- 
 couraging the growth of the latter. To get the 
 fullest returns in these directions the dipping 
 should be done twice each year — in the spring 
 shortly after shearing and again in the fall, just 
 before the advent of winter. 
 
 Shortly after shearing it is an advantage to 
 dip the flock thoroughly so as to cleanse the 
 skin. This not only adds to the thrift of the 
 sheep and the lambs, but in both instances it 
 
 favors the secretion of yolk and this means the 
 growth of a sound, live, uncotted fleece. Not 
 only is the growth of wool better from it, but it 
 adds directly to the function of the fleece as a 
 protection to the sheep. The fleece of a sheep 
 that has been dipped is more likely to remain 
 intact throughout the season, as there is no 
 cause for the sheep rubbing or otherwise break- 
 ing the compactness of it. Another advantage 
 that seems to follow dipping at this time is that 
 it seems to lessen the tendency of the sheep to 
 lose its wool in spots too early in the season. 
 When the fleece is clean and healthy it seems to 
 continue growing longer and the wool does not 
 peel in patches. Dipping in the fall is more for 
 the purpose of removing from the fleece such for- 
 eign matter as may have been gathered during 
 the summer and also freeing it from any of the 
 parasites that prove such an annoyance during 
 the winter season. Even under the best condi- 
 tions the fleece is likely to become filled more 
 or less with sand and other foreign matter which, 
 during the winter, would produce such irrita- 
 tion as to cause the sheep to rub against sharp 
 surfaces and destroy the compactness of the 
 fleece. 
 
 By dipping sheep late in the fall, when the 
 ground is frozen and then keeping them away 
 from the straw stacks and feeding them in racks 
 that prevent the chaff from falling into the wool, 
 it is possible to put a clip on the spring market 
 just as clean as if the sheep had been washed 
 just previous to being shorn. 
 
 It is hard to measure the damage that is done 
 to the fleece alone, to say nothing of the thrift of 
 the sheep, by overlooking dipping in the fall. 
 It is quite common to see sheep in the ordinary 
 flocks of the country with fleeces badly broken by 
 rubbing under wagons or some such means, 
 through their endeavors to get rid of the irrita- 
 tion of the dirt that was left in the fleece. Such 
 fleeces are likely to become cotted, especially if 
 the sheep have not been dipped in the spring. 
 Neglect of spring dipping is apt to result in a 
 decreased secretion of yolk, a condition which 
 favors cotting. A fiber of wool is covered with 
 scales that overlap each other similarly to the 
 shingles on a roof. To' keep these scales down 
 and to prevent them from warping just as shin- 
 gles would do there must be a liberal supply of 
 yolk in the fleece. If this yolk is not secreted, 
 owing to the unthrifty condition of the skin, 
 the scales rise and the fibers become so matted 
 that they finally reach what is known as a cotted 
 condition. Fleeces of this kind sell for 3 or -1 
 cents per pound less than they otherwise would 
 on the general market. 
 
 The fleece of a sheep that has not been dipped, 
 also one that is dirty or discolored, sells for 
 
MISCELLANEOUS. 
 
 171 
 
 ". or 4 cents per pound less in title Chicago mar- 
 ket tihan the fleece of a sheep that has been 
 cleaned by dipping. These are facts that may 
 be verified every spring. It is said that the ben- 
 efits of dipping applied to a single fleece would 
 pay for the dipping of more than a dozen sheep. 
 
 While the foregoing applies especially to breed- 
 ing flocks, there are just as forcible reasons for 
 dipping feeders. ■ In feeding sheep it is of prime 
 importance to reach as rapidly as possible that 
 sappy and thrifty condition which is conducive 
 to good gains. Dipping will hasten this and 
 also remove the risk of unlimited losses through 
 an outbreak of scab. It is good policy to take 
 it for granted that the feeders are in need of 
 dipping rather than wait for the evidence of it 
 which usually comes when the sheep should go 
 to market. 
 
 Dipping being so necessary it follows that it 
 will pay to arrange for a dipping vat especially 
 for this purpose. The cost of this is sometimes 
 used as an argument against it, but this may 
 be easily overcome by a number of farmers in a 
 community combining and building a dipping 
 vat for the use of all. It would be easy to drive 
 the sheep to this plant and the ease with which 
 they may be dipped would result in a consid- 
 erable saving of labor. 
 
 The dipping vat (Fig. 319), which is here- 
 with described, cost about $50 and could be 
 
 
 La roe Yard 
 
 
 
 
 
 
 
 
 
 
 GaTchinq / 
 PfeoV 
 
 
 
 Gfilfi/ 
 
 
 
 
 
 art \ 
 
 
 
 Gatchinq \ 
 Pen \ 
 
 
 
 
 
 
 
 
 
 
 Draining 
 
 a 
 
 
 
 a"swiipin 
 
 
 a* in 
 
 41 
 
 O 
 
 
 
 
 PIG. 319— DIPPING VAT POR SHEEP. 
 
 built much more cheaply with some study as 
 to the more economical use of material. There 
 is one feature about this vat which is not wholly 
 satisfactory and that is due to the fact that 
 the planks used in making the vat are not as 
 
 durable as they should be. Iron tanks which 
 are manufactured would be much more satis- 
 factory on that account. An ordinary wooden 
 vat well painted will last several years, but in 
 making a vat of this kind it would be better to 
 put a little extra money in it so as to make it 
 more durable. 
 
 The ground plan (Fig. 319), readily explains 
 the general arrangement. The only point to 
 which attention may be called in the construc- 
 tion of the yards is that there are no corners 
 for the sheep to be crowded in, consequently 
 they move along as freely as required. EJach 
 catching pen is exactly the same size as each 
 of the draining pens, consequently they hold the 
 same number of sheep. By taking these dimen- 
 sions it is easy to run the sheep into the vat 
 in groups just sufficient to fill each of the drain- 
 ing pens desired. The gates between the catch- 
 ing pens are sliding so that the sheep may read- 
 ily pass through one from the other. The sec- 
 ond catching pen, or the one nearest the dipping 
 pen, is floored, as this tends to keep the feet of 
 the sheep clean just before they enter the dip. 
 The dipping vat is 12' long, 4|' deep, 20" wide 
 at the top end and 6" wide at the bottom. 
 
 The vat holds about 125 pails of water with 
 the dip required to give the fluid the needed 
 strength. It is sufficient to dip about 125 sheep. 
 This is allowing more fluid than is generally 
 stated to be sufficient, but it is better to use 
 this amount and thereby clean the fleeces thor- 
 oughly. This amount may be used in dipping 
 sheep that have their fleeces about half grown. 
 If the dipping is done shortly after shearing 
 much less dip will be required. 
 
 For the comfort of the sheep it is advisable 
 to choose a day that is not too warm, and care 
 should be observed also in driving the sheep and 
 penning them in that they do not become over- 
 heated. In passing them through the dip haste 
 should be avoided. They should be allowed, to 
 remain as long as possible in the draining-pens. 
 This is better for the sheep, saves dip and les- 
 sens the danger of poisoning afterwards. There 
 have been cases where the sheep have died 
 through eating grass on which they have 
 been allowed to run before they had become thor- 
 oughly dry. Then if the sheep are turned out 
 too hurriedly from the draining-pens and the 
 sun is very warm it will dry out the fleece and 
 add to its harshness. 
 
 This dipping vat is best for a flock of about 
 200 sheep. For a large number it would be 
 preferable to make the vat longer so that more 
 dip could be put in and more sheep run through. 
 It is easy, however, to dip as many as 500 sheep 
 with this vat, but more thorough dipping can be 
 given by having the vat considerably longer. In 
 
172 
 
 FABM BUILDINGS. 
 
 that case the yards and draining-pens should 
 be enlarged so that the 'sheep could be run 
 through in larger groups. It would seem that 
 for dipping sheep on an extensive scale it would 
 be an advantage to have the vat double, so that 
 the sheep turns when it gets to the end and 
 swims back and goes out near the point where 
 it started. This long swim cleanses the fleece 
 thoroughly. 
 
 For a farm flock a small dipping plant of 
 this kind is admirably adapted, but it would be 
 a more economical arrangement for several to 
 combine and make a plant for this purpose. 
 
 THE WATEE SUPPLY ON THE FARM. 
 
 Proximity of a source of pure water to the 
 barn or stable is of more importance than might 
 at first thought appear. To have a spring or 
 running stream located a quarter, of a mile from 
 the barns often means a great deal of extra labor 
 on the part of the work stock in traveling that 
 distance every day for their water. Put the 
 water even one-eighth of a mile from the barn 
 and say the horses are watered there. Three trips 
 a day with work horses mean three-quarters of 
 a mile of travel, and generally not over the 
 smoothest road. This amounts to some 270 miles 
 each year and a farmer may live sixty years on 
 his farm. Put it low and say that he travels but 
 15,000 miles in watering his horses during his 
 lifetime. Is this not an important item in farm 
 economies ? 
 
 Small streams for watering live stock are 
 usually of more detriment than value in that they 
 are the distributors of many diseases. Swine- 
 breeders know to their sorrow the cost of water- 
 ing at running streams where contagion is so 
 easily carried with the current. 
 
 A spring high enough above the farm so that 
 water from it may be carried in iron pipes to the 
 yards and buildings is of incalculable value on 
 a stock farm. Next to this comes the well and 
 wind-pump. Dug wells are sink-holes of iniquity, 
 summer resorts for mice, toads, worms and 
 insects, breeding places for disease germs. The 
 drainage of the yards, distant privy vaults and 
 sink-drains is often to these wells. The driven 
 well, put down where there are tight veins of 
 clay to keep out surface water, is generally safe. 
 Nothing can get in it from above. Seepage of 
 surface impurities is almost impossible. The 
 driven well can be put any place where it is 
 desired, within the stable, at the kitchen door, 
 in the barn-yard or wherever it is most con- 
 venient. 
 
 Where the subsoil is of sand or gravel or is not 
 water-tight the driven well will of course afford 
 no security against water pollution. It will, how- 
 ever, in any case be free from danger of invasion 
 
 by rats, mice or insects. A good driven well at 
 the house will repay its cost many times over. 
 
 Best of all is the well which is sunk clear into 
 the hard rook. Then if the steel tubing is sunk 
 properly there can be no fear of contamina- 
 tion. 
 
 WATEE SUPPLY FOE FARM BUILDINGS. 
 
 A farm water supply system is thus described 
 by one who is using it: An ordinary windmill 
 
 v/f orces the water into an underground tank, from 
 which it is conducted by pipes where wanted. 
 The water being forced through a check-valve 
 from the pump into the tank fills the bottom of 
 the tank and thus compresses the air in the top 
 of the tank. The pressure thus obtained is suffi- 
 cient to force the water into any part of the barn 
 or house. A water-pressure gauge is attached to 
 the pipes just over the kitchen sink and shows at 
 a glance and at all times the exact amount of 
 pressure,, obviating any liability to excessive 
 pressure and danger of breaking pipes. The 
 pump is usually shut off at forty pounds, when a 
 hose can be attached and the water thrown over 
 the house or barn. The tank may be located in 
 the cellar. It may be an iron tank 3%' in diam- 
 eter and 12' long, and located underground near 
 the well. Its capacity is 30 barrels, but it is 
 never full, as the air occupies some of the space 
 in the tank. A 50-barrel tank for a stock or 
 dairy farm would be advisable. 
 
 The system is very simple, easily constructed 
 and anybody can manage it successfully. It puts 
 the enterprising farmer on a par with the dwellers 
 of cities as regards a water supply and it is not 
 expensive. Including a well 100' deep, a wind- 
 
 \l mill and force pump, tank, 1,000' of supply pipe, 
 400' of sewer pipe, hydrants, sinks and bath-room 
 fixtures this water system cost $600. It can gen- 
 erally be installed at much less cost than the esti- 
 mate given. Very often a second-hand boiler 
 good enough to hold water can be obtained at low 
 cost. Any iron tank strong enough to sustain a 
 pressure of about 40 pounds will serve. There is 
 no danger of the water freezing, no luke-warm 
 water in summer and there is a lively pressure at 
 any point where it is led in pipes. 
 
 There is a simple system operating on the same 
 plan applicable to houses. It consists of two or 
 three of the cylindrical galvanized boilers, of 
 about 40 gallons capacity, one of which is 
 heated from the range. A force pump in the 
 kitchen sink forces water into the bottom of the 
 other two tanks and the air is compressed in the 
 upper ends. This keeps the hot' water reservoir 
 always filled and gives pressure to force either 
 cold or hot water to any part of the house. A 
 small steam gauge registers the amount of pres- 
 sure, which is usually about 20 pounds. 
 
MISCELLANEOUS. 
 
 173 
 
 This system is so simple and cheap that any 
 farmer can afford it and the satisfaction it gives 
 is beyond calculation. Any plumber can put it 
 in and it should not cost, piping and all, more 
 than $40. 
 
 EARTH WATER TANK. 
 
 The plan illustrated in Fig. 320 shows a sec- 
 tion of a dirt tank. The dimensions are given, 
 but the size can be suited to requirements. A 
 100,000-gallon dirt tank costs very little more 
 
 himself with but little help. The plan explains 
 itself fully, the principle being that the bacteria 
 which are generated by putrefaction multiply 
 very quickly in the first septic tank, devouring 
 bhe solid matter until almost eliminated. What 
 passes into the second septic tank undergoes the 
 same process, but to a less amount, owing to its 
 being purer. The liquid now flows into the 
 primary filter, being a trench 15' long and 3' 
 to 4' deep. At its bottom is a layer of broken 
 stone, surmounted by a layer of gravel, which is 
 
 DIRT WALLS ABOUT 9FEET HEIGH ABOUT 30 FEET WIDE AT BOTTOM 
 
 .TAKEN OUT. -WiffMjgi -. 
 
 \WITH PLOW/FOUNDATION LOOSENED WITH 
 NDSCRAPCR/ APLOW TO BUILD SOILON 
 
 X PIPE LAID IN BEFORE 
 
 BUILDING 
 
 FIG. 320— EARTH WATER TANK. 
 
 than a 10,000-gallon cypress cistern. Hundreds 
 of these dirt tanks have been made, and are 
 being made in Western and Southwestern Texas. 
 
 A HINT ON CISTERN MAKING. 
 
 Many cisterns are faulty in construction in two 
 important details: they are too shallow; the 
 water gets warm quickly and soon fails. They 
 are too flat on the bottom. The bottom of the 
 cistern should be like the bottom of a funnel, 
 V-shaped, and in the lowest apex should be the 
 pipe connecting to the pump. Whatever sedi- 
 ment, leaves or trash gets into the cistern will 
 at once be pumped out before it will have time 
 to taint the water. 
 
 PAEM DRAINAGE SYSTEM. 
 
 The drainage system shown in Pig. 321 is cheap 
 and effective and can be put in by the farmer 
 
 underdrained by an Akron pipe, leading the 
 filtered water into a siphon set a foot below the 
 bed and made of the same piping. The secon- 
 dary filter, reached through the siphon, consists 
 of an air chamber of cobblestones, above which 
 rests three feet of double-screened gravel and 
 sand. An 8' pipe runs from the surface of the 
 ground into' this air chamber and by means of a 
 force pump the purified water is raised. 
 
 The septic tanks must be water-tight and 
 sealed practically air-tight on top by an iron 
 manhole. The bacteria thrive without oxygen, 
 and sewer gas will not generate unless a certain 
 amount of air space is provided. One cubic 
 yard of filtering space is sufficient for one per- 
 son. In this plan 50' of filter space has been 
 provided with 15 cubic yards of filtering material 
 in this instance, because 15 is the average num- 
 ber of persons supposed to occupy the farm and 
 
 |"*.htt«.Ta»k £W&>t£jTinfc 
 
 ^ej><rm *~S Sure. yVcCTet- . 
 
 >IG. 321— FARM DRAINAGE SYSTEM. 
 
174 
 
 FABM BUILDINGS. 
 
 using it. This system is becoming popular both 
 for private and public places. 
 
 WATER CLOSETS. 
 
 There is no reason why sanitary conditions on 
 the farm should be so objectionable as they are 
 often found. Disease on farms is often traceable 
 to contamination of water by filthy cess-pools. 
 In these days of windmills and force pumps there 
 seems to be no reason why country people should 
 be without the advantages of water in any part 
 of the house desired. 
 
 Perhaps no one thing adds more to the charm 
 and healthfulness of a dwelling than a bath-tub. 
 There is nothing that can be added to the home 
 that will give more pleasure to all the family 
 than the bath-tub and a plentiful supply of water 
 always at hand, hot or cold. A bath-room may be 
 fitted up with porcelain-lined tub, water closet 
 and all for about $100. 
 
 The water closet if properly constructed and 
 the drainage from it carried off a sufficient dis- 
 tance is the most sanitary of all systems. One 
 should avoid the use of an underground cess- 
 pool near the house to receive drainage from the 
 bath-room. It should be carried to a distance, 
 the farther the better. 
 
 The well that supplies the drinking water 
 should be a driven well and should, if possible, 
 penetrate the earth deep enough to put several 
 feet of impervious clay between the water supply 
 ' and surface drainage. Such a well may cost a 
 trifle more at the start but it is by many con- 
 sidered cheaper in the long run. 
 
 Privies with vaults or cess-pools below are 
 universally condemned. Beneath the privy put 
 an impervious lining of cement, so that under no 
 circumstances can any drainage from it pollute 
 the soil below. Make a dust-bin in the privy, 
 lining it with sheet-iron, so that if necessary in 
 winter dry ashes may be used instead of dust. 
 Beneath the seats there may be placed large gal- 
 vanized iron buckets, or if preferred square 
 buckets of the same material. These buckets are 
 easily emptied and it should be attended to as 
 regularly as any other farm-work. 
 
 WATER IN THE COW STABLE. 
 Where it is desired to water cows in their stalls 
 there is perhaps nothing so satisfactory as the 
 
 A 
 
 I — I C/osed. Open 
 
 BTG. 322 — WATER IN THE COW STABLE. 
 
 simple trough that is covered by a hinged cover, 
 which when closed helps make the front of the 
 manger. This trough should be made of con- 
 
 crete, if the floor and manger are of concrete. 
 The trough may be 8" wide, 6" deep and with a 
 slight incline at the bottom, level at top and a 
 plug at the lower end that will drain it each time 
 it is used. One user of this system has a 1^4" 
 pipe in the bottom of his trough with a *4" hole 
 opposite each cow, so that the water does not flow 
 appreciably from one cow to another. ( See Pig. 
 322.) 
 
 FORMULA FOR WHITEWASH. 
 
 Take a half bushel of unslacked lime, slack it 
 with boiling water, cover during the process to 
 keep in steam, strain the liquid through a fine 
 sieve or strainer, and add to it a peck of salt, 
 previously dissolved in warm water; three pounds 
 of ground rice boiled to a thin paste and stirred 
 in while hot; half a pound Spanish whiting and 
 one pound of glue, previously dissolved by soak- 
 ing in cold water, and then hanging over the 
 fire in ,a small pot hung in a larger one filled 
 with water, add five gallons of hot water to the 
 mixture, stir well and let it stand a few days 
 covered from dirt, It should be applied hot, for 
 which purpose it can be kept in a portable fur- 
 nace. Whitewash makes things look neat and 
 clean and is especially adapted to the inside of 
 stables and sheds. For outside work a little tint 
 added to it makes it better. Pretty tints of yel- 
 low are made by the use of yellow ochre. It is 
 necessary to use considerable of the ochre. It 
 is much lighter after it is dry than it appears 
 when first put on. Where outside plastering is 
 done this limewash with ochre in it is admirable. 
 The addition of ochre to the wash seems to add to 
 its permanence and to make it less liable to rub 
 off. The essential thing in making limewash 
 ■seems to be to have good fresh lime, slake it in 
 boiling water, add some corn starch or flour paste 
 or paste made from boiled rice, which is supposed 
 to make it stick, and some glue. 
 
 EOOFS AND ROOFING. 
 
 For roofs of farm buildings slate and good 
 shingles are popular. Steel roofing unless kept 
 well painted is of very short usefulness. Paint- 
 ing makes it costly. It is hot in summer, drips in 
 cool weather and is sometimes noisy. It is, to 
 be sure, proof against sparks. Slate in the long 
 run is perhaps the cheapest of all roofs if well 
 laid. Shingles come next. Make the roofs with 
 an angle of 45 degrees. Lay them with either 
 galvanized nails or the old-fashioned cut nails. 
 Do not be deceived with the small wire nails 
 which rust off in a few years. A shingle roof 
 will last a long time if the shingles are boiled in 
 linseed oil. Put in a little color if you like. A 
 warm red makes a roof look well. Do not paint 
 the butts of shingles under the impression that 
 
MIBCELLA NEO US. 
 
 175 
 
 it will make them more durable. This will really 
 hasten decay. 
 
 WING'S COW STALL. 
 
 Joseph E. Wing describes this stall thus : There 
 are three essentials to a perfect stall : that it be 
 'comfortable for the cow, that it keep her clean, 
 and that it be convenient for the man who cares 
 for the cow. The stall I describe (see Pig. 323) 
 
 PIG. 333— WING'S COW STALL. 
 
 is nearly perfect in all these particulars. I 
 am indebted to Geo. E. Scott of Ohio for my first 
 knowledge of this stall, but I have since changed 
 it slightly from his model. 
 
 The cement floor is admirable. Let it extend 
 forward far enough to form the bottom of the 
 feed box at A (Fig. 324). Imbedded in it step 
 the foot of the post C, and place the 2"x4" on 
 which rest the ends of the front posts at A. Let 
 the manure trench be 16" wide and 8" or 10" 
 deep. This depth permits the, use of plenty of 
 absorbents and also prevents the cows from step- 
 ping into the ditch either when standing in 
 
 PIG. 384— WING'S COW STALL SHOWING CEMENT TLOOB. 
 
 their stalls or when passing out and in. The 
 distance back of the ditch may be 3' or more, ac- 
 cording to space at hand. From B to trench let 
 there be a slope of not more than 4". From the 
 edge of the trench to the front of the stall at 
 A the distance should be from 6' to 6' 8", accord- 
 ing to the size of the cows to be stabled. The 
 partitions between the cows are 5' high and 3' 6" 
 
 long and in the drawing are shown cut away to 
 give sight of the %" iron rod R, on which slides 
 the chain that confines the cow. This rod is 
 best placed midway between the partitions, as 
 then the cow can lick herself on either side. 
 
 The ends of the 1 " x 3 " laths that form the front 
 of the manger are shown. They should be spaced 
 about 4" apart. The cow draws her hay through 
 these spaces. The board B is about 1' high and 
 hollowed slightly in the center where the cow's 
 neck comes when she lies down. The one-quarter 
 round keeps it solid and makes it easier for her 
 to clean the meal out of her box. The partitions 
 go clear across the manger and feed-boxes. The 
 sloping side of the manger D is tight, so that 
 meal may be poured thereon and allowed to run 
 down into the feed-box below. Hay is put in at 
 E. The space E is not partitioned off but is con- 
 tinuous along the entire front of the cows. A box 
 for bran may easily be made below the sloping 
 board D. 
 
 The advantage of this stall is that as the cow 
 cannot push ahead, being restrained by the slats 
 in front of her, she is compelled to drop her 
 manure in the gutter. She will not step in this, 
 as it would be uncomfortable for her to do so and 
 the real and practical working of the thing is 
 perfection. We have fitted a small stable with 
 these stalls and the cows have never soiled them- 
 selves in it since it was made. 
 
 Place the partitions from 3' 6" apart to 4', ac- 
 cording to the size of the cows to be stabled. The 
 partitions being high and tight prevent cows an- 
 noying each other, and being short give room to 
 the milker and groom and also cause the cows to 
 present a handsome appearance when viewed from 
 the side or rear. The rod R is bolted at each 
 end, but if a safe fire-escape is wanted it should 
 be arranged as shown in Fig. 323. Here the rod 
 slips through the eyes of the eye bolts A and B 
 and is held suspended by the small chain C. This 
 is riveted to the iy 2 " gas pipe D, which has a 
 short piece turned down to make a crank at one 
 end, as E. This pipe extends along the entire row 
 of cattle and turns easily in its supports. When 
 there is danger or the cows are to be loosened a 
 few turns of the crank winds all the chains and 
 raises the rods out of their places, when the 
 cow chains slip off and the cows are free. It 
 may pay to fit a stable with this simple device 
 with a view of freeing cows at any time when 
 they are to be watered or turned out. Of course 
 the chains would be unwound before the cows are 
 put back in their stalls. This device is, so far 
 as I know, original with me. 
 
 THE VAN NORMAN COW STALL. 
 
 The ideal cow stall should have among other 
 requisites the following : a fastener that will hold 
 
176 
 
 FARM BUILDINGS. 
 
 the animal securely, be easy to fasten when secur- 
 ing the animal and to unfasten when turning it 
 out. The fastener should be so arranged that 
 there is no danger of the animal getting the feet 
 caught in it, and should give the maximum of lib- 
 erty commensurate with cleanliness. The stall 
 should be so constructed as to keep the animal 
 clean and absolutely to prevent one animal from 
 injuring another by stepping on the udder or by 
 hooking and from frightening another by being 
 able almost to reach it. The manger should hold 
 the necessary feed and roughage, keeping it with- 
 in reach of the animal, preventing it being gotten 
 
 moval. The stall may be constructed of 2" lum- 
 ber, dressed on two sides, or if to be whitewashed 
 iy 2 " stuff, rough, will hold the whitewash better 
 than if smooth. These are standard sizes of lum- 
 ber, but iy 2 " dressed and 1%" rough are strong 
 enough. For dairy cows of average size stalls 
 3' 6" from center to center and 5' from gutter to 
 manger will be about right. The animal should 
 have just room to stand comfortably with hind 
 feet an inch from the gutter and front feet just 
 back of A in Fig. 3. A desirable arrangement 
 is to place the timber A 5' from the gutter at one 
 end of the barn and enough closer at the other 
 
 MMseMciir crTmnsursvsaasnKimEAaimiCR 
 
 r/G2 
 
 Murimsau vw/e/i 
 
 Fife. 6. 
 
 K. 
 
 Vig.1 
 
 under foot and should be easily cleaned of all 
 refuse matter. Often the owner of a herd' of 
 cattle desires a stall that will expose to the visi- 
 tor's view as much of each animal as possible 
 without lessening the security to his animals. A 
 stall should be inexpensive and strong. These 
 conditions are met fully in the cow stall designed 
 by Prof. H. E. Van Norman of the Indiana Ex- 
 periment Station. 
 
 Fig. 2 represents the arrangement for two rows 
 of stalls facing each other with the feeding alley 
 raised to the top of the manger, allowing feed and 
 hay to be swept into the manger and refuse to be 
 swept out of the manger into the alley for re- 
 
 W- 
 
 Fig i. 
 
 end to fit the smallest animal, thus giving the 
 stalls varied lengths. 
 
 To build the stall place the 2" x 6" A (Fig. 3) 
 ' in position 5' or less from the gutter, then the 
 raised feeding floor should be built with the joist 
 S 2~y 2 ' in the clear from A ; then cut the plank B 
 and fasten in place, and successively planks C, 
 D and E, holding them temporarily with a cleat 
 until F and G are secured. To cut F and G, 
 lay two pieces of plank on the floor, and on the 
 one G (Fig. 6) lay off the distance 1 to 2 along 
 the edge equal to the distance from the top of 
 partition 2 (Fig. 4) to middle of manger on top 
 of A at 1, Fig. 4; then mark off 2-3 and 3-1, 
 
MISCELLANEOUS. 
 
 177 
 
 making the corner at 3 exactly square. It will 
 make little difference if planks 6 and P, Pig. 4, 
 do not touch at 1. When properly fitted toe nail 
 G to A at 1, and nail B, C, D and E to F and G; 
 then toe nail H and I in place. The partition 
 between the stalls is now held securely in place 
 and the operation may be repeated for as many 
 stalls as wanted. 
 
 It is well to leave the planks B, C, D, E a little 
 long, or even square and. when in position draw 
 lines from 4 to 5 and' 4 to 6, Fig. 3, and saw off 
 along these lines. The ends of the planks B, C, 
 D and B should be covered with a partition cap 
 0, Pig. 3, which holds them in place and gives 
 a finished appearance to the stalls. In the ab- 
 sence of the capping 0, strips as shown at P, Fig. 
 3, may be used. The bar J, Fig. 4, should be 1" 
 shorter than the distance between partitions and 
 made of 1" x 3" light strong wood, round corners 
 and slides behind iron staples. K, Figs. 4 and 7, 
 are made of %" round iron, with nuts on the 
 end or with a hole and key. These staples K 
 should be placed 9" from the partition and lower 
 end near the floor. In the middle of J place a 
 clevis of 1" x y 8 " strap iron, in which to fasten a 
 common chain tie. Bore a hole for clevis bolt 
 just above the middle of bar. This bar should 
 hang far enough from the neck to allow the cow 
 to stand comfortably with the head in a natural 
 
 position. Where conditions make the feeding 
 alley impracticable the front of the manger may 
 be arranged on the plan of the dotted lines in 
 Fig. 3. If desired a 2" x 2" piece may be run 
 along on top of the stalls at 2, Fig. 4, though it 
 is not recommended. It has been suggested that 
 
 J\ ixi" i^.\Kjof Ircva 
 
 Fig. 5 
 
 instead of the gutter a drop be arranged, as 
 shown in Fig. 5. T and U are made of a 2" x 6", 
 split diagonally. 
 
 Commenting on the Van Norman stall Joseph 
 E. Wing says : "It is the simplest, cheapest and 
 in some ways the most hygienic stall of them all. 
 It gives an uninterrupted view of the cattle. It 
 does not waste the feed. The objection to it is 
 that cows that are wild are not so readily secured 
 as with some other stalls and there is some noise 
 when cattle are feeding, owing to their being 
 fastened to a sliding bar in front. It keeps them 
 clean and they are comfortable." 
 
 APPENDIX. 
 
 Since the foregoing pages were put to press 
 some additional views of barns and other farm 
 buildings have come to hand. While we are 
 without details as to dimensions and construc- 
 tion in these cases we nevertheless have deemed 
 
 them of sufficient general interest to be incor- 
 porated in a supplementary way in this volume. 
 Possibly some hints of value may be gleaned^ 
 from these illustrations, most of which are from 
 recent photographs. 
 
 THB YARD AND MAIN BUILDINGS ON THE tfABM OIP W. B. COFMAN, JVAIBFIELD CO., OHIO. 
 
178 
 
 FARM BUILDINGS, 
 
 ■ ■■ -.^ u ■■■ 
 
 A PICTURESQUE WELL SHELTERED FARM IN WESTERN MAINE. 
 
 A UTAH SHEEP SHED. SEE DESCRIPTION. PAGE 102. 
 
 A MODEL KENTUCKY MULE 
 
APPENDIX. 
 
 ■ 179 
 
 NEW BARN AT THE COLORADO AGRICULTURAL COLLEGE, FORT COLLINS. 
 
180 
 
 FARM BUILDINGS. 
 
 AN IOWA DAIRY BARN SHOWING SILO— W. B. BABNEY & CO., FRANKLIN 00. 
 
 Co 
 
 DOOR 8 r - T WIDE 
 \ 
 
 a. 5 
 
 5o 
 
 < CM 
 O X 
 
 JL4|t\L§_ _ ml U _l__LL__ 
 § rafflv aisle 
 
 GRINDER 8 FEED ROOM OVER THIS PAW 
 20x32x|8 
 
 MANGER 
 
 DOOR SLIDING DOOR B'-' 
 
 
 
 be; 
 
 
 
 CD 
 
 
 
 E 
 
 
 
 s: 
 
 
 
 o 
 
 
 
 
 
 
 z 
 
 
 
 
 
 iaduj 
 
 
 
 
 
 3 . ■ ' 
 
 4? 
 
 £ # 
 
 _1 
 
 :■■ 
 
 
 
 
 
 S 
 
 
 
 m 
 
 .PULLEY 
 
 t?AKUNtEN(f CALFSTANTIONS 
 
 en 
 
 PLAN AND END ELEVATION Off IOWA DAIRY BARN— W. B. BARNEY & CO., FRANKLIN CO. 
 
APPENDIX. 
 
 181 
 
 STABLES FOR STOCK ON PENNSYLVANIA FARM OF SENATOR P. C. KNOX. 
 
 PRIVATE STABLES AT THE COUNTRY PLACE OP SENATOR P. C. KNOX OF PENNSYLVANIA. 
 
182 
 
 FARM BUILDINGS. 
 
 ARRANGEMENT OF BARNS AND SILO IN THE YARDS OF SMITH & M'GREGOR, WASHINGTON CO., MINN. 
 
 A MINNESOTA SELF-FEEDER TOR HOGS. 
 
 42 
 
 FEED ALLEY 6X42' 
 
 FEED ROOM. 
 lVXI3' 
 
 MANURE tRE N Ch nr 
 
 STA .LS 
 
 3 6 
 
 RASSAGE 5 
 
 FLOOR PLAN OF DAIRY DARN FOR 20 COWS. 
 
 TWO LARGE BARNS ON FARM OF J. B. BTJRRIS, PUTNAM CO., IND. 
 
APPENDIX. 
 
 183 
 
 GROUP OP FARM BUILDINGS ON THE GROUNDS OF THE TENNESSEE EXPERIMENT STATION AT KNOXVTLLE. 
 
 C- CHUTE WITH DODGE GATE 
 D— DIPPING TANK 
 P- SMALL PEN FOR STARTING 
 CATTLE THROUGH CHUTE 
 
 ARRANGEMENT OF CORRALS FOR A RANCH. 
 
 * ;iW* -A . "■"" — ~A -A. — ""™= — -« . — 
 
 
 4* » *• 
 
 6* 
 
 **• 
 
 
 un*» 
 
 I— lllll'lll'lflllii^l 
 
 A SOUTHERN EXPERIMENT STATION BARN. 
 
184 
 
 FABM BUILDINGST 
 
 j'SRu^i. 
 
 To Tow/* 
 
 
 O 
 
 
 '^fjfDOft^ CSC* 
 
 fclm^i iiiiiiiiii-iiii 
 
 SUGGESTED ARRANGEMENT OF FARM HOUSTC, BUILDINGS AND GROUNDS FOR A NORTH FRONT. SCALE 1 IN. TO 90 FEET. 
 
 (SEE PAGE 11.) 
 
 
 m 
 
 BARN AND YARD AT THE MINNESOTA EXPERIMENT STATION, ST. ANTHONY PARK. 
 
APPENDIX. 
 
 185 
 
 DAIRY BARN AT TENNESSEE EXPERIMENT STATION. 
 
 -<?)-^<?^-f?3— e<^- 
 
 SUGGESTED ARRANGEMENT OF FARM HOUSE, BUILDINGS AND GROUNDS FOR A SOUTH FRONT. SCALE 1 IN. TO 90 FT. 
 
 (SEE PAGE 11.) 
 
PRINTED BY R. R. DONNELLEY 
 AND SONS COMPANY AT THE 
 LAKESIDE PRESS, CHICAGO, ILL