j|j|j |j|f>jt B i li iiii wnii ai # « i« »i ii ^i w>i«)i i i > l iil nii !> itri^j ) •n'ri'i-oiiiinwinwii'iimii'ii'm'ittiiij mW. WW-'''- i : H flfff ; ;,; I ; ;i i ■■1 i I'm ss n^sa. 5*/ ■ tl li' rM iii ii> Mm.^ CQEMRIGHT DEPOSIT. / THE BOOK OF ICE-CREAM Edited by L. H. BAILEY Carleton: The Small Grains. B. M. Duggar: The Physiology of Plant Production. J. F. Duggar: Southern Field Crops. Fisk: The Book op Ice-Cream. Gay: Breeds of Live-stock. Gay: Principles and Practice of Judging Live-Stock. Goff: Principles of Plant Culture. Guthrie: The Book of Butter. Harper: Animal Husbandry for Schools. Harris and Stev.art: The Principles of Agronomy. Hitchcock: Text-book of Grasses. Jeffery: Text-Book of Land Drainage, Jordan: Feeding of Animals, Revised, Livingston: Field Crop Production. Lyon: Soils and Fertilizers. Lyon, Fippin and Buckman: Soils; Their Properties and Management. Mann: Beginnings in Agriculture. Montgomery: The Corn Crops. Morgan: Field Crops for the Cotton-Belt. Mumford: The Breeding of Animals. Piper: Forage Plants and their Culture. Sampson: Effective Farming. Thorn and Fisk: The Book of Cheese. Warren: Elements of Agriculture. Warren: Farm Management. Wheeler: Manures and Fertilizers. White: Principles of Floriculture. Widtsoe: Principles of Irrigation Prac- tice. THE BOOK OF ICE-CREAM BY WALTER W. FISK w ASSISTANT PROFESSOR OF DAIRY INDUSTRY, NEW YORK STATE COLLEGE OF AGRICULTURE AT CORNELL UNIVERSITY N^m fork THE MACMILLAN COMPANY 1919 All rights reserved Copyright, 1919 By the MACMILLAN COMPANY Set up and electrotyped. Published November, 1919. DEC il iyi9 ©a.A535996 ^^ . iK I PREFACE The older ones of us look back on the ice-cream of our youth as a luxury, to be expected on festivals and holi- days. The rising generation, however, is coming to look on it as a food. Once the manufacture of the confection- ery shop and the household, it is now produced in great quantities by concerns devoting themselves to it entirely, making it by highly developed standardized processes. A line of special machinery has been perfected for its manufacture. The subject is taught in the colleges. Yet the home manufacture has not passed and should not pass; rather should the product be made more frequently and in larger quantity in the household. No longer must one offer an excuse for a book on ice- cream. This book is made for class-room and laboratory use, growing out of the author's teaching experience; the manufacturer's interest has been set forth; yet it is hoped that the housewife will find directions for her use. Acknowledgment is due the following parties for valuable assistance either for the illustrations, or definite information or helpful criticisms: Henry Vogt Machine Co., Louisville, Ky.; Wheats Ice Cream Co., Buffalo, N. Y.; DeLaval Separator Co., New York, N. Y.; Jamison Cold Storage Door Co., Hagerstown, Md.; Merrell-Soule Co., Syracuse, N. Y.; The Ekenberg Co., Cortland, N. Y.; Chapin-Sacks Mfg. Co., Washington, D. C; The Cream- ery Package Mfg. Co., Chicago, 111.; York Mfg. Co., York, Pa.; Davis- Watkins Dairymen's Mfg. Co., Chicago. vi PREFACE 111.; J. G. Cherry Co., Cedar Rapids, la.; Emery Thomp- son Machine and Supply Co., New York, N. Y.; T. D. Cutler, Ice-Cream Trade Journal, New York, N. Y.; Brunswick Refrigerating Co., New Brunswick, N. J.; L. O. Thayer, The International Confectioner, New York, N. Y.; Mojonnier Bros., Chicago, 111.; Sharpies Separator Co., West Chester, Pa.; Joseph Burnett Extract Co., Boston, Mass.; Nafis Glass Co., Chicago, 111.; J. E. Reyna, Dept. of Drawing, New York State College of Agri- culture, Ithaca, N. Y. The following members of the Dairy Dept. of the New York State College of Agriculture at Cornell University, Ithaca, N. Y: W. A. Stocking, H. E. Ross, T. J. Mclnerney, W. E. Ayres, G. C. Dutton, H. C. Troy, E. S. Guthrie, G. C. Supplee. W. W. FISK. Ithaca, N. Y., March 1, 1919. TABLE OF CONTENTS (Numbers in the text refer to paragraphs) CHAPTER I PAGES GENERAL STATEMENTS ON ICE-CREAM 1-7 Materials used in ice-cream, 1; Definition of ice-cream, 2; Problems of ice-cream-making, 3; Ice- cream-making a science, 4. CHAPTER II MILK AND CREAM AS RELATED TO ICE-CREAM ......... 8-24 Method of securing supply, 5; Quality of milk and cream desired, 6; Why milk and cream are not of the desired quality, 7; The flavor of foods eaten by the cow, 8; The absorption of flavors and odors in the atmosphere, 9; The unhealthy condition of the cow, 10; The bac- teria in the milk, 11; The sediment test, 12; How to prevent the growth of micro-organisms in the milk and cream, 13; Milk and cream production and handling, 14; Clarifier, 15; The chemical composition of the milk and cream, 16. CHAPTER III MANUFACTURED MILK PRODUCTS AS RELATED TO ICE- CREAM 25-42 Condensed and Evaporated Milk: Method of manufacture, 17; Standards for condensed milk, 18; Conditions essential for a milk condensory, 19; Supply of condensed milk for the ice-cream plant, 20. Milk Powder: Standards for milk powder,' 21; Powdered milk processes, 22; Merrell-Soule vii viii TABLE OF CONTENTS PAGES powdered milk, 23; History of Merrell-Soule proc- ess, 24; Uses of Merrell-Soule powder in ice-cream, 25; Ekenberg powdered milk, 26; Uses of Eken- berg powder in ice-cream, 27; Butter, 28. CHAPTER IV SUGAR, CHOCOLATE PRODUCTS, FRUITS, STABILIZERS AND FILLERS 43-56 Sugar, 29; Invert sugar, 30; Sugar-saving sub- stitutes, 31; Cocoa and cocoa products, 32; Man- ufacture of chocolate and cocoa, 33; Composition of cocoa products, 34; Adulteration of cocoa and standards of purity, 35; Chocolate sirup, 36; Fruits, 37; Nuts, 38; Stabilizers and fillers, 39; Gelatine, 40; Preparing gelatine for use in the ice- cream, 41; Gum tragacanth, 42; Other substances used as binders, 43; Eggs, 44; Starchy fillers, 45; Prepared ice-cream powders, 46; Rennet, 47. CHAPTER V FLAVORING EXTRACTS 57-68 Vanilla Extract: Nature of vanilla plant, 48; Curing vanilla beans, 49; Marketing vanilla beans, 50; Production of vanilla beans, 51; The ingredi- ents of vanilla extract, 52; The chemistry of van- illa, 53; Adulteration of va.silla extract, 54. Lemon Extract: Preparation of lemon oil, 55; The chem- istry of lemon oil, 56; Orange extract, 57; Fruit extracts, 58. CHAPTER VI CLASSIFICATION 69-80 Classification of ice-cream, 59; Receipts for ice- cream, 60; Vanilla ice-cream, 61; Chocolate ice- cream, 62; Caramel ice-cream, 63; Coffee ice-cream, 64; Maple ice-cream, 65; Fruit ice-cream, 66; Nut TABLE OF CONTENTS ' ix PAGES ice-cream, 67; Bisque ice-cream, 68; Mousse, 69; Cooked ice-cream, 70; Parfait, 71; Puddings, 72; Custards, 73; Ices and sherbets, 74; Ices, 75; Water sherbets, 76; Punches, 77; Milk sherbets, 78; Lacto, 79. CHAPTER VII EQUIPMENT 81-100 Freezers, 80; Mixers, 81; Gelatine kettles, 82; Hardening the ice-cream, 83; Packing-cans, 84; Ice crushers, 85; Ice-cream can washers, 86; Emul- sors, creamers, and homogenizers, 87; Cost of equipment, 88. CHAPTER VIII REFRIGERATION AS APPLIED TO ICE-CREAM-MAKING. . . 101-128 Terms used, 89. Natural Ice: The ice field, 90; The ice-house, 91; Harvesting and storing, 92; Amount of ice needed, 93; Use of ice and salt mixture, 94. Mechanical Refrigeration: Principles of mechanical refrigeration, 95; Materials used in mechanical refrigerating systems, 96; Opera- tion of refrigerating machines, 97; The compres- sion system, 98; Parts of a compression system, 99; Operation of direct expansion compression system, 100; Location of evaporating coils, 101; Notes on operating compression system, 102. Absorption Systems: Operation of absorption re- frigerating systems, 103; Arrangement of double pipe and atmospheric absorption machines, 104. CHAPTER IX PREPARING THE MIX 129-133 Importance of preparing the mix, 105; Usual procedure in preparing the mix, 106; Temperature of the mix, 107. X TABLE OF CONTENTS CHAPTER X PAGES FREEZING PROCESS 134-144 Purpose of freezing, 108; Rate of freezing, 109; Proper method of freezing, 110; Over-run or swell, 111; Condition of ice-cream when removed from freezer, 112; Freezing sherbets and ices, 113. CHAPTER XI HARDENING ICE-CREAM 145-162 Methods of hardening, 114; Hardening in ice and salt mixture, 115; The slush-box or brine-box method of hardening, 116; The hardening-room, 117; The still-air type, 118; The gravity air-type, 119; The forced-air type, 120; Defrosting the coils, 121; Time required for hardening, 122; Ef- fects of hardening on quality, 123; Fancy molded ice-cream, 124. CHAPTER XII JUDGING AND DEFECTS OF ICE-CREAM 163-169 Score-cards, 125; Explanation of character- istics mentioned in score-card, 126; Defects in ice-cream, 127; Defects in flavor, 128; Defects in body and texture, 129; Defects in richness, 130; Defects in appearance, 131; Defects in package, 132. CHAPTER XIII BACTERIA IN RELATION TO ICE-CREAM 170-182 Sources of bacteria in ice-cream, 133; The ef- fect of freezing and hardening on the bacterial count, 134; Types of organisms in ice-cream, 135; The total-acid groups, 136; The inert group, 137; The alkaU group, 138; The peptonizing group, 139; Colon Bacilli in ice-cream, 140; Difficulties in studying the bacteriology of ice-cream, 141. TABLE OF CONTENTS sd CHAPTER XIV PAGES TESTING 183-245 The Babcock Test: Testing whole milk for fat, 142; Composite samples of milk, 143; Measuring the sample, 144; Adding the acid, 145; Whirling the sample, 146; Reading the test, 147; Appear- ance of a completed test, 148; Care of the test- bottles, 149; Testing cream, 150; Cream testing apparatus, 151; Sampling cream, 152; Making the cream test, 153; Tempering the fat and reading the percentage, 154; Testing skim-milk, 155; Modi- fications of the Babcock test for ice-cream, 156; The glacial acetic and hydrochloric acid test, 157; The sulfuric acid test, 158; Acetic and sulfuric acid test, 159; The lactometer, 160; Calculating the solids not fat in the milk, 161; Testing milk for acidity, 162; Test for formaldehyde, 163; Test for boiled milk, 164. Testing Butter for Fat, Mois- ture, and Salt: Preparing the sample, 165; Test- ing butter for fat, 166; Testing butter for mois- ture, 167; Testing butter for salt, 168; Test for viscosity, 169; Standardization, 170; Benkendorf test for over-run in ice-cream, 171 ; Test to deter- mine the hardness of ice-cream, 172. Mojonnier Tester: General preliminary information, 173; Test- ing evaporate, sweetened condensed, bulk con- densed milk, ice-cream (mix or melted) for fat or total solids, 174; Fat determination, 175; Total solids determination, 176; Testing butter, 177; Testing fresh milk, skim-milk, whey, and butter- milk for fat and total solids, 178; Testing powdered milk, cocoa, malted milk and milk chocolate for fat and total solids, 179; Testing cream for fat and total solids, 180; List of precautions to observe in operating Mojonnier tester, 181. Mojonnier Over-run Tester: Adjusting cups for mix, 182; Actual operation, 183; Controlling the over-run, 184; Savings and economics, 185. xii TABLE OF CONTENTS CHAPTER XV PAGES MARKETING AND BUSINESS MANAGEMENT 246-271 Demand for ice-cream, 186; Food value of ice- cream, 187; Locating a market, 188; Method of delivery, 189; Cost of delivery, 190; Packages used for delivery, 191; Advertising, 192; Sales- men, 193. Business Management: Purchase of raw material, 194; Price of dairy products, 195; Bookkeeping system, 196; Shipping clerk, 197; Report blanks, 198; Losses, 199; Pack-cans and tubs, 200; Rusty pack-cans, 201; Soft ice-cream, 202; Transferring, 203. Laws: Sanitary condi- tions and adulterated milk and cream, 204; Bab- cock test, 205; Purchaser's or vender's license, 206; Legal standards, 207. CHAPTER XVI CONSTRUCTION AND ARRANGEMENT OF THE FACTORY . . . 272-286 Location of the plant, 208; Arrangement of machinery, 209; Loading platform, 210; Light, 211; Ventilation, 212; Floors, 213; Ceilings and side-walls, 214; Sinks and cupboards, 215; Locker rooms, 216; Cleanliness, 217; Cleaning utensils, 218; Cleaning the floor, 219; Store-room and work shop, 220; Sanitary codes, 221. CHAPTER XVII HISTORY AND EXTENT OF THE INDUSTRY . 287-296 Early history, 222; Development of ice-cream in the household, 223; Development of wholesale ice-cream, 224; Extent of the industry, 225. LIST OF ILLUSTRATIONS PAGE Fig. 1. — Refrigerator room for storing cream and milk in a large ice-cream plant. (Courtesy of Wheat's Ice Cream Co., Buffalo, N. Y.) 12 Fig. 2. — Filters from sediment tests showing the amount of dirt in different samples of milk. These are the grades made by the New York City Board of Health . . 18 Fig. 3. — Sharpies milk clarifier 22 Fig. 4. — De Laval milk clarifier, turbine drive 22 Fig. 5. — ^View of modern condensory showing hot wells, vacuum pan, vacuum pump and cooling tanks. (Cour- tesy of Wheat's Ice Cream Co., Buffalo, N. Y.). . . . . 26 Fig. 6. — Fruit storage in large ice-cream plant. (Courtesy of Wheat's Ice Cream Co., Buffalo, N.-Y.) 51 Fig. 7. — Steam jacketed kettle for heating gelatine 53 Fig. 8. — Hand freezer with tub and can cut away showing ice and salt mixture and beaters and scrapers in the can. 82 Fig. 9. — Hand freezer with fly wheel, using salt and ice mixture for freezing. The capacity of this freezer is five gallons 82 Fig. 10. — Power driven tub and can freezer using a salt and ice mixture. The can, dasher and gears are shown removed 82 Fig. 11. — Horizontal brine freezer attached to a salt and ice brine box. The pump is behind the box 83 Fig. 12. — ^Verticle belt driven brine freezer connected to ice and salt brine box. (Courtesy of Emery Thompson Machine and Supply Co., New York City.) 84 Fig. 13. — Perfection brine freezer, direct motor drive. (Courtesy of J. G. Cherry Co., Cedar Rapids, Iowa.) . . 85 xiii xiv LIST OF ILLUSTRATIONS PAGE Fig. 14. — Progress vertical belt drive brine freezer. (Cour- tesy of Davis Watkins Dairymen's Manufacturing Co., Chicago, 111.) 86 Fig. 15. — Emery Thompson vertical direct motor drive brine freezer. (Courtesy of Emery Thompson Machine and Supply Co., New York City.) 87 Fig. 16. — Fort Atkinson belt drive brine freezer. (Cour- tesy of Creamery Package Manufacturing Co., New York City.) 88 Fig. 17. — Disc brine freezer either continuous or batch. (Courtesy of Creamery Package Manufacturing Co., New York City.) 89 Fig. 18. — Side view of disc freezer shown in Fig. 17, show- ing brine tank and pump. (Courtesy of Creamery Package Manufacturing Company, New York City.) 89 Fig. 19. — Freezing discs of freezer shown in Figs. 17 and 18. The scrapers for removing the frozen ice-cream from the discs and the screw to force it out of the delivery spout are shown. (Courtesy of Creamery Package Manufacturing Co., New York City.) 90 Fig. 20.— a pasteurizer or ripener used as an ice-cream mixer. Strips are attached to the coils to prevent the settling of the sugar on the bottom 90 Fig. 21. — Minnetonna starter can or ice-cream mixer. (Courtesy of Davis-Watkins Dairymen's Manufactur- ing Co., Chicago, 111.) 91 Fig. 22. — ^Alaska ice-cream mixer. The side is cut away showing the coils and insulation. The mechanical agi- tator is seen at the bottom. The cover fits air tight so that by means of an air pump and air pressure the mix may be forced to the freezer. (Courtesy of Creamery Package Manufacturing Co., New York City.) 92 Fig. 23. — ^Wizard ice-cream mixer. (Courtesy of Cream- ery Package Manufacturing Co., New York City.) . . 92 Fig. 24. — Emery Thompson ice-cream mixer. (Courtesy of Emery Thompson Machine and Supply Co., New York City 92 LIST OF ILLUSTRATIONS xv PAGE Fig. 25. — Two types of ice-cream packing-cans 93 Fig. 26.— Ice spud 94 Fig. 27. — Ice cracker 94 Fig. 28. — Perforated ice shovel 94 Fig. 29. — Ice crusher with tight and loose pulley for me- chanical power. The teeth or picks on the drum may be seen. 94 Fig. 30. — The perfection ice cream can washer and ster- ilizer. (Courtesy of J. G. Cherry Co., Cedar Rapids, Iowa.) 94 Fig. 31. — Fort Atkinson ice-cream can washer and steril- izer. (Courtesy of Creamery Package Manufacturing Co., New York City.) 95 Fig. 32. — De Laval centrifugal emulsor. (Courtesy of De Laval Separator Co., New York City.) 95 Fig. 33. — Perfection cream maker and emulsifier. (Cour- tesy of J. G. Cherry Co., Cedar Rapids, Iowa.) 96 Fig. 34. — Progress homogenizer. (Courtesy of Davis- Watkins Dairymen's Manufacturing Co., Jersey City, N. J.) 97 Fig. 35. — Gaulin homogenizer. (Courtesy of Creamery Package Manufacturing Co., New York City.) 98 Fig. 36.^ — ^Sharples centrifugal emulsor. (Courtesy of Sharpies Separator Co. (West Chester, Pa.) 99 Fig. 37.— Hand ice-saw 106 Fig. 38. — Ice-plow with marker 106 Fig. 39.— Splitting fork 107 Fig. 40. — ^Approximate temperatures obtained with dif- ferent proportions of ice and salt 108 Fig. 41. — Refrigeration available with different percent- ages of salt 109 Fig. 42. — Diagram showing relation of heat to tempera- ture 113 Fig. 43. — Simplest compression system of refrigeration. . 116 xvi LIST OF ILLUSTRATIONS PAGE Fig. 44. — Compression system of refrigeration in which the flow of liquid is regulated by expansion valve and the liquid changes to a gas in the coil of pipe thereby cool- ing the brine. The gas then passes off into the at- mosphere 117 Fig. 45. — Complete system of direct expansion refriger- ating system 118 Fig. 46. — Combination of direct expansion and brine stor- age tanks. This is the same system as shown in Fig. 45 with the brine tank (T) added in the refrigerator 120 Fig. 47. — Arrangement where it is desired to use cold brine for cooling in some machine such as an ice-cream freezer. This is the same refrigerating system as shown in Figs. 45 and 46 121 Fig. 48. — Diagram of the Vogt absorption refrigerating machine, showing pipe connections and directions in which the liquids and gases travel throughout the en- tire system. (Courtesy of Henry Vogt Machine Co., Louisville, Kentucky.) 123 Fig. 49. — General arrangement of double pipe absorption refrigerating machine, showing the connections and the direction in which the liquids and gases flow. (Cour- tesy of York Manufacturing Company, York, Pa.) . . 124 Fig. 50. — General arrangement of atmosphere absorption . machine showing the connections and the direction in which the liquids and gases flow. (Courtesy of York Manufacturing Company, York, Pa.) 126 Fig. 51. — Mixing room in large ice-cream plant. (Courtesy of Wheat's Ice Cream Company, Buffalo, N. Y.) .... 132 Fig. 52. — Battery of freezers in a large ice-cream plant. (Courtesy of Chapin-Sacks Manufacturing Co., Wash- ington, D. C.) 135 Fig. 53. — Different styles of transfer ladles or scoops 146 Fig. 54. — Plank box for hardening ice-cream in a salt and ice mixture. The cans are placed in perforated cylin- ders so that the cans may be changed and the ice will not fall in and fill the space 147 LIST OF ILLUSTRATIONS xvii PAGE Fig. 55. — Still-air hardening-room showing evaporating coils forming shelves on which the pack-cans of ice- cream are placed to harden. Other evaporating coils may be seen on the sides and ceiling. (Courtesy of Brunswick Refrigerating Co., New Brunswick, N. J.) 150 Fig. 56. — Forced air hardening-room. (Courtesy of Chapin- Sacks Manufacturing Co., Washington, D. C.) 152 Fig. 57. — Brick ice-cream trowels. Straight and bent handles 158 Fig. 58. — Quart and sectional brick molds. The sec- tional bricks hold several quarts 159 Fig. 59. — Brick hardening-room. (Courtesy of Chapin- Sacks Manufacturing Co., Washington, D. C. 160 Fig. 60. — Center mold and examples 161 Fig. 61. — Individual ice-cream molds and ice cave for pack- ing molds 161 Fig. 62. — ^Babcock milk pipette 185 Fig. 63. — Babcock whole milk test-bottle 186 Fig. 64.— Acid measure for Babcock test 187 Fig. 65. — Diagram showing the motion and position of a test-bottle while mixing the milk and the acid 188 Fig. 66. — Hand and power centrifuges 189 Fig. 67. — Proper way to read the percentage of fat in a Bab- cock whole milk test-bottle 191 Fig. 68" — Babcock cream test-bottles 193 Fig. 69. — Method of reading the percentage of fat in a Bab- cock cream test-bottle 195 Fig. 70.— Skimmed-milk test-bottle 196 Fig. 71. — Quevenne lactometer 199 Fig. 72.— Board of Health lactometer. . . .* 200 Fig. 73.— Nafis acid test 201 Fig. 74. — Apparatus for testing ice-cream over-run by the Benkendorf method ; 213 Fig. 75. — Mojoimier tester for fat and total solids. 217 xviii LIST OF ILLUSTRATIONS PAGE Fig. 76. — Mojonnier over-run tester 241 Fig. 77. — Ice-cream packing tubs 252 Fig. 78. — ^Auto delivery truck for ice-cream 253 Fig. 79. — Ice-cream cabinet with side cut away showing insulation and perforated cylinders on which the pack- cans of ice-cream set 254 Fig. 80. — Different styles of ice-cream dishes 255 Fig. 81. — Shipping platform and office of shipping clerk in a large ice-cream plant. (Courtesy of Wheat's Ice Cream Co., Buffalo, N. Y.) 261 Fig. 82. — Revolving door used for putting the ice-cream into the hardening-room 263 Fig. 83. — Plan of a small ice-cream plant 273 Fig. 84. — Basement plan of large ice-cream plant 274 Fig. 85. — First floor plan of plant shown in Fig. 84 275 Fig. 86. — Second floor plan of plant shown in Figs. 84 and 85 275 Fig. 87. — A loading platform in a large ice-cream plant. (Courtesy of Chapin-Sacks Manufacturing Co., Wash- ington, D. C.) 276 Fig. 88. — The value of skyhghts is shown by the well- lighted freezing-room, considerable floor space above being sacrificed for this purpose. (Courtesy of Wheat's Ice Cream Co., Buffalo, N. Y.) 277 THE BOOK OF ICE-CREAM THE BOOK OF ICECREAM CHAPTER I GENERAL STATEMENTS ON ICE-CREAM Ice-cream is known commonly to-day as ja food, al- though in the past it was considered and used only as a delicacy or dessert. Because of the rapid growth of the industry and the large number and varying amounts of materials that can be used in the making of ice-cream, its composition may be varied within wide limits. The Federal Government and most of the States have set standards for ice-cream. Some products, such as cus- tards, sherbets, ices and the like, are usually included in the general discussion of ice-creams but technically should not be classed with them. 1. Materials used in ice-cream. — The basis of ice-cream is some dairy product or a combination of dairy products, such as milk, cream, skim-milk, condensed milk, milk powder, homogenized or emulsified milk or cream, and the like. These materials contain varying amounts of fat and solids not fat, ranging from to several per cent. Either one or all may be used, as the manufacturer de- termines, to give the ice-cream the desired amount of fat and milk solids. The price often determines the kind and amounts of the different materials to be used. It is im- portant that these dairy products be clean; otherwise the ice-cream may have an undesirable flavor. 1 2 THE BOOK OF ICE-CREAM Sugar in some form must be used to sweeten ice-cream. Granulated sugar was employed ordinarily before the war. However, in conserving for the war, it was found that various sirups could be substituted. Corn sirup was commonly used, and some invert sugar, maple sirup and honey in smaller amounts. A large variety of materials may be utilized to flavor the ice-cream. The extracts commonly employed are vanilla and lemon. Fruits, either fresh, canned, pre- served, dried or candied, may be used as flavoring, various bread or cake products, such as macaroons, sweetened wafers and sponge cake, and also caramel and chocolate products, usually chocolate or cocoa. A little color of the proper shade to give the product the characteristic tint suggested by the flavor is com- monly added. If the ice-cream is not consumed as soon as it is made, ice crystals soon separate, causing it to become grainy in texture. In order to prevent this, some form of *' stabilizer" is added, commonly gelatine. However, gum tragacanth or some of the prepared ice-cream pow- ders may be used. 2. Definition of ice-cream. — ^Because of the large vari- ation of materials, both in quantity and kind, that may be used in its making, the definitions of ice-cream are more or less elastic. The various dictionaries give the following definitions: Webster, — "Ice-cream is milk or cream sweetened, flavored, and congealed by a freezing mixture, sometimes instead of cream the materials of a custard are used"; Century, — "Ice-cream is a confection made by congealing variously flavored cream or custard in a vessel surrounded with a freezing mixture;" Stand- ard, — "Ice-cream is cream, milk or custard sweetened GENERAL STATEMENTS ON ICE-CREAM 3 and flavored and frozen by a freezing mixture, being usually agitated by a dasher in the process to make it of uniform consistency/' The United States Department of Agriculture bases its definition * on the composition of the finished ice-cream. Its definitions are as follows: Ice-cream is a frozen product made from cream and sugar with or without a natural flavoring and contains not less than 14 per cent of milk-fat. Fruit ice-cream * is a frozen product made from cream, sugar and sound, clean, mature fruits, and contains not less than 12 per cent of milk-fat. Nut ice-cream * is a frozen product made from cream, sugar and sound non-rancid nuts and contains not less than 12 per cent of milk-fat. The National Association of Ice-Cream Manufacturers defines ice-cream and the adulterated product as follows: That for the purpose of this act ice-cream is hereby defined and standardized: First: Ice-cream is a frozen compound, varied a^ to kind and proportion of ingredients within the limits established by custom and usage. Second: Ice-cream consists chiefly of a sweetened and flavored mixture of cream, or cream and milk, or milk, with or without added milk-fat in the form of sound sweet butter or as contained in condensed, evaporated or concentrated milk or in milk powder, and with or without added milk solids not fat in the form of skim-milk powder or as contained in milk powder or in condensed, evaporated or concentrated skim-milk, or of a sweetened and flavored homogen- ized or emulsified mixture of sound, sweet butter, milk powder or skim-milk powder and water, with * Office of the Secretary, U. S. Dept. Agr., Bui. 19, 1906. THE BOOK OF ICE-CREAM the addition of gelatine, vegetable gum, or other wholesome stabilizer. Third: Standard ice-cream contains not less than eight (8) per cent milk-fat and the content of milk- fat and milk solids not fat combined shall not be less than eighteen (18) per cent except when the ingredients of standard ice-cream include eggs, fruit or fruit juice, cocoa or chocolate, cake, confections or nuts, such reduction of the percentage of milk-fat and milk solids not fat as may be due to the addition of such ingredients shall be allowed. Fourth: When ice-cream is sold or offered for sale without designation of its kind, quality or grade on a label, brand, or tag attached to the package or container, or, in case of removal from the original package or container, by a notice conspicuously posted in or at the place where such ice-cream is sold or offered for sale, it shall be deemed that such ice- cream is sold or offered for sale as of the grade of and for standard ice-cream, or better. That for the purposes of this act ice-cream shall be deemed to be adulterated : (1) If in quahty or grade it is lower than the pro- fessed standard of quahty or grade which it is sold or offered for sale. (2) If it contains any added poisonous or other added deleterious ingredient which may render such ice-cream injurious to health. (3) If it contains any rancid or renovated or process butter, or any fat or oil other than milk-fat and the fat or oil of contained eggs or nuts and the fat or oil of substances used for flavoring purposes only. GENERAL STATEMENTS ON ICE-CREAM 5 (4) If it consists in whole or in part of any filthy or decomposed substance which may render such ice-cream injurious to health, or is otherwise so contaminated that such ice-cream is injurious to health. That for the purpose of this act ice-cream shall be deemed to be misbranded: First: If the label, brand, tag or notice under which it is sold or offered for sale is false or misleading in any particular as to the kind, grade or quality or composition of such ice-cream; or if any notice to the purchaser required by this act to be given is omitted. Second: If it is sold or offered for sale as the product of one manufacturer when in reality it is the product of another manufacturer: or if on the label, brand, tag or notice under which it is sold or offered for sale there is any false statement concerning the sanitary conditions under which such ice-cream is manufactured. So far the description of ice-cream has mentioned only the materials to be used and in some cases the chemical composition in so far as percentage of fat is concerned. It is evident that there is considerable difference of opin- ion regarding the minimum percentage of fat that the ice-cream should contain. It would seem that it might not only be desirable to mention the materials which could be employed, but also the percentage of fat and total solids or milk solids not fat, by means of a sliding scale. In the description, no account is taken of the bacterial-content of the ice-cream. The number of or- ganisms may or may not give an indication of the quality of the materials used and the sanitary condition under 6 THE BOOK OF ICE-CREAM which the manufacturing and handling is done. When a bacterial standard for milk is universally recognized and enforced, then a bacterial standard for ice-cream may be enforced. It is to be desired that an adequate definition of ice-cream will be forthcoming and that this definition will be enforced. This will do much to im- prove the quality of the product. 3. Problems of ice-cream-making. — The successful making of ice-cream calls for an understanding of the com- plex factors involved. These factors are: The production and handling of the milk and the milk products employed; the chemical and bacteriological composition of the milk products; the various tests used, such as fat, acid, tests for swell and the like; the blending of the flavors of the various products to secure the characteristic flavor de- sired; the freezing process and subsequent handling of the ice-cream; the construction and operation of the machinery. A working knowledge of the combination of the above factors is necessary to make ice-cream of uni- form quality. After the manufacture, the marketing of the product is a vital question and it should receive con- stant attention and study. 4. Ice-cream-making a science. — Only recently has the making of ice-cream been recognized as founded on science. This is probably because in the past most of the ice-cream was made in small amounts largely in the household, while now it is manufactured in large quantities in commercial plants. In these large plants and in the agricultural colleges, considerable attention has been paid recently to the making of ice-cream. No description of the process can replace experience. Description of appearance of the ice-cream and conditions during the making process, in GENERAL STATEMENTS ON ICE-CREAM 7 terms definite and clear enough to be readily understood by beginners, has been found to be impossible. Certain principles and essentials of practice can be presented, which form the foundation for intelligent work. The more study given to the process, and the better the under- lying principles are understood, the further we will depart from rule-of-thumb practice. CHAPTER II MILK AND CREAM AS RELATED TO ICE- CREAM Several milk products are commonly used in ice- cream, namely: whole and skimmed-milk, cream, con- densed milk, evaporated milk, milk powder and butter. These may be utilized singly or in combinations. The most important characteristic of the milk products is their flavor which should be clean and sweet; if not, it is likely to impart its undesirable flavor to the ice-cream. Much might be written on the production, care and composition of the milk and cream. Space will not per- mit this, but the essential factors as related to ice-cream will be discussed. 5. Method of securing supply. — The ice-cream indus- try offers an entirely different problem from the other branches of the dairy industry in relation to securing a supply of milk and cream. This is due to the location. There are usually brokers or commission men who are willing to handle butter, cheese, condensed milk and other dairy products which are not comparatively as perishable as ice-cream. Therefore, the butter, cheese, and condensed milk plants are located where they can secure easily a supply of raw milk, which is in the coun- try. On the other hand, there are no brokers or com- mission men who handle ice-cream; therefore, the ice- cream is sold directly to the retailer or consumer. Because of the ease of delivery, the ice-cream plant is located in 8 MILK AND CREAM 9 the center of population, namely, the city or village. It has not proved satisfactory, either from the view point of quality or cost of production, to make the ice-cream near the supply in the country and ship the finished product to the city. Due to the location of the ice-cream plant in the city, there are four ways of securing the raw materials: 1. Buy milk and cream from dealer. 2. Operate creamery in country and get supply from it. 3. Use surplus from other dairy operations, and pur- chase necessary balance. 4. Use of homogenized or emulsified milk and cream. Each ice-cream concern will have to decide, after care- fully considering all the factors, which method is best adapted for its use. Each has its advantages and dis- advantages. Buying milk and cream from dealer. Advantages: 1. No surplus to dispose of. 2. Minimizes labor in the ice-cream plant. 3. Requires less capital. Disadvantages : 1. Uncertainty of cream supply. 2. No control of quality. 3. Higher cost of cream. 4. No control of fat-content of cream. 5. Must have separate supply of condensed milk. 6. At mercy of cream dealer. 7. Difficult to dispose of any surplus. Operating creamery in country and getting supply from it. Advantages: 1. Certain of known supply. 10 THE BOOK OF ICE-CREAM 2. Better control of quality. 3. Easy to dispose of any surplus. 4. Usually a cheaper supply. 5. Can secure cream of desired fat-content. 6. Can pay patrons better price for milk. 7. May make own supply of condensed milk. 8. More independent. Disadvantages: 1. Requires more capital. 2. Requires more labor. 3. Requires more management. 4. Must deal directly with the dairy-men. 5. Transportation. 6. Must find suitable location. Using surplus from other dairy operations and purchasing necessary balance. Advantages : 1. Makes an outlet for surplus. 2. Economy of delivery. Disadvantages : 1. May make too large a business. 2. May not have necessary equipment, especially refrigerator. 3. May not be able to purchase necessary balance of supply. Disadvantages same as buying from dealer. 4. If side line, may not give it proper attention. 5. May not have surplus only part of year so balance of year do not care to operate. Use of homogenized or emulsified milk and cream. Advantages: 1. When big demand can quickly make supply of cream. MILK AND CREAM U 2. Sweet cream can be secured in localities where it can not be produced easily, especially the South. 3. Does not necessitate carrying a large surplus of cream. 4. Usually a cheap supply of cream. Disadvantages : 1. Tendency to try to use butter and milk prod- ucts of inferior quality. 2. Because of the physical nature of homogenized cream, try to use less fat in it. 6. Quality of milk and cream desired. — Regardless of how obtained, the cream and milk should be of the de- sired quality for ice-cream manufacture. The cream should be clean flavored and sweet. In some plants, when the cream is slightly sour, a neutralizer is added, but this practice should not be followed. Better care, better holding methods or both should be employed to insure sweet cream. The refrigerated room in which milk and cream are stored in a large ice-cream plant is shown in Fig. 1. Cream for ice-cream-making should not have more than 0.24 per cent of acid by the acid test. (For use of acid test, see Chapter XIV.) In order to in- sure sweetness, cream is usually pasteurized. Pasteuriza- tion * is heating to a temperature suflftciently high, usually 145° F. and held at this temperature for a sufficient period, usually thirty minutes, to kill most of the organ- isms in the milk and then rapidly cooling to 50° F. or below. When pasteurized cream and milk are used, there is not the danger from disease organisms that there is * Ayres, S. H., " The Present Status of the Pasteurization of Milk/' U. S. Dept. Agr. Bui. 342, 1916. 12 THE BOOK OF ICE-CREAM from raw cream. An ''aged" cream is to be desired for ice-cream-making because it is more viscous. By ''aged" is meant the holding of the cream for a period after sepa- rating before it is made into ice-cream. Usually it is aged for twenty-four to thirty-six hours. While aging it must be kept cold so it will not sour and it should not be Fig. 1.— Refrigerated room for storing milk and cream in a large ice-cream plant. frozen. It is hard to melt frozen cream and it is liable to cause the ice-cream to be grainy. The demand for ice-cream fluctuates with the weather changes. When it is hot there is an extensive demand but if the weather rapidly becomes cool this demand suddenly decreases or vice versa. This means that the ice-cream- rriaker either must carry or have at his disposal a variable supply of cream. When hot weather increases the de- MILK AND CREAM 13 mand, there may not be time to age the cream or it may be held so long that it becomes sour. Homogenized or emulsified cream is to be desired for ice-cream-making because it gives a smoother body and texture to the product. This is undoubtedly due to the fat globules and other solids being broken up into smaller particles by the process. 7. Why milk and cteam are not of the desired quality. — Some milk and cream has undesirable flavors which may be more or less pronounced. These are due to: the flavor of foods eaten by the cow; the absorption of flavors and odors from the atmosphere; the health of the cow; the bacteria present. If not properly handled, the milk and cream will soon become sour. 8. The flavor of foods eaten by the cow. — The presence of undesirable flavors in the milk is due many times to the cows eating foods with very pronounced flavors. Most common of these foods are onion, garlic, turnips, cabbage, decayed ensilage, various pasture weeds, and the like. The flavoring oils are volatile and so are able to pass easily through all the tissues of the animal, and in a short time pass off through the various excretory channels. During the time that the food is undergoing digestion, these volatile oils are not only present in the milk, but all the tissues of the animal. By the time the process of digestion is completed, the volatile flavors will have passed away largely. Therefore, if the time of milking and feeding are properly regulated, a dairy-man may feed considerable quantities of strong-flavored food, without any appreciable effect on the flavor of the milk. To do this successfully, the cows should be fed immedi- ately before or after milking, preferably the latter. This allows time for the digestive process to take place, during 14 THE BOOK OF ICE-CREAM which time the volatile substances will have passed away. While, if the milking occurred three or four hours after feeding, these volatile substances would be present in the milk and so flavor it. In the case of those plants which grow wild in the pasture and to which the cows have continued access, it is much more difficult to overcome the bad flavor in the milk. The only thing which can be done is to allow the cows to pasture for a short time immediately after milking. This will make it necessary to supple- ment the food of the pasture with dry feed, or to have another pasture where these undesirable plants do not grow. 9. The absorption of fiavors and odors in the atmos- phere. — Milk, especially when warm, possesses a remark- able ability to absorb and retain odors in the surrounding atmosphere. For this reason, the milk should be exposed only in a surrounding of clean pure air. Some of the common sources of these undesirable odors are : bad smell- ing stables; unclean cows; aerating milk near hog pens, barnyards, swill barrels, and like odoriferous sources; strong-smelling feeds in the stable during milking, and the like. The only way to overcome these undesirable flavors and odors in the milk is not to expose the milk to them. The safest policy is to remove the source of the odor. 10. The unhealthy condition of the cow. — Milk secreted just before or just after parturition is different in physi- cal properties and chemical composition from that se- creted at any other time during the lactation period. This milk is known as colostrum. It is considered unfit for human lood, either as milk or products manufactured from the milk. Most states consider colostrum adulter- MILK AND CREAM 15 ated milk, and prohibit its sale fifteen days before or five days after parturition.* Whenever disease manifests itself in the cow, the milk should be discarded at once as human food. Some dis- eases are common both to the cow and man, such as tuberculosis and foot-and-mouth disease. If such dis- eases are present in the cow, the milk acts as a carrier for them to man. Digestive disorders of any sort in the cow are frequently accompanied by undesirable flavors in the milk. These are not believed to be due to the food eaten, but to the bad condition of the animal. On resuming a. normal condition, these undesirable flavors disappear. This is especially noticeable when cows are turned out to pasture for the first time in the spring, or when they are pastured on rank fall feed, such as second-growth clover. 11. The bacteria in the milk. — The bacteria are microscopic unicellular plants without chlorophyll. Be- sides bacteria, there are other forms of the lowest orders of the vegetable kingdom found in milk, such as yeasts and molds. The general characteristics of yeast and bacteria are somewhat similar. Bacteria are very widely distributed throughout nature. They are so small that they may float easily in the air or on particles of dust. They are so resistant to adverse conditions of growth that they may be present in a dormant or spore stage, and thereby not be recognized readily; when suitable environments for growth are again produced, germina- tion takes place at once. They are found in all surface water, on the surface of the earth, and upon all organic * N. J. Agricultural Law, 1913, section 30; Mich. Agricultural Law, 1915, section 77; Wis. Agricultural Law, 1913, section 4601- 49-5. 16 THE BOOK OF ICE-CREAM matter. There are a great many different groups of bacteria, some beneficial and some harmful to man. As they are so small, it is difficult to differentiate between the beneficial and harmful groups, except by the results produced or by a careful study in an especially equipped laboratory. Bacteria have many forms, the three com- mon forms being : spherical (coccus) ; rod-like or cylindri- cal (bacillus); and corkscrew (spirillum). The bacteria reproduce very rapidly by fission, that is, a transverse partition forms in the cell and when this partition is completed, the cell is divided. There are then two bac- teria where there was but one before. In some cases, this division has taken place regularly in twenty to thirty minutes. Like other plants, they are very sensitive to a food supply, to temperature, and to moisture, as con- ditions of growth. Inasmuch as the bacteria are plant cells, they must imbibe their food from materials in solu- tion. They may live on solid substances, but the food elements must be rendered soluble before they can be utilized. Bacteria prefer a neutral or slightly acid medium for growth, rather than an alkaline reaction; however, there are, many exceptions to this. The food for bacteria must contain carbon, hydrogen, oxygen, and nitrogen, together with small amounts of mineral matters. Or- ganic compounds make available food supplies. Ordinary milk furnishes a very favorable medium for the growth of bacteria because it contains an adequate and easily available food supply. In milk, there are certain groups of bacteria, which are ordinarily present, but any others which happen to get into the milk will live and rapidly multiply. Most forms of bacteria are dependent on tem- perature as a condition of growth. There is a range of temperature, more or less wide, at which the bacteria MILK AND CREAM 17 will grow and multiply with the greatest rapidity. This is called the optimum temperature and varies with the different groups of bacteria, but for most it is between 75° F. and 95° F. Growth of most of the bacteria found in milk will take place between 40° F.-45° F. to 105° F.- 115° F. Above and below these temperatures growth is retarded, and, if carried to extremes, life will be de- stroyed. Like plants which form structures called seeds to carry them through conditions unfavorable to growth, so some groups of bacteria form spores. The spores are exceedingly resistant to unfavorable conditions of growth, such as heat, cold, drying, food supply, and even chemical agents. It is this property which makes it difficult to destroy some bacteria. Because of the harmful effect of the micro-organisms in the milk and cream, precautions should be taken to keep them out. If they do enter, their growth can be checked by keeping the milk and cream cold. What has been said regarding bacteria is true of molds and yeasts. 12. The sediment test. — The amount of solid material or dirt in the milk is an indication of the amount of bac- terial contamination. It should be remembered that the strainer will take out the solid material, but the soluble portion and the bacteria will be left in the milk or cream. Thus an efficient strainer will defeat the sediment test. There are several sediment tests on the market. The test consists of filtering about a pint of milk through a cotton disc filter about an inch in diameter. The solid material or dirt is left on the filter. (Fig. 2.) The amount of dirt would indicate the amount of contamination in the milk. Much improvement in the quality of the milk has been accomplished by the use of the sediment test, because the cotton discs with the dirt are posted where 18 THE BOOK OF ICE-CREAM each patron can see them and pride causes the careless dairy-man to take more pains in the care and handhng of his milk. 13. How to prevent the growth of micro-organisms in the milk and cream. — Next in importance to clean pro- duction in the care of milk and cream, is the prevention of growth or development of the organisms in it. This is accomplished by cooling and keeping the milk and Fig. 2. — Filters from sediment tests showing the amount of dirt in different samples of milk. These are the grades made by the New York City Board of Health. cream cold and covered. If they are produced clean and kept covered, there are certain to be some micro-organisms in the milk and unless cooled these will develop and quickly spoil the milk and cream. Ross * and Mclnerney give the following summary regarding the cooling of milk and cream: ''Milk becomes cool, of course, when it gives up its heat to some substance colder than itself, and in order to have a rapid exchange of temperatures between two substances it is necessary that they have approximately the same density. On account of the great difference in density between air and milk, the latter will cool very *Ross, H. E., and Mclnerney, T. J., ''Cooling milk," Cornell Reading Courses, Vol. V, No. 102, 1914. MILK AND CREAM 19 slowly in air even though the temperature of the air is rather low. • If milk is allowed to cool by standing in a cold atmosphere, it will do so unevenly, and by the time the milk in the center of the can is cooled, that part near the walls of the can may be frozen. The fat is not evenly distributed in frozen milk; therefore it is not so good as normal milk. ''1. The bacteria-content of milk held at a temperature of 50° F. increases slowly, while the bacteria-content of milk held at 90° F. increases rapidly. "2. At a temperature of 90° F. bacteria increase rapidly in milk that had either a small or a large amount of bac- teria in it originally. "3. Cooling milk by placing the cans in a tank of ice water is a practical method for use in farm dairies. To cool the milk rapidly it must be stirred at frequent inter- vals. "4. Stirring the milk at intervals of five minutes caused a sufficiently rapid drop in temperature. Ra- pidity of coohng due to stirring the milk at intervals of five minutes and at intervals of ten minutes was very slight. "5. When sufficient quantities of ice were used, stirring the water in the cooling tank had little effect on the rapidity of cooling. "6. In order to obtain the best efficiency from the conical type of cooler, it is absolutely necessary to stir the water inside the cooler. "7. Lower temperatures can be obtained by using brine and ice than with ice water alone." Stocking * shows the effect of temperature on the de- * Stocking, W. A., Jr., ''Problems of the milk producers," N. Y. State Dept. Agr., Circ. 10, 1910. 20 THE BOOK OF ICE-CREAM velopment of the bacteria in milk by the following experi- ment: A sample of milk, which was thoroughly mixed, was divided into six equal parts. The six bottles were placed in water at different temperatures for twelve hours, at which time the germ-content of each lot was determined. The six bottles were then all placed to- gether in a temperature of 70 degrees and allowed to remain until they curdled. As each sample curdled, the time was recorded. The difference in the germ-content and the keeping time is the result of the difference in temperature for a period of twelve hours only, and shows what may happen easily in milk which is allowed to stand overnight without thorough cooling. Table I Effect of different temperatures for twelve hours on the growth of bacteria and on the keeping quality of milk I II Kept at 45 degrees Kept at 50 degrees Number of bacteria 9,300 Number of bacteria 18,000 Curdled in 75 hours Curdled in 72 hours III IV Kept at 55 degrees Kept at 60 degrees Number of bacteria 38,000 Number of bacteria 453.,000 Curdled in 49 hours Curdled in 43 hours V VI Kept at 70 degrees Kept at 80 degrees Number of bacteria 8,800,000 Number of bacteria 55,300.,000 Curdled in 32 hours Curdled in 28 hours 14. Milk and cream production and handling. — The following diagram shows the main sources of contamina- tion and the undesirable methods of handling by which the quality of milk and cream is impaired : MILK AND CREAM 21 Sources of contamination and undesirable methods of handling Atmosphere in the stable I Dust from feed ' Dust irom floor and beddmg On the 'farm Cows Utensils Milker Exterior of udder and flank [ Coat Dirty utensils Rusty utensils Dirty clothes Dirty hands Wetting the teats ri 1- . [ Air and dust Cooling I j^j^^y ^^^^^ Transportation from farm to creamery Creamery ■ Careless methods Transportation from creamery to ice-cream manufacturer Ice-cream manufacturer Exposed to sun and dust Carried in dirty utensils Allowing milk to stand before separating Allowing cream after separated to stand before cooling I Not cooling cream to low [ enough temperature Dirty equipment Use of dirty rusted cars. Allowing to stand on railroad platforms, in the sun uncovered Lack of can jackets Poor delivery service Lack of refrigerator cars Too long shipments Holding cream too long Lack of refrigerator space to hold cream Dirty equipment and utensils The above shows that the producer controls most of the factors which concern the sources of initial contami- nation.* After the milk leaves the producer, if it is not * Ayres, S. H., Cook, L. B., Clemner, P. W., "The four essential factors in the production of milk of low bacterial content," U. S. Dept. Agr., Bui. 642, 1918. 22 THE BOOK OF ICE-CREAM properly handled, the organisms in it may develop or if exposed to dirty conditions more contamination may take place. The important factors in the production and handling of milk are: clean utensils, clean healthy cows, Fig. 3. — Sharpies milk clarifier. Fig. 4. — De Laval milk clarifier turbine drive. small-top milk-pails, proper cooling and maintaining of low temperature, 50° F. or below. The importance of can jackets to aid in keeping the cream cold should not be overlooked, especially when shipping in hot weather. The quality^ of the milk and cream is largely determined by the time it is delivered at the ice-cream plant. 15. Clarifier. — If solid or semi-solid dirt either visible MILK AND CREAM 23 or invisible is in the milk, it can be removed by the use of a clarifier. This is a specially devised machine (Figs. 3 and 4) which takes out the dirt by centrifugal force. It is desirable to clarify milk and cream for ice-cream- making. Besides removing dirt which gets into the milk during handling, the clarifier also takes out blood cor- puscles and pus cells which are sometimes secreted with the milk. 16. The chemical composition of the milk and cream. — It is not possible here to discuss in detail the composi- tion of the milk and cream and the factors influencing it. Ross * gives the composition of milk, cream and skimmed-milk as follows: Table II Showing composition of milk Average Maximum Minimum Water 87.0 90.69 80.32 Sugar Fat Casein Albumen Ash Table III Showing composition of cream Cream high in fat Cream low in fat Water 29.0 76.6 Fat 67.5 •.15.2 Casein 5.0. ... . . 6.03.... .. 2.11 4.0..., , .. 6.47..;. . . 1.67 2.6..., . . 4.23.... .. 1.79 0.7. ... . . 1.44.... . . .25 0.7..., ... 1.21..., . . .35 .„ ( 1.2 3.1 Albumen j Sugar 2.2 4.5 Ash 0.1 0.6 * Ross, H. E., "Composition of milk and some of its products," Cornell Reading Course, Vol. 11, No. 32, 1913. 24 THE BOOK OF ICE-CREAM Table IV Showing composition of skimmed-milk Water 90.60 Fat 10 Sugar 4 . 95 Casein 3 . 15 Albumen 42 Ash 78 From the view po'nt of the ice-cream-maker, the fat and solids not fat are of special consideration. Each state has standards for milk, cream and skimmed-milk. (See Table XV.) The federal standards * are as follows: Milk is the fresh clean, lacteal secretion obtained by the complete milking of one or more healthy cows, properly fed and kept, excluding that obtained within fifteen days before and ten days after calving and contains not less than eight and one-half (8.5) per cent of solids not fat and not less than three and one-quarter (3.25) per cent of milk-fat. Skim-milk is milk from which a part or all of the cream has been removed, and contains not less than nine and one-quarter (9.25) per cent of milk solids. Cream is that portion of milk, rich in milk-fat, which rises to the surface of milk on standing, or is separated from it by centrifugal force, is fresh and clean and contains not less than eight- een (18) per cent of milk-fat. Milk and cream should be purchased on the fat test and not by measure, the price being based on the fat- content. For method of testing, see Chapter XIV. Because of the variable composition of milk and cream, it is necessary to standardize them for use in ice-cream- making. For method of standardization, see Chapter XIV. * Office of the secretary, U. S. Dept. Agr., Circ. 19, 1906. CHAPTER III MANUFACTURED MILK PRODUCTS AS RE- LATED TO ICE-CREAM Besides the milk and cream, several other manufac- tured milk products are used in ice-cream. What has been said previously about the milk and cream applies also to the milk for these products. The quality, es- pecially the flavor, is very important. CONDENSED AND EVAPORATED MILK There is a difference between condensed and evapo- rated milk, but because of their similarity, both in com- position and manufacture, they will be considered to- gether. Condensed milk usually has sugar added to preserve it, although some ice-cream-makers use it without added sugar, when it is known as plain in contrast to sweetened condensed milk. The evaporated milk is usually sterilized in sealed cans to preserve it, no sugar being added. More condensed milk is employed in mak- ing ice-cream than evaporated milk. The condensed is usually shipped to the ice-cream manufacturer in bulk, either in milk-cans or barrels. 17. Method of manufacture. — The water is removed from the milk by heating under reduced pressure. The heating is usually done in a copper pan. (Fig, 5.) This is accomplished by means of a steam jacket on the bottom and usually one or two steam coils in the pan. Before 25 26 THE BOOK OF ICE-CREAM drawing the milk into the pan, it is heated in an open copper vessel, by turning direct steam into the milk. This container is called the hot well or fore warmer. The temperature varies according to whether plain or sweet- ened condensed is being made. The sweetened is heated Fig. 5. — View of modern condensory showing hot wells, vacuum pan, vacuum pump and cooling tanks. higher to dissolve the sugar. The object of heating under reduced pressure is to reduce the boiling point. At ordi- nary pressure milk would boil at the same temperature or a little above that of water. At this temperature the milk could not be condensed without imparting a pro- nounced cooked flavor and caramelizing a part of the sugar. The vacuum in the pan is produced by means of a MANUFACTURED MILK PRODUCTS 27 vacuum pump. A vacuum equal to a column of mercury about 25 inches is usually maintained. The condenser is located at the top of the pan and is directly connected with it. As the milk boils, the vapor passes from the pan into the condenser. In the latter the vapor comes in contact with a spray of cold water which causes it to condense. The pump carries off the condensing water and the condensed vapor. When the desired density is reached, the milk is drawn from the pan and cooled. The proper concentration of the milk is determined by a special graduated scale known as the Baume. A more recent method is an electric resistance. If sweetened condensed is being made, the sugar is added to the milk, the mixture of sugar and milk are heated to dissolve the sugar before drawing them into the pan. Sometimes the milk is superheated; this consists of turning live steam into the milk just at the time that the desired concentration is reached. It gives the condensed milk more of a '4ivery" appearance, which is probably due to the precipitation of the albumen. The length of time required for condensing the milk to the desired consistency varies with the amount of milk in the pan, amount of heating surface, size and capacity of vacuum pump, and amount and temperature of water in the condenser. 18. Standards for condensed milk. — The following standards are given by the United States Department of Agriculture: * ''Sweetened condensed milk, sweetened evaporated milk, sweetened concentrated milk, is the product result- ing from the evaporation of a considerable portion of the * Office of the Secretary, U. S. Dept. Agr., Food Inspection, De- cision 170, 1917. 28 THE BOOK OF ICE-CREAM water from the whole, fresh, clean, lacteal secretion obtained by the complete milking of one or more healthy cows, properly fed and kept, excluding that obtained within fifteen days before and ten days after calving, to which sugar (sucrose) has been added. It contains, all tolerances being allowed for, not less than twenty-eight per cent (28.0 per cent) of total milk solids, and not less than eight per cent (8.0 per cent) of milk fat. "Condensed skimmed milk, evaporated skimmed milk, concentrated skimmed milk, is the product resulting from the evaporation of a considerable portion of the water from skimmed milk, and contains, all tolerances being allowed for, not less than twenty per cent (20.0 per cent) of milk solids. "Sweetened condensed skimmed milk, sweetened evap- orated skimmed milk, sweetened concentrated skimmed milk, is the product resulting from the evaporation of a considerable portion of the water from skimmed milk to which sugar (sucrose) has been added. It contains, all tolerances being allowed for, not less than twenty-eight per cent (28.0 per cent) of milk soHds." Condensed or evaporated milk should be purchased only on its composition, both fat and solids not fat. For method of testing, see Chapter XIV. 19. Conditions essential for a milk condensory.* — "First. The plant should be located in a community which is not only thoroughly adapted in every way to a high standard of extensive dairy farming, but is already far advanced in such development. The herds of cows should be large, healthy, well cared for, and of a breed or breeds that produce a grade of milk reasonably adapted * These conditions are taken from the U. S. Dept. Agr., Weekly News Letter, Vol. II, No. 45. MANUFACTURED MILK PRODUCTS 29 for* condensing purposes and the production of a standard product. ''Second. In establishing a plant for condensing milk by the vacuum process it is of primary importance that the location provide an abundant, steady supply of pure, cold water, independent of the supply required for boiler use. The quantity of water required to condense a given quantity of milk will, of course, vary with the operating conditions, such, for example, as the temperature of the condensing water and the temperature (or the pressure) of the vapor to be condensed. A general idea of the importance of water supply can be obtained from the authoritative estimate that about 3 gallons of water are required for the condensing of one pound of fresh milk (about one pint). Difficulty in obtaining an ade- quate supply of good, pure, cold water is a cause of serious embarrassment to some of the commercial condensories now established, and the lack of it has been the cause of many failures. ''Third. An abundant supply of milk is an absolute necessity. The exact quantity required daily will, of course, vary with the size of the plant. Several reliable authorities have estimated that for the profitable pro- duction of condensed milk on a commercial scale the supply of raw milk to the factory should not fall below 15,000 pounds a day. This estimate is exclusive of the daily supply of milk normally required for other purposes by the community. Furthermore, if the finished product is to be of marketable quality, the milk received at the condensory must be of exceptionally high grade; that is, clean and pure. While first-class milk is essential for the manufacture of a first-class dairy product of any kind, it is absolutely necessary if a condensed milk factory is to 30 THE BOOK OF ICE-CREAM be a success. If a few cans of low-grade milk are not detected at the receiving platform of a condensory, the slight defects in the raw milk are multiplied in the process of condensing it, and the result is practically certain to be the complete loss of the whole batch, which may represent a financial loss of several hundred dollars. This statement may be illustrated concretely: It is claimed by authorities that raw milk containing as much as 0.2 per cent acid (calculated as lactic acid) is not fit for condens- ing purposes. This does not necessarily mean that it would taste sour, but if accepted and condensed in the ratio of 2.25 to 1 (it may be more but is seldom less), the acidity, increasing in the same ratio, would reach 0.45 per cent, which would be practically certain to cause a sour taste in the finished product. Every housewife knows that sour milk will coagulate or curdle on heating, and that the higher the temperature the more rapid is the curdling process and the finer the curd. This makes it unfit for cooking purposes. In the commercial pro- duction of evaporated milk, the product must be sterilized in the cans at a very high temperature in order to insure a good keeping quality. It is obvious, therefore, that if milk is delivered to the factory with a slight excess of acidity, it would probably be impossible to sterilize the product obtained from it without producing a hard curd, which would make the product absolutely unsalable, and thus a total loss to the manufacturer. Furthermore, excessive acidity, which is principally caused by im- proper care and handling of the milk, is not the only condition that may render milk unfit for condensing. Other undesirable qualities of the milk may also be induced by poor health and improper care of the cows, by the kind and the condition of their feed, and by MANUFACTURED MILK PRODUCTS 31 many other details of imperfect management of the dairy farms. ''The services of experts thoroughly qualified by train- ing and long experience in this particular line will be required to detect and guard against these unfavorable conditions. ''Fourth. Adequate facilities for marketing constitute another essential to the commercial success of a condensed milk plant. Commercial success, of course, implies a profitable market for the product — a market which is readily and directly accessible to the plant without adding excessively to the , cost of manufacture, either in the form of high freight rates or long hauls from the condensory to a railroad. As already indicated, the successful manu- facture of condensed milk on a commercial scale requires a large output of the finished product — a very much larger output than is likely to be consumed in the local market; therefore, in selecting a location, favorable transportation facilities to a good market or markets are a consideration of vital importance to ultimate success. '' Fifth. In establishing and operating a condensory, the necessity of adequate capital is another important question. The cost of buildings and equipment will, of course, vary with the purchase of superior or inferior materials and workmanship, as well as size of the plant, and, in some measure, the kind of condensed milk to be produced. In any case, however, the buildings should . be thoroughly substantial, more so than is commonly considered necessary for a creamery or a cheese factory. The major part of the equipment is a very highly special- ized, more or less complicated, and very expensive type. The proper operation of the equipment, especially the vacuum pan, and the sterilizer when the product is steril- 32 THE BOOK OF ICE-CREAM ized in cans, calls for a high degree of skill and large experience, if serious losses are to be avoided and a stand- ardized legal product is to be produced. The cost of buildings, equipment, and operation of a plant for the manufacture of evaporated milk (unsweetened condensed milk for household use) will illustrate the capital required for the manufacture of any other form of condensed milk. Some reliable authorities have conservatively estimated that adequate buildings and equipment for a minimum production on a commercial scale would cost in the neighborhood of $25,000, exclusive of working capital. The markets for condensed milk at best are very unstable. Frequently, the manufactured product must be held several months before it is marketed. In the meantime, the plant must be kept in operation, for which a very considerable surplus capital must be provided. The same authorities estimate this item at $10,000. It there- fore appears that in establishing and operating a milk condensory, capital to the amount of at least $35,000 must be provided. That this estimate is conservative is indicated by the fact that manufacturers of condensed milk have stated that a capital of $50,000 is usually necessary to operate a condensed milk factory. "Sixth. Commercial success in any manufacturing enterprise usually requires much more than merely plac- ing the product upon the market. A demand for the product must be firmly established and a regular trade developed before success is assured. To attain such a result the new product must meet the keen competition of similar products already well established. There are many well-established brands of condensed milk now on the market. There may be room for many more, but new brands, regardless of their quality, must expect to MANUFACTURED MILK PRODUCTS 33 overcome strong competition before a firm foothold is gained. This usually requires extensive advertising and a competent, vigorous sales force, which entails a heavy expense. Good salesmanship and advertising must be continued. The necessity of a thoroughly organized seUing organization should, therefore, not be overlooked.'' 20. Supply of condensed milk for the ice-cream plant. — From the above conditions essential for a conden- sory, it is evident that an ice-cream plant would not be jus- tified in trying to operate one, unless also they maintained a large milk and cream receiving plant in the country. It is the usual practice for the ice-cream manufacturer to purchase the supply of condensed milk. However, some plants have a condensory in connection with their country plant, which is operated successfully. When the supply of condensed milk is purchased, the basis of payment should be the composition. For the methods of testing condensed milk, see Chapter XIV. MILK POWDER In certain localities, especially the South where it is hard to secure milk and cream, milk powder and butter are often emulsified or homogenized to make cream. Milk powder is also employed in the same way to meet sudden demands for cream. Milk powder is often used in ice-cream to increase the milk solids not fat and thereby give a firmer body and a smoother texture. The com- position varies in fat from skim to whole milk. 21. Standards for milk powder. — The following stand- ards are given by the United States Department of Agriculture :* * Office of the Secretary, U. S. Dept. Agr., Food Inspection De- cision 170, 1917. 34 THE BOOK OF ICE-CREAM ''Dried milk is the product resulting from the removal of water from milk, and contains, all tolerances being allowed for, not less than twenty-six per cent (26.0 per cent) of milk fat, and not more than five per cent (5.0 per cent) of moisture. ''Dried skimmed milk is the product resulting from the removal of water from skimmed milk and contains, all tolerances being allowed for, not more than five per cent (5.0 per cent) of moisture." 22o Powdered milk processes. — Two patented proc- esses of making powdered milk are in general use in this country at the present time, the Merrell-Soule and the Ekenberg. 23. Merrell-Soule powdered milk.* — "The desired process must, it was evident, be one which would not af- fect the active principles or the nutritive qualities of milk, nor change its chemical reactions in any way. The product when reaching the consumer must be, in every essential quality, fresh milk. "The methods known as condensation and evapora- tion, also the earlier milk powder processes, were efforts to achieve the desired result. But in none of them was the goal completely attained, as it is to-day in Merrell- Soule Powdered Milk — the product of a perfected process. "Liquid Milk is seven-eighths water. Merrell-Soule Powdered Milk contains approximately 2 per cent of moisture. Transportation cost is thus reduced to a very small percentage of the expense of shipping liquid milk. The fact that powdered milk may be shipped by freight, * This article is taken from the publication, ''Merrell-Soule Pow- dered Milk for the Dairy, Creamery and Ice Cream Plant," Merrell- Soule Co., Syracuse, N. Y., 1918. MANUFACTURED MILK PRODUCTS 35 while liquid milk must go by express or baggage, means an additional saving. ''The expense of shipping powdered milk is also, of course, much lower than the transportation cost of the condensed product. "The Merrell-Soule process reduces the bacteria count to a remarkably low figure, and it is a demonstrated fact that the bacteria which are to be found in the fresh-made powder tend to die off, rather than propagate, during storage. "Merrell-Soule Powdered Milk is quickly and easily dissolved in water, and the 'reconstituted' liquid milk thus obtained is pure, fresh milk, with the delicate odor and unmistakable flavor of fresh milk, and with every chemical reaction and nutritive property of fresh milk retained unchanged . " 24. History of Merrell-Soule process. — "The history of powdered milk dates back to the middle of the last century, when an inventor named Grimwade patented, in England, the first commercially usable process. "He added carbonate of soda to fresh milk, evaporated it in open-jacketed pans, with constant agitation, until a dough-like substance resulted; added cane sugar, pressed the mixture between rollers into ribbons, dried it still further, then pulverized it. "This process, cumbersome and unsatisfactory as it must have been, was in practice for some years. Other processes followed at intervals for half a century, but the real commercial development of the industry dates back only about twenty years. "It was in 1899 that a machine for the drying of milk by what has since become known as the 'double roll' process was invented by W. B. Gere, since deceased, then 36 THE BOOK OF ICE-CREAM secretary of the Merrell-Soule Co., and I. S. Merrell, first vice president of the company. But the 'dry milk^ which resulted from this process was not satisfactory, and for that reason was not put on the market by the Merrell- Soule Company. ''Several other processes were then tried out, but none proved satisfactory until Lewis C. Merrell, brother of I. S. Merrell, hit upon the spraying of milk into a regu- lated current of heated air. This gave the quality that had been desired, and the next thing was to determine the commercial value of the process. "In January, 1905, a building owned by the Merrell- Soule Company at Fayette ville, N. Y., was equipped, and powdered milk was produced, in a small way, by this spray process. Enough was marketed, and with suf- ficiently gratifying results, to warrant the company in going ahead with the enterprise. "Meantime, patents had been applied for, and the patent office had referred the Merrell-Soule Company to a United States patent granted in 1901 to Robert Stauf, of Posen, Germany, which seemed to cover the process. F. C. Soule, president of the Merrell-Soule Company, thereupon went to Germany and bought not only the United States patent held by Stauf, but also thirteen foreign patents owned by Stauf and his associates. "The wisdom of the purchase of all the patents held by the Stauf interests has since been amply demonstrated. In 1915, patent litigation which had been in the courts for three years was decided by the Court of Appeals in favor of the Merrell-Soule Company, the decision being based on this company's possession not only of its own patents, but also of the basic patents governing the spray process of powdered milk manufacture. MANUFACTURED MILK PRODUCTS 37 ''Following the success of the experiment at Fayette- ville, the construction of the first Merrell-Soule Powdered Milk factory, at Arcade, N. Y., was begun in 1906. Be- fore this factory was completed, it had been discovered that a better product could be obtained by condensing the milk in a vacuum pan before spraying. This resulted in new patents covering what was known as the Merrell- Gere process, embodying the original Stauf method and the improvement mentioned. "Since then many other improvements have been made at the Merrell-Soule plants, many other patents taken out. The first powdered milk factory, at Arcade, was followed by a second, at Little Valley, N. Y., in 1909. Since then factories have been established at Frewsburg, N. Y., Union City, Pa., Waterford, Pa., Farmersville Station, N. Y., Warsaw, N. Y., Gainesville, N. Y., Attica, N. Y., and Omaha, Neb. ''Consumption of milk has increased from 18,000 quarts per day, in 1906, at Arcade, to 300,000 quarts per day, at the present time, in the ten factories. The output of powdered milk has grown from 2,500 pounds per day, twelve years ago, to a present capacity of 50,000 pounds per day. "These products include Powdered Skimmed Milk, Butterfat Powders, of varying butterfat content, 'Cream PowderSjV which contain up to 72 per cent, butterfat, and Powdered Buttermilk.'' 25. Uses of Merrell-Soule powder in ice-cream. — " The ice-cream manufacturer demands a milk or cream prod- uct which is clean, which will not sour quickly, which is not a breeder of bacteria, and which gives him the largest percentage of milk solids in proportion both to its bulk and its cost. All these essentials he finds in Merrell- 38 THE BOOK OF ICE-CREAM Soule powdered milk. Its powdered form insures the greatest possible purity and cleanness, as is attested by many authorities. There need be no loss through sour- ing, no sticky, half-empty cans standing around, gather- ing flies and breeding bacteria, when Merrell-Soule powdered milk is used. The ice-cream man makes up just what he needs for the day's business. He can make up a big supply of cream, for a sweltering day's run, or a small amount for a cool day. A sudden drop in tem- perature will not leave him with a lot of cream on hand that must either be used or spoiled. It has been proved that Merrell-Soule powdered milk shows a far smaller bacteria count than any other form of milk, and it offers no breeding place for microbes. ''Merrell-Soule powdered milk can be put to many uses in the ice-cream factory: — ''1. In the production of milk or cream from powdered skimmed milk, butter and water. ''2. The production of skimmed milk from powder and water. "3. The standardization of the milk solids in the ice- cream batch. "4. Furnishing the necessary skimmed milk solids. ''5. Blending butter and the powdered skimmed milk with liquid whole milk of any fat content, for the com- plete total milk solids of the batch. "Other uses could be mentioned, but these will give the ice-cream maker an idea of the importance of Merrell- Soule powdered skimmed milk in his business. "Many of the large ice-cream makers are beginning to realize the losses which they incur every year through using condensed milk to raise the per cent of milk solids in their ice-cream. MANUFACTURED MILK PRODUCTS 39 "By the use of powdered skimmed milk they have an easy and accurate means of holding the solids to any desired percentage. " Merrell-Soule powdered skimmed milk does not take the place of gelatines, ice-cream powders and the like,which prevent the ice crystals in ice-cream, but it does provide the solids, not fats, which give ^body and texture' to the ice-cream and makes it smooth, velvety and palatable. '^ Almost every ice-cream maker has his own formula for his mix, which gives the best satisfaction to the trade he serves, and for this reason we will not print any ice- cream formulas. We will be glad, however, to furnish formulas which have given good results, to any ice-cream maker who applies to us. "In our own experimenting, and in practical work in some of the large ice-cream factories, we have found the powdered skimmed milk to be a wonderful help to ice- cream makers in a great many ways." 26. Ekenberg powdered milk.* — "The Ekenberg proc- ess was invented by Dr. Martin Ekenberg of Stockholm, Sweden. Dr. Ekenberg had experimented with milk drying for some years, and his father, who was an eminent chemist, also, had devoted considerable time to this problem. "The Ekenberg process is the result of these investi- gations, and the machine which Dr. Ekenberg invented, he called the Ekenberg Exsiccator. This consists of a single drum with conical shaped ends, revolving in a vacuum chamber. The milk is introduced into the cham- ber through various pipes and is sprayed into the conical or bowl shaped ends of the revolving drum, — the drum * This description was given by L. P. Bennett, president of the Ekenberg Co., Cortland, N. Y. 40 THE BOOK OF ICE-CREAM being heated by steam at a low temperature. The vac- uum maintained in the chamber, is from 25 to 27 inches, and as a result, the temperature in the chamber is low, not exceeding 100° F. "The milk upon being introduced into the bowl shaped ends is evaporated to a considerable degree and then passes off into the suction pipe of a pump, from which the milk is again introduced into the vacuum chamber, this time upon the periphery of the drum, to which it adheres, and is then removed by a series of scrapers or knives. It will be seen that the milk is only upon the drum during about two-thirds of one revolution. The dried product falls into another chamber which is separated from the main vacuum chamber by a series of air locks, so that it may be removed at will from the exsiccator, without stopping the continuous working of the machine. "When the dried product is removed, its condition is that of light fluffy flakes. It is then allowed to stand in a chamber heated to about 90° F. for about one hour, during which time, the lactose crystallizes. From this chamber it is removed, and then milled in the same man- ner as wheat is milled in the manufacture of wheat flour." 27. Uises of Ekenberg powder in ice-cream. — " Ekenflor is the trade name given to the many grades of powdered milk made from skimmed milk, partly skimmed milk, or whole milk. In using Ekenberg Powdered Milk for ice-cream it is not necessary to change the present formu- las, but only to adapt then to the use of milk in dry form. • "The raw milk from which Ekenflor is made is drawn from inspected dairies and is manufactured in clean sanitary factories and is therefore of the finest quality. "Ekenflor does not sour or draw flies, and its use by the ice-cream maker can not fail to reduce the chance of MANUFACTURED MILK PRODUCTS 41 unsanitary conditions in his factory and his losses from spoiled milk. ^' There is always 'sl feast or a famine' in the raw-milk market, and as our powdered skimmed milk keeps almost indefinitely without cold storage, it is always ready for immediate use, no matter how sudden or great the de- mand may be. Its use makes the ice-cream manufac- turer independent of his local supply of milk or cream or condensed milk and of the local prices." 28. Butter. — ^For the making of emulsified or homo- genized cream, butter is ordinarily employed to supply the milk-fat. Unsalted butter that is clean flavored and made from clean cream is to be desired. If the butter is produced from inferior cream or has any undesirable flavor, the cream made from it will have the same undesirable flavor. It is the usual practice to store the butter during the period of low prices,' which is commonly the summer, and then to use it when prices are high, usually the winter. The question of the kind of butter and method of storage is a very vital one. It is generally considered that sweet cream butter holds better in storage. The temperature of storage should be as near 0° F. as possible. The successful storing of buttei; requires an intimate knowledge both of market conditions and the desired quality of butter for storage. The daily prices and move- ments of butter, in and out of storage, and the daily receipts in the different markets and the sales, may be obtained from the daily and weekly reports made by the Bureau of Markets, United States Department of Agri- culture. In New York City, the market reports are also made in the ''Price Current," published by the Urner Barry Company. Before storing butter, these reports 42 THE BOOK OF ICE-CREAM should be studied carefully, to make sure that the market conditions will warrant storage. The quality of the butter can be determined by the market grades or by the actual examining by an expert butter judge. Usually when the ice-cream manufacturer purchases butter for storage, the quality will be determined by the market grade, as personal examination is seldom possible. CHAPTER IV SUGAR, CHOCOLATE PRODUCTS, FRUITS, STABILIZERS AND FILLERS Besides the milk products, a number of other materials are used in ice-cream. These are embodied in small amounts but their quality is of vital importance. For this reason they are briefly discussed. 29. Sugar. — For sweetening the ice-cream, granulated sugar is usually employed. This may be either cane- or beet-sugar, and should be free from all visible dirt. Sugar seems to contain many mold spores and so should be examined to determine the presence of mold or bac- teria. However, during the war, in order to conserve the supply of granulated sugar, various substitutes were used, such as corn sirup, invert sugar, honey and maple sirup. 30. Invert sugar. — Ruehe * gives the following direc- tions for making invert sugar: ''Cane sugar (or beet sugar) can be inverted by the simple process of heating in the presence of an acid. The chemical reaction that takes place results in the same products being formed as are formed when the sugar (sucrose) is taken into the human body, the sugar forming equal parts of dextrose and levulose. The following formula may be used in making invert sugar syrup of * Ruehe, H. A., " Conserving sugar in ice cream manufacture," El. Exp. Sta. Circ. 219, 1918. 43 44 THE BOOK OF ICE-CREAM such sweetness that a pound of the syrup will replace a pound of sugar: 100 pounds of sugar 44 pounds of water 50 grams of powdered tartaric acid These ingredients are mixed together and boiled for 30 to 35 minutes. If boiled longer than 35 minutes, the syrup darkens in color and a flavor develops which tends to make the syrup resemble glucose syrup, and this is somewhat undesirable. This solution boils at a tem- perature of about 221 degrees Fahrenheit. A steam pressure kettle can be used very satisfactorily or an open candy kettle over a steady fire may be used. If the solu- tion is boiled too vigorously, there will be too large a loss by evaporation. Ordinarily the loss will be from 3 to 5 per cent. "The above formula should make 140 pounds of syrup, and if there is considerable loss due to evaporation, the syrup can be brought up to this weight by the addition of water. The resultant invert sugar syrup is not unlike strained honey in appearance and taste. It contains about 71.4 per cent of sugar and it tastes considerably sweeter than a sugar syrup of the same strength. It does not crystallize, and it mixes readily with the ingredients of the ice cream. It can be used in the same proportions as sugar, the amount necessary for ten gallons of ice cream being 6.5 to 7 pounds. It gives very satisfactory results in freezing and a pleasant flavor in the finished product. "It can be readily seen that by using the above method the sugar supply can literally be stretched, for with only 71.4 per cent as much sugar as is now being used in ice cream, the same degree of sweetness can be obtained." SUGAR, CHOCOLATE PRODUCTS, ETC. 45 31. Sugar-saving substitutes. — Frandsen,* while work- ing on sugar-saving substitutes, reached tlie following conclusions: '^1. Four formulas have been worked out which save from 30 per cent to 50 per cent of cane sugar in the mix : I. 44 lbs. 17 per cent cream 4 lbs. cane sugar 1% lbs. corn syrup (glucose) 4 oz. vanilla 4 oz. gelatine II. 44 lbs. 17 per cent cream 2.9 lbs. cane sugar 2 . 9 lbs. corn syrup 4 oz. vanilla 4 oz. gelatine III. 44 lbs. 17 per cent cream 13^ lbs. cane sugar 43^ lbs. invert sugar 4 oz. vanilla 4 oz. gelatine IV. 44 lbs. 17 per cent cream 13^ lbs. corn syrup 13^ lbs. invert sugar 234 lbs. cane sugar 4 oz. gelatine 4 oz. vanilla ''2. The ice cream prepared according to these four formulas meets the requirements of good ice cream. ''3. Corn syrup dissolves with difficulty in cold cream. When added to cream before pasteurizing, it dissolves readily. "4:. In hydrolyzing the syrups, excessive heating should be avoided. * Frandsen, J. H., Rovner, J. W., and Luithly, John, "Sugar-saving substitutes in ice cream," Neb. Exp. Sta., Bui. 168, 1918. 46 THE BOOK OF ICE-CREAM "5. When invert sugar and corn syrup are used as the only source of sweetening, a rather noticeable syrupy flavor is imparted to the ice cream. "6. When invert sugar, cane sugar and corn syrup are used in the proportions indicated in Formula No. 4, no objectionable flavor is noticeable. ''7. It is thought that hydrolyzing corn syrup in the presence of an acid will enhance its sweetening properties. '^8. In addition to saving cane siigar, all four formulas lower the cost of sweetening per gallon of ice cream. "9. Corn sugar can replace 50 per cent of cane sugar in the mix. ''10. None of the substitutes so far tried will satis- factorily replace all the cane sugar in the ice cream mix." 32. Cocoa and cocoa products. — The various choco- late and cocoa preparations are manufactured from the bean of the tree Theohroma Cacao, of the family of Ster- culiacese. This tree averages 13 feet in height, and its main trunk is from 5 to 8 inches in diameter. It is a native of the American tropics, being especially abundant and growing under best conditions in Mexico, Central America, Brazil and the West Indies. The cocoa beans of commerce are derived chiefly from Ariba, Bahia, Caracas, Cayenne, Ceylon, Guatemala, Haiti, Java, Machala, Maracaibo, St. Domingo, Surinam and Trinidad. Besides these, the Seychelles and Mar- tinique furnish a small amount. The plant seeds, or beans, grow in pods, varying in length from 23 to 30 centimeters, and are from 10 to 15 centimeters in diameter. The beans, which are about the size -of almonds, are closely packed together in the pod. Their color when fresh is white, but they turn brown on drying. SUGAR, CHOCOLATE PRODUCTS, ETC. 47 The gathered pods are first cut open, and the seeds removed to undergo the process of "sweating" or fer- menting, which is conducted either in boxes or in holes made in the ground. This process requires great care and attention, as on it depends largely the flavor of the seed. The sweating operation usually takes two days, after which the seeds are dried in the sun until they assume their characteristic warm red color, and in this form are shipped into our markets. 33. Manufacture of chocolate and cocoa. — For the production of chocolate and cocoa, the beans are cleaned and carefully roasted, during which process the flavor is more carefully developed, and the thin, paper-like shell which surrounds the seed is loosened and is very readily removed. The roasted seeds are crushed, and the shells, which are separated . by winnowing, form a low-priced product, from which an infusion may be made having a taste and flavor much resembling chocolate. The crushed fragments of the kernel or seed proper are called cocoa nibs, and for the preparation of chocolate they are finely ground into a paste and run into molds, either directly or after being mixed with sugar and vanilla extract or spices, according to whether plain or sweet chocolate is the end product. For making cocoa, however, a portion of the oilor fat known as the cocoa butter is first removed, by subjecting the ground seed fragments to hydraulic pressure, usually between heated plates, after which the pressed mass is reduced to a very fine powder, either directly or by treat- ment with ammonia or alkalies, to render the product more soluble. It is held that the large amount of fat contained in the cocoa seeds (varying from 40 to 54 per cent) is difficult of digestion to many, such as invalids 48 THE BOOK OF ICE-CREAM and children, and hence the desirabihty of removing part of the fat. 34. Composition of cocoa products. — The chief con- stituents of the raw cocoa bean, named in the order of their relative amount, are fa|}, protein, starch, water, crude fiber, ash^ theobromine, gum and tannin. In the roasting there is reason to believe a volatile substance is developed much in the nature of an essential oil, which gives to the product its peculiar flavor, and is somewhat analogous to the caffeol of coffee. Tannin, the astringent principle of cocoa, exists as such in the raw bean, but rapidly becomes oxidized to form cocoa red, to which the color of cocoa is due. 35. Adulteration of cocoa products and standards of purity. — The following are the United States standards: '^ Standard chocolate should contain not more than 3 per cent of ash insoluble in water, 3.5 per cent of crude fiber, and 9 per cent of starch, nor less than 45 per cent of cocoa fat. "Standard sweet chocolate and standard chocolate coating are plain chocolate mixed with sugar (sucrose), with or without the addition of cocoa butter, spices, or other flavoring material, containing in the sugar and fat-free residue no higher percentage of either ash, fiber or starch than is found in the sugar and fat-free residue of plain chocolate. ''Standard cocoa should contain percentages of ash, crude fiber, and starch corresponding to those of plain chocolate, after correcting for fat removed. ''Standard sweet cocoa is cocoa mixed with sugar (su- crose) containing not more than 60 per cent of sugar, and in the sugar and fat-free residue no higher percentage of either ash, crude fiber, or starch than is found in the sugar and fat-free residue of plain chocolate. SUGAR, CHOCOLATE PRODUCTS, ETC. 49 ''The removal of fat, or the addition of sugar beyond the above prescribed hmits, or the addition of foreign fats, foreign starches, or other foreign substances, con- stitutes adulteration, unless plainly stated on the label. ''The most common adulterants of cocoa are sugar and various starches, especially those of wheat, corn and arrowroot. Starch is sometimes added for the alleged purpose of diluting the cocoa fat, instead of removing the latter by pressure, thus, it is claimed, rendering the cocoa more digestible and more nutritious. Unless its presence is announced on the label of the package, starch should be considered as an adulterant. Cocoa shells are also commonly employed as a substitute for, or an adulter- ant of, cocoa. Other foreign substances found in cocoa are sand and ground wood fibre of various kinds. Iron oxide is occasionally used as a coloring matter, especially in cheap varieties. "Such adulterants as the starches and cocoa shells are best detected by the microscope. The presence of any considerable admixture of sugar is made apparent by the taste. Mineral adulterants are sought for in the ash." 36. Chocolate sirup. — Ice-cream may be flavored by pouring a chocolate sirup over it. The following ma- terials are used in making the sirup : Powdered cocoa, 1 pound Sodium chloride, 6^ drams Granulated sugar, 16 pounds Shredded gelatine, 23^2 ounces Vanilla extract, 2^ ounces Dissolve the gelatine in 10 pints of cold water, heat to the boiling point, then add 15 pounds granulated sugar, stirring occasionally until dissolved. Triturate 1 pound granulated sugar with the powdered cocoa and 50 THE BOOK OF ICE-CREAM sodium chloride until thoroughly mixed, then add to the hot solution; boil for ten minutes, stirring constantly; strain while hot and when cool, add the vanilla. 37. Fruits. — Many different fruits may be used to flavor ice-cream. The principal ones are pineapple, cherry, strawberry, raspberry, lemon, orange, peaches, and the like. In their season, the fresh ripe fruit is used as a flavoring. For the period when the fresh fruit cannot be obtained, the fruit may be canned, preserved without chemicals, preserved with chemicals, or dried. Only fresh ripe fruits should be employed, whether used fresh or held in some manner; since for ice-cream-making the fruit must be broken into small pieces, it is often cheaper to obtain from canneries small fruits or broken or crushed pieces. In some of the large ice-cream plants the fruits are preserved in large jars (Fig. 6) by the addition of sugar and kept cold but not frozen. Fruits preserved in this way give the product a flavor similar to fresh fruits. Fruit extracts may be derived from the fruit, by frac- tional distillation in dilute alcohol. These extracts should not be confused with artificial or imitation flavors. The latter are often coal tar ethers or esters. In order to obtain the desired flavor, it is usually necessary to com- bine fruit extracts with the canned and preserved fruits. 38. Nuts. — Only sound non-rancid nuts should be employed to flavor ice-cream. For flavoring, the nut meats should be blanched by soaking in hot water, and then removing the outer coating or covering; these blanched nuts should then be ground. Often broken nuts can be secured cheaply. A flavoring extract may be made from the nuts. In many respects this is desirable because a more pronounced flavor is obtained. For example, SUGAR, CHOCOLATE PRODUCTS, ETC. 31 pistachio nuts give a very weak extract. It is the custom to use pistachio flavoring and color the ice-cream green. 39. Stabilizers and fillers. — If ice-cream is not con- sumed as soon as made, ice crystals will begin to form unless some stabilizer is used. This is a substance added to ice-cream to prevent the formation of ice crystals which cause a grainy bodied product. Stabilizers are Fig. 6. — Fruit storage in large ice-cream plant. sometimes known as '^ holders" or '^colloids" and com- monly as '^binders." A ^^ filler" is some substance added to the ice-cream to cheapen it, usually to replace the milk-fat and milk solids not fat. A "filler" may serve the purpose of a ''binder" or a "stabilizer," but a stabil- izer cannot take the place of a "filler." The common stabilizers are gelatine and gum tragacanth. The com- mon fillers are the various starches, such as cornstarch, rice fiour, arrowroot, wheat flour, eggs, an excess of gelatine and the like. 52 THE BOOK OF ICE-CREAM 40. Gelatine. — Commercial gelatine is an animal product made from bones, hides, skins, tendons, horn piths, tannery trimmings and any kind of connective tissue from the animal's body. Pure gelatine is an amor- phous, more or less transparent substance of vitreous appearance. It is brittle when dry, free from color, taste and smell. Gelatine and glue are manufactured from the same materials, more care being used in making gelatine. The detail process of making gelatine varies in the different factories, but the general steps are as follows: Treating and cleaning the raw material; dissolving gela- tine; concentrating; chilling and spreading; drying; finishing; including grinding and packing. Gelatine is put on the market in sheet, flake, shredded and powdered form. If made from clean materials, no objection can be raised against its use as a food. Gelatine swells in cold water, absorbing five to ten times its weight of water. This is sufficient water to dissolve it at a temperature of 85° F. to 90° F. The strength or gelatinizing power of different samples of gelatine varies within wide limits. The following is a simple method to compare different gelatines: Take ten grams of the sample and soak over night in 100 cubic centimeters of cold water. The next morning dissolve the gelatine at a temperature of 80° C. First note the odor. It should not be pronounced or disagreeable. Determine length of time it takes for a 50 cubic centimeter pipette full to run out. Note the time it takes to gelatinize. Test the strength with a jelly tester which is a simple arrangement to deter- mine the -weight necessary to force a plunger into the gelatine. 41. Preparing gelatine for use in the ice-cream. — In SUGAR, CHOCOLATE PRODUCTS, ETC. 53 order to utilize gelatine in ice-cream, it must be brought into solution. A steam-jacketed copper kettle is usually employed for heating the gelatine (Fig. 7). If a smaller quantity is taken or a special gelatine cooker is not avail- able, a double boiler or a can set in water can be used. Whatever utensil is selected to cook the gelatine, it should be kept clean. In many ice-cream factories, the gelatine cooker is badly neglected. Before the gelatine is heated, it should be soaked in cold water. One pound of gelatine should be put into about eight quarts of water. Some prefer to use milk instead of water. The gela- tine should be stirred into the water rather than the water poured on to the gelatine. This will to a large extent eliminate the formation of lumps which would require excessive heating to break them down. The gelatine should be soaked from twenty to thirty min- utes in cold water before the heat is applied. This soaked or soft gelatine should then be placed in a water-jacketed heater and heated to a temperature of 165° F. to 170° F. In case the gelatine is soaked in milk, it should not be heated above 145° F. A higher temperature is very liable to give it a cooked or scorched 'flavor. At this lower tern- Fig. 7. — Steam-jacketed kettle for heating gelatine. 54 THE BOOK OF ICE-CREAM perature, it is advisable to hold it ten or fifteen minuses to make sure that the gelatine is all broken down. It is nec- essary to heat the gelatine to the temperature mentioned above to secure the best results. The eye cannot deter- mine when the gelatine is all broken down. There is dan- ger of over-heating; it should not be held at high tempera- ture for long periods of time nor allowed to boil. In put- ting the gelatine into the mix, it should be done at the above mentioned temperatures for dissolving; not all at one time, but poured in slowly and with as rapid agitation of the mix as possible, and it will distribute itself more evenly before it has time to congeal. A good gelatine will jelly at a temperature of 85° to 90°, according to the pro- portions used; so that when pouring gelatine into a mix with a temperature probably of 45° or 50°, it is very liable to harden and make the ice-cream lumpy. 42. Gum tragacanth. — This is a compound gum ob- tained from a shrub, a species of Astragalus. In July or August the leaves are stripped from the shrub and a hole made in the bark. The shape of the hole regulates the form of the gum, a longitudinal cut making the leaf or flake form, a puncture the thread form, and an irregular hole a knob-like mass. The gum is gathered by the natives. Dry weather gives a whitish colored gum which is best; wet and dusty weather give an inferior yellowish gum. Gum tragacanth will absorb fifty times its weight of water. For use in ice-cream, the gum is soaked in water, one ounce of gum absorbing two quarts of water. At least twenty-four hours should be allowed for this ab- sorption. Before being put in the ice-cream, the mixture should be strained to remove any lumps. If it is not all to be used as soon as soaked, a gum stock may be pre- SUGAR, CHOCOLATE PRODUCTS, ETC. 55 pared by adding sugar at the rate of two pounds for each quart of water. This will act as a preservative. Gum tragacanth is odorless and tasteless. Just how it acts as a binder is not known. 43. Other substances used as binders. — Two plants, Irish and Iceland moss, are sometimes used as binders. The former is a sort of algse and the latter a lichen. They are both very low in food value. 44. Eggs. — In some kinds of ice-cream, eggs are neces- sary to give the characteristic body and texture. When eggs are employed, it is usually as a filler, since it is possi- ble to reduce the percentage of either the Inilk-fat or milk solids not fat or both. The usual practice is to separate the yolks and whites of the eggs. The yolks are cooked with the cream if used and the whites beaten and added just before the ice-cream is frozen. Eggs usually give ice-cream a smooth texture and a firm body. They also impart a characteristic flavor. 45. Starchy fillers. — Several starchy substances, such as cornstarch, rice flour, arrowroot and wheat flour, are sometimes used in large quantities and so become fillers. They give a characteristic starchy flavor to the ice- cream. They are often employed to cheapen the prod- uct. The starches are ordinarily cooked before using but sometimes are mixed with the sugar and used with- out cooking. 46. Prepared ice-cream powders.— A large number of prepared substances, both powders and liquids, is on the market. These are often used in the place of some other binder. They may contain any or all of the materi- als previously mentioned, and in addition they often contain sugar to give both bulk and weight. These powders are usually added to the ice-cream by mixing 56 THE BOOK OF ICE-CREAM with the sugar. Many times, in proportion to the results obtained, they are found to be expensive. 47. Rennet. — Another binder is some form of rennet. Its use is not common and is ordinarily in combination with other materials. CHAPTER V FLAVORING EXTRACTS* Because of the distinct taste which the flavoring ex- tract imparts to the ice-cream, it is important that it be of good quahty. The vanilla extract is most common, but lemon, orange, pistachio, almond, various fruit, and others are used to some extent. Flavoring extracts are prepared commonly by grinding or chopping the sources of their various flavors and steep- ing or dissolving them in alcohol; or by distilling them, wholly or fractionally; or, when necessary for any reason, simulating them by chemistry, or by the use of a flavor source to all intents the same as the original. VANILLA EXTEACT Extract of vanilla, properly made, is the pure essence of the vaniUa bean, dissolved in alcohol. Although there are fifty or more kinds of vanilla plant, the only one with a fruit suitable for use in flavoring extract is Vanilla planifolia, so called by botanists for its flat leaves. It is a native of the valley of Mazantla, in Vera Cruz, Mexico, seemingly the only place where conditions of soil and climate suffice to bring it to its highest point of cultivation. The other vanillas, native to various parts of Spanish America, are fit only for use * This article on flavoring extracts is furnished by the Joseph Bur- nett Extract Co., Boston, Mass. 57 58 THE BOOK OF ICE-CREAM in perfumery and soap, because, though aromatic, they are rank in taste. 48. Nature of vanilla plant. — The plant of vanilla is an orchid, having roots in the air as well as in the ground. It clings to trees or frames, twining around them as it grows, and favors most a light, loose soil, well drained, with '^ quilted sunshine and leaf -shade," a con- dition naturally brought about by the foliage of the protecting trees. In Mexico it is grown from cuttings set out in the forest, one to a tree; this support, together with 70 to 90 degrees of continued heat, frequent rains, and a final dry season being needful to its best growth. Frost is deadly, and in too close planting disease is likely to ravage the crop. After eighteen months, the vine is clipped to check its growing until it bursts into flower, which occurs in Sep- tember. The stem of the vanilla is thick and round, the leaves large, smooth and pointed, the flower beautiful, much resembling the tuberose, and delightfully fragrant. Formerly the blossoms were fertilized by a small bee, which carried the pollen from one to another, for the plant is of two sexes. At present this is done by hand — a better way, inasmuch as only the best flowers need be fertilized, the plant thereby keeping vigorous and healthy. Artificial pollenizing developed from transplanting vanilla in the island of Reunion, where the crops originally failed for lack of insects to carry the pollen. Following each blossom comes a small pod, but most of these pods fall off. The remaining ones mature in about six weeks, growing in bunches of six to ten, and resembling bananas, being five to ten inches long, yellow green, and banana-like in shape. They are watery and tasteless, without the pleasant aroma of vanilla, the FLAVORING EXTRACTS 59 well-known taste and smell of which must be brought out by curing. If left on the vine, they ripen slowly, but usually they are picked before they ripen, as otherwise they split in curing. When this happens they are known to the trade as "splits," and are considered undesirable on account of their full and heavy flavor. 49. Curing vanilla beans. — After picking, the Maz- antla beans are transported to Papantla, the largest town in the valley, to be cured. The process is laborious, and although somewhat primitive, very simple. The beans are exposed on frames to the sun by day and by night are wrapped in blankets under cover. This continues, in fair weather, for about a month; then the beans are dried indoors for forty days more, until they turn a deep rich brown in color, and become delightful to the smell. If the weather is wet, they are moistened, blanketed, and heated in ovens, the heat being moderate and varied with the size of the beans; after which they are by turns exposed to the air and heat until cured. The sun drying is preferred, as it gives the beans better keep- ing quahties. Such is the process in effect, but in fact each bean is treated separately; for proper curing, to bring out the desired fine qualities of taste and smell, is of the utmost moment; and only native judgment, or the skill born of long handling, ever gives the real adroitness. Badly cured beans lack any stable taste or smell, and are likely to become moldy. Their use in trade is made possible, in this case, by scraping and chopping them up with poor and broken beans and those that fell early from the vines; then they are sold under the name of "Mexican cuts," chiefly to manufacturers of cheap ex- tracts. 50. Marketing vanilla beans. — The long fine beans, 60 THE BOOK OF ICE-CREAM resembling thin cigars, are molded, pulled, and' tied in bundles of 100 to 150, varying in length from six to eleven inches, and in weight from twelve to twenty-four ounces. The bundles are packed forty to a tin, and shipped four tins to a case in sweet-smelling cedar boxes. The entire Mexican output is consigned to the United States, where it brings from seven to ten dollars a pound. The Aztecs knew the properties of vanilla, and are said to have called the plant thilxochitl. They used the bean in making chocolate, through which it became familiar to their Spanish conquerors, and thus to Europe. The name vanilla is derived from the Spanish word vaina, meaning sheath or pod, and the suffix -ilia, little. The use of vanilla in chocolate was its only notable one for many years, although during that time great medical properties were claimed for it. It was not until the eight- eenth century that some person now unknown discovered its general utility for flavoring. 51. Production of vanilla beans. — Vanilla cultivation in Mexico was in the hands of the Indians for centuries, but in 1896 the government, claiming they had no title, drove them off and sold the land to Greeks, who now control the industry there. Almost every European power has tried to grow vanilla in the tropics, outside of Mexico. Many of the early trials were failures; none has been a complete success, at least in so far as rivaling the fine quality of the Mexican product is concerned. Cuttings were transplanted in the island of Reunion and grown by artificial pollenizing, as has been^aid, but the resulting beans were not as good as the parent beans of Mexico. Reunion was formerly known as Bourbon Monarchy, but the French, who had FLAVORING EXTRACTS 61 every reason to hate the name, rechristened the island; the beans, notwithstanding, are still called Bourbon beans. Vanilla grows in Reunion much as it does in Mexico, ex- cept that it takes longer to develop. The great difference is in the curing, for there, owing to the climate, the sun treatment is inexpedient. The beans, placed in baskets, are plunged into hot water for about twenty seconds, drawn out to drain for as many minutes, and then wrapped in blankets to be sunned during the warm hours for five to eight days. They are housed at night as in Mexico, but drying is also hastened chemically with chloride of calcium (the basis of lime). After curing, the beans are straightened, graded by size, smell, and soundness, bundled and packed in tins which weigh, when ready for export, from ten to twenty pounds each. Tahiti exports a particularly inferior quality of beans. They are grown from Mexican or Bourbon slips, but the change of soil and climate imbues them with an unmis- takable rankness, to which, up to within a few years, were added careless growing and packing, in nowise im- proving them. Although inspection by the French colo- nial government has somewhat bettered the care of these beans, their flavor is probably unchangeable. Tahiti beans are all shipped to the United States, whence those not used are reshipped to Europe. They are sorted here into three grades: pink label, best; white, fair; green, poor; but the only real difference is their length and appearance. A small crop of beans grown from Mexican slips is raised in the island of Guadeloupe; they are known to the trade as "South Americans," and are of low quality, without the finer characteristics of good vanilla. 62 THE BOOK OF ICE-CREAM The average world's production of vanilla is as follows: Mexican: Whole beans .240,000 pounds Cuts 80,000 " Bourbon: (From aU sources) 700,000 " Tahiti ■ 450,000 " South American 25,000 " Total 1,495,000 II 52. The ingredients of vanilla extract. — Vanilla beans, glycerine, sugar and alcohol are the only ingredients requisite or advisable in a vanilla extract; consequently the excellence of such an extract rests in the quality of the beans and of the alcohol employed, and in the means and skill devoted to employing them. The process at its best is chopping or grinding the beans and treating them with dilute alcohol of 20 to 70 per cent strength, in the proportion of one part of the bean to ten parts of the liquid, the alcohol acting as a solvent. The old-fashioned and as yet unequaled way is to treat the beans by steeping and dissolve out the soluble matter. The chopped beans are placed in a cask and the dilute alcohol poured over them; they are then left to soak for one to twelve weeks, when the extract is drawn off and the sugar added to it, and it is either bottled immediately or aged. Aging greatly improves it, but few manufacturers care to assume the added cost. Another method of obtaining the extract is by distilla- tion; that is, by evaporating and condensing the liquid in which the beans have been steeped. There is also a machine which effects the result more rapidly by pump- ing the liquid steadily through the chopped beans, at an even temperature. Many other means are also employed. FLAVORING EXTRACTS 63 They are all cheaper than the old-fashioned way, but have nothing to recommend them from the consumer's point of view. Distillation, for example, might ruin the delicate flavor of choice Mexican beans; while no process would ever impart one to Bourbons or Tahitis. 53. The chemistry of vanilla. — Given the highest grade of Mexican beans and pure cologne spirit — the trade name for doubly distilled alcohol — with the old- fashioned method of compounding them, and there re- mains to vanilla extract-making only the knowledge and skill available in the process. These, however, are far from comprising the whole secret of success. Although seemingly a matter of chemistry, extract-making has always been a stumbling-block to the chemist. Chemi- cally, there is no difference between the richest Mexican beans and the wretchedest Tahitis, but to even a normal nose the difference is striking and immediate. There is still much to be learned about the chemistry of vanilla. Its flavor is known to be due to natural vanil- lin, the chief flavoring principle of the plant, and to certain gums and resins, but of these last next to nothing is known. Yet if aptitude and experience still play the leading part in well-made extracts, chemistry without question takes the center of the stage in the adulterated ones. Under the present law (1913), an extract may be sold as "extract of pure vanilla" if it is made of genuine vanilla beans; consequently "Mexican cuts,'' "splits," and rank Tahitis can be and are sold under this label; whereas some extracts, though strictly speaking not adulterated, are really worse than some adulterated ones. These "cheap vanillas" are made possible by the difference in cost between fine Mexican beans and poor defective ones, 64 THE BOOK OF ICE-CREAM or beans of other growth; a matter, as a rule, of four or five dollars a pound; and are readily exposed by a com- parative test in cookery or on the tongue. 54. Adulteration of vanilla extract. — ^A common adul- terant of cheap vanillas is artificial coumarin. Real coumarin is an aromatic crystalline substance found in the Tonka bean or cumaru. Tonka beans were formerly rampant in imitation vanillas, but their present high price, due to their use in cheap tobacco, has practically curtailed this activity. The Tonka, with its real cou- marin, was bad enough — ^the theory has even advanced that hayfever is due to the presence in the air of coumarin from plants — but artificial coumarin, as flavoring, is worse. It is a powerful drug; a coal tar product, heart depressant and active poison. Artificial vanillin produced by chemistry also is em- ployed plentifully, not only in substitution but also for strengthening weak pure extracts. The real vanillin is one of the odorous principles of the vanilla bean, taking the form of tiny crystalline needles of hot bitter taste. It is imitated chemically by combining oxygen and eiigenol, a colorless compound from oil of cloves, of bay, of cinnamon leaves, or of allspice; or by coniferin, a com- pound ether obtained from wood. Lacking the necessary gums and resins, it does not taste like real vanilla, and needless to say, its composition is not such as to inspire confidence. Coumarin and vanillin are ordinarily used together in adulterating; the mixture is then sweetened and artificially colored, with prune juice added. This sometimes brings a substantial profit of 150 per cent to its manufacturer. Fortunately detection of these subterfuges by simple means is not difficult. A suspected extract can be tested FLAVORING EXTRACTS 65 by holding a tablespoon of it over a lamp or other flame until about two-thirds of the liquid has evaporated; then, if on adding water to the remaining third until the spoon is full, the extract remains clear, undoubtedly it is not vanilla but an artificial product. Taste and smell, if one is familiar with true vanilla, are often test enough; cou- marin in particular can be recognized by its odor, which is like that of Indian grass or ''wood grass." The best test for the quality of vanilla is to pour a few drops on a lump of sugar, and then suck the extract through the lump. To determine the relative values of two or more extracts, a separate lump should be used for each. The distinction between good and bad will then be marked sharply. Finally, to avoid adulteirated ex- tracts, the label should be read carefully. LEMON AND ORANGE EXTRACTS Owing to its refreshing aroma, convenience in use, and low cost, lemon extract holds popular favor as second to vanilla. Extract of lemon is made by dissolving lemon oil, chiefly from skin of the fruit, in alcohol. To conform to the government standard, the compound must contain at least 5 per cent of the oil. The world's yearly yield of lemon oil is about two million pounds, of which southern Italy and Sicily pro- duce the most, although there is some output from France and Spain. The best is shipped from Messina. 55. Preparation of lemon oil. — ^Lemon trees flower in the summer, and the fruit is picked from November to February. As the oil from the later fruit has the richer color, many makers prefer it, but the earlier oil has the finer flavor. 66 THE BOOK OF ICE-CREAM Lemon oil is extracted most satisfactorily by washing and paring the lemon skin so that it comes off in one piece, and then pressing it against a clean sponge. The sponge absorbs the oil, and when full is squeezed into a container from which the oil is filtered and packed in sealed copper vessels, holding either ten or twenty-five pounds, for shipment. In France the fruit is sometimes rolled about in vessels driven full of spikes, the oil running into a receptacle below. Another method is to press the whole fruit in a large vat, add water, and distill the resulting mixture. This has been tried in California, although without suc- cess, since the oil thus secured is very bitter, tasting strongly of turpentine. 56. The chemistry of lemon oil. — The oil is known to contain a large amount of terpenes or principles chem- ically hke turpentine, which would account for such a taste or smell in a poor or stale product. These, with 6 to 10 per cent of citral, the chief flavor-giving constit- uent of lemon oil, would seem to identify the peculiar lemon taste; although there are certain unknown esters, or compound ethers, corresponding to the salts in met- als, which also are taken to be factors of it. Citral is found in exactly the same form in limes, mandarins, and oranges. Adulteration of lemon extract consists usually in either lowering the required amount of oil, or using in place of it citral, oil of lemon-grass, or some other natural oil containing citral. These substitutes naturally fail to give the true flavor, because they are lacking in terpenes, and presumably in the esters just mentioned. Many makers, to weaken the extract, lessen the alcohol; this indicates that their product cannot be made of lemon oil, FLAVORING EXTRACTS 67 because this will not dissolve in dilute alcohol. In most cases, weakened extracts are made of citral. Terpenless lemon and orange extracts are made from lemon and orange oils from which the terpenes have been removed. They are much in favor among makers of low- grade flavors because they are soluble in very weak alco- hol, and because considerably less oil is needed to make the extract. On account of the removal of the terpenes, the flavor is of course quite different from that of the true oils. Using stale lemon oil in extract is not against the law, but no one is likely to buy more than once a product so compounded, for its foul taste of turpentine will ruin any cooking in which the extract is used. To test lemon extract a little should be poured from the bottle, the cork replaced, and the bottle shaken for a few seconds. If the bubbles disappear at once, there is no water in the extract, and it is probably pure. If they disappear slowly, there is water in it, and the extract can contain no lemon oil. Or a teaspoonful of the extract may be added to a glass of water; if small drops of oil come to the surface, and the water, on standing, becomes cloudy, the extract is probably pure. But if the extract dissolves immediately, leaving the water clear, it is not pure, and contains no lemon oil. No adulterated extract of any kind is really cheap. It is an actual fact that in a test of an adulterated lemon extract against a pure one costing twice as much, the pure one at but double the cost was found to be ten times as strong, in addition, of course, to its having by far the better flavor. 57. Orange extract. — Like lemon, orange extract must contain at least 5 per cent of the fruit oil. The only 68 THE BOOK OF ICE-CREAM chemical difference between orange and lemon oil is that the former has an infinitely small proportion of flavoring esters not found in lemon. The two fruits are grown in the same countries and in the same way, the methods of producing the two oils are identical, and the tests for the adulteration of the one extract hold good for the other. 58. Fruit extracts. — Raspberry, strawberry, cherry, apple, pineapple, banana, and other familiar fruit flavors constitute a class of flavoring extracts similar in character and similarly made. They can be derived from their respective fruits, although previous to 1911 this was thought impossible. Up to that time, imitation extracts had been compounded chemically from coal tar ethers and esters, and ether was added often to give them pungency. They all tasted alike and none of them tasted like any fruit. One difficulty in making real fruit extracts was the lack of the essential oils in the several fruits; another, the change brought about in the delicate esters, the cause of the flavor, by cooking, since great heat destroys them. Pure fruit extracts are in every way immeasurably su- perior to the old unwholesome and unhealthful ether preparations, of which purchasers should beware. Fruit flavors labeled artificial or imitation are of the type; if not labeled, they can be detected by the odor of ether rising when the cork is drawn. CHAPTER VI CLASSIFICATION OF ICE-CREAMS Because of the large variety of materials used and the different methods of blending and preparing them, it is desirable to have a classification of ice-creams. Several * classifications have been made but the following, based on the materials used and the method of preparing them, seems best adapted for general use. These classifications have been based on the materials employed, the flavoring materials used, and the form in which the ice-cream was put up for market. 59. Classification of ice-cream. — The following is based on the materials used; the subclasses are divided according to the flavoring materials. I. Plain ice-cream, often known as Philadelphia ice- cream, is made from cream, sugar, and flavoring, with or without condensed milk or some stabilizer. This class may be subdivided as follows: (1) Plain — flavors are used such as vanilla, chocolate, caramel, coffee, mint, maple. (2) Fruit — afresh or canned fruits are employed for flavors, such as peaches, strawberries, cherries, pine- apples, raspberries. * Mortensen, M., '' Classification of ice cream and related frozen products," la. Exp. Sta., Bui. 123, 1911; Washburn, R. M., "Prin- ciples and practice of ice cream making," Vt. Exp. Sta., Bui. 155, 1910; Frandsen, J. H., and Markham, E. A., " The manufacture of ice cream and ices," Orange Judd Co., 1915. 69 70 THE BOOK OF ICE-CREAM (3) Nut — nuts such as walnuts, almonds, chestnuts, pistachio, furnish the flavoring. (4) Bisque — ^materials are used for flavoring such as macaroons, marshmallows, grapenuts, sponge cake. (5) Mousse — ^rich whipped cream sweetened and flavor folded in, sometimes eggs are used. II. Cooked ice-cream, often known as French or Nea- politan, is made from cream, sugar, eggs, and flavoring. As custards they sometimes contain flour or cornstarch. This class may be subdivided as follows: (1) Parfaits or French — flavors such as vanilla, choco- late, and the like are the most common but various fruits are sometimes used. (2) Puddings — these are highly flavored with various dried and candied fruits, nuts, and spices and eggs. (3) Custards — these contain flour, cornstarch, or other similar ingredients and are almost always flavored with vanilla. III. Sherbets and ices are made from water or milk, sugar, often egg albumen and a stabilizer, and flavored with fruit juices or other natural flavorings. (1) Ices — ^made'from water, sugar, and some natural fla- voring without eggs or a stabilizer. This may include gran- ites and frappes. Granites are frozen with little agitation, while frappes are only semi-frozen to a slushy consistency. (2) Water sherbets — ^made the same as ices with the addition of egg-whites and sometimes a stabilizer. If the whole egg is used, they are sometimes called souffles. (3) Punches— ices or water sherbets flavored with liquors or highly flavored with fruit juices and spices. (4) Milk sherbet — ^made from whole or skimmed- milk, sugar, and egg-whites, with or without a stabilizer and flavored with some natural flavoring. CLASSIFICATION OF ICE-CREAMS 71 (5) Lacto *^ — made from skimmed or whole sour milk instead of sweet milk but in other respects resembhng milk sherbets. 60. Receipts for ice-cream. — ^A large number of receipts or formulas for ice-cream might be given. Each manu- facturer usually has a receipt for his own use, which is slightly different from any other. Ordinarily ice-cream manufacterers employ the same classes of materials but in different amounts. The receipts given are typical of those used and give satisfactory results. So far as possible receipts will be given which use the various materials and at the same time vary the composition. 61. Vanilla ice-cream. — These receipts may be used as a basis for other ice-creams by substituting other flavors. These provide a basis for all plain ice-creams. Receipt No. 1. 40 lbs. 20 per cent cream 9 " sugar 4 oz. gelatine dissolved in 4 lbs. water 4 " vanilla Receipt No. 2. 32 lbs. 20 per cent cream 8 " whole or skimmed-milk condensed 9 " sugar 4 oz. gelatine dissolved in 4 pounds of water 4 " vanilla Receipt No. 3. 26 lbs. 18 per cent cream 14 " skimmed-milk condensed 8 " sugar 4 oz. gelatine dissolved in 4 pounds water 4 " vanilla * Mortensen, M., " Lacto, a frozen dainty product," la. Exp. Sta., Bui. 140, 1913. 72 THE BOOK OF ICE-CREAM Receipt No. 1 will test from 14-15 per cent of fat. Receipt No. 2 will test 13-14 per cent fat if whole milk condensed is used and 11-12 per cent of fat if skimmed- milk condensed. Receipt No. 3 will test 8-9 per cent of fat. 62. Chocolate ice-cream. — Either chocolate or cocoa may be employed to give the chocolate flavor. Some manufacturers prefer one and some the other. A thick chocolate sirup may be purchased from some flavor manufacturing concerns. A pound to a pound and a quarter of chocolate or cocoa is sufficient for a ten-gallon mix. The chocolate or cocoa may be softened in either water or milk. The cocoa forms a liquid much easier. The best way to prepare either is to put it into a double boiler and cook until a thick sirup is formed. About two quarts of milk or water is sufficient for a pound or a pound and a quarter of chocolate or cocoa. This can be used with the mixes given for vanilla ice-cream. Some manu- facturers of ice-cream prefer some vanilla with the choco- late, believing that it imparts a better flavor. 63. Caramel ice-cream. — This may be made by sub- stituting caramel flavor for the vanilla in each receipt. The flavor may be obtained by caramelizing or carefully burning sugar or by adding prepared caramel flavor. The amount of either which should be used depends on the strength of the flavor. 64. Coffee ice-cream. — Ice-cream may be flavored by the addition of coffee. The amount to use will depend on its strength. The coffee should be strained and only the liquid portion added. It may be substituted for the vanilla in the receipts. 65. Maple ice-cream. — Maple sirups or prepared maple flavor may be used to flavor ice-cream in place of CLASSIFICATION OF ICE-CREAMS 73 the vanilla. The amount depends on the strength of the materials used. 66. Fruit ice-cream. — Various flavors of fruit ice- cream may be made by substituting the fruit for the vanilla in the receipts already given. Either the fresh fruit or the preserved or canned ones may be used. In many cases the fruit sirups or extracts are employed either alone or with the fruits. It is usually customary to add a small amount of color to mix with the fruit in order to give the product the characteristic fruit color. This is not necessary but adds to the appearance of the ice- cream. The amount of fruit necessary depends on its flavor; for example, fruits with a very pronounced flavor, such as raspberry will go further than a fruit with a very delicate flavor such as peach. Usually two quarts of preserved fruits are enough to make ten gallons of ice- cream. The fruit should be chopped before adding. 67. Nut ice-cream. — Various nuts maj^ be employed to flavor ice-cream but they are not commonly used alone. The most common is pistachio. In this case the nut itself is not utilized ordinarily but an imitation flavor, and the ice-cream colored green. This is a trade custom. 68. Bisque ice-cream. — Various bread products may be used to flavor ice-cream, the result being called bisque. The common material is macaroons, but other materials such as sponge cake, grape nuts, and dried cakes may be added. The material should be dried and then ground through a food chopper before it is added to the ice- cream. 69. Mousse. — This differs from the other plain ice- creams as the cream is whipped first and the flavoring then folded inside. Various flavors may be used, but maple is the most common. 74 THE BOOK OF ICE-CREAM Mousse foundation 4 eggs 20 egg -yolks 1 lb. sugar 2 qts. whipped cream Cook sugar to heavy thread. Beat the eggs and yolks and pour sugar in slowly. Beat on ice until cold. Add whipped cream, mixing thoroughly. Fruits and nuts may be added. 70. Cooked ice-cream. — No basic receipts can be given for Class II as for Class I, in which the various flavoring materials may be substituted. Most of the cook-books give numerous receipts which belong to this class. In fact there are so many receipts for cooked ice-creams that only a few of the better ones can be given; they are usually made in small quantities. 71. Parfait. — The use of eggs makes an ice-cream of different flavor and body. This is the main difference between parfait and the plain ice-creams in Class I. Usu- ally the eggs are cooked either in afl or a part of the mix before they are added to the freezer. Receipt No. 1. 40 lbs. 20 per cent cream 10 " sugar 4 oz. vanilla 8 doz. eggs well beaten Beat the egg-yolks till smooth, add the sugar, and beat again till it is dissolved. Beat the whites to a stiff froth and stir into the yolks and sugar. Mix all with the cream and cook in a double boiler to a temperature of 180° F. for fifteen minutes. Cool to 40° F., add vanilla and freeze. CLASSIFICATION OF ICE-CREAMS 75 Receipt No, 2. 40 lbs. 28 per cent cream 10 " sugar 4 oz. vanilla 8 doz. eggs well beaten 2 qts. crushed strawberries Beat whole eggs together, add to the mix and freeze, or the whites may be beaten separately if desired and added after the mix is partly frozen. Receipt No. 3. 40 lbs. 25 per cent cream 12 " sugar 4 oz. vanilla 4 lbs. chopped walnut meats yolks of 8 dozen eggs Beat the egg-yolks till smooth, add the sugar and beat again. Then add to the cream and cook in a double boiler to 180° F. for fifteen minutes. Cool, add the bal- ance of the mix, and freeze. Other nuts or fruits may be substituted for those mentioned in the above receipts. 72. Puddings. — This product is usually very rich and is a combination of cream, sugar, eggs, spices, various fruits and nuts. Receipt No. 1. — Nesselrode 32 lbs. 28 per cent cream 10 doz. eggs 10 lbs. sugar 6 oz. vanilla 4 lb. chopped walnut meats 3 " " candied cherries 3 " " " fruits 4 " " raisins Cook the egg-yolks with the cream. Beat the whites and add when partly frozen. 76 THE BOOK OF ICE-CREAM Receipt No. 2— English Plum 32 lbs. 25 per cent cream 8 doz. eggs 12 lbs. sugar 3 " cocoa or chocolate 5 " assorted fruits that do not pulp 2 " seeded raisins 3 " dates 4 '' walnut meats 4 tablepoonfuls ground cinnamon 1 '' ginger 1 " ground cloves Use the eggs as directed under receipt No. 1. Chop the fruits and nuts fine. ' Receipt No. 3 — Fruit Pudding 32 lbs. 10 per cent cream 8 " whole condensed milk 8 " sugar 5 oz. gelatine dissolved in part of cream 2 lbs. chopped cherries 2 " " raisins 2 " " nuts 1}4. qts. sherry wine Soak the fruit overnight in sherry wine. Receipt No. 4 — Manhattan Pudding * 3 gals. 30 per cent cream 10 doz. eggs 12 lbs. sugar 2 qts. orange juice 1 pt. lemon juice 4 lbs. walnut meats 4 " pecan meats 4 " cherries and assorted fruits 73. Custards. — A custard is usually made of milk, sugar, flavoring, cornstarch or flour and the process is * la. Bui. No. 123. CLASSIFICATION OF ICE-CREAMS 77 rather long. Quantities given in receipts are for hand freezers. Receipt No. 1. 6 qts. milk 3 lbs. sugar 24 eggs 12 tablespoonfuls cornstarch 6 " vanilla or to taste Put the milk over the fire in a farina or double water i boiler. Moisten the cornstarch with a little cold milk so that it can be added to milk without lumping. When the - milk is hot, add the cornstarch and stir until it begins to thicken. Beat the eggs and sugar together until light and i then add them to the hot milk. Cook a few minutes, take from the fire, flavor and cool ^and freeze same as ice-cream. Other flavors, as coffee or chocolate, may be made by substituting these flavors for the vanilla. Receipt No. 2. 5 qts. milk 1 qt. 30 per cent cream 8 eggs 23^2 lbs. sugar 6 tablespoonfuls flour 13^ oz. of vanilla to taste Follow directions given for No. 1 Receipt No. 3. 2 qts. 30 per cent cream 4 " milk 3 lbs. sugar 13^2 qts. minute tapioca Yolks of 4 eggs 1 teaspoonful salt 4 teaspoonfuls lemon extract 2 teaspoonfuls rose extract 78 THE BOOK OF ICE-CREAM Cook the tapioca in 2 quarts of milk for ten minutes, then add the remainder of the milk, the sugar and the salt. Cook ten minutes longer. Remove from the fire and add the egg-yolks well beaten. Then add the extract, cool and freeze. When nearly done add the cream previ- ously beaten to stiff froth and finish freezing. A large number of receipts for custard ice-cream may be found in the various cook-books. 74. Ices and sherbets are usually made either of water or milk, with or without eggs and flavoring. Some kinds are frozen without agitation and some beaten like ice- cream while freezing. 75. Ices are simply water sweetened, flavored and frozen. They become grainy in texture very quickly. Receipt No. 1. 48 lbs. water 20 " sugar 6 '' lemon juice Receipt No. 2. 48 lbs. water 20 " sugar 2 " lemon juice 4 qts. pineapple juice Receipt No. 3. 48 lbs. water 20 " sugar 2 " lemon juice 4 qts. finely pulped strawberries . 76. Water sherbet. — The only difference between water sherbet and ices is that eggs are used in the former and not in the latter. CLASSIFICATION OF ICE-CREAMS 79 Receipt No. 1. 48 lbs. water 16 " sugar 1 lb. lemon juice 4 qts. grated pineapple (or pineapple juice) 6 oz. gelatine in 4 lbs. water, if desired 24 egg-whites beaten stiff and added when mixture is partly frozen Receipt No. 2. Same as No. 1 except replace the pine- apple with grape juice. Receipt No. 3. Use same mix as No. 1 except replace the pineapple with orange juice. Boil the water and sugar to a clear sirup, then strain and cool before freezing. 77. Punches. — The essential difference between ices, water sherbets and punches, is the material used for flavoring. Receipt No. 1. 48 lbs. water 20 lbs. sugar 1 " lemon juice 1 qt. brandy and rum mixed Receipt No. 2. 48 lbs. water 20 " sugar 1 lb. lemon juice 1 qt. orange juice 2 qts. wine 4 oz. gelatin in part of water Receipt No. 3. 48 lbs. water 20 " sugar 1 qt. lemon juice 1 " raspberry juice 1 " grape juice cloves, cinnamon, allspice, and nutmeg to taste 80 THE BOOK OF ICE-CREAM 78. Milk sherbets. — These are similar to water sher- bets except milk is used in place of water. Receipt : 48 lbs. milk 16 " sugar 5 ozs. gelatine in 2 qts. water 1 lb. lemon juice 4 qts. fruit flavoring 12 egg-whites beaten stiff and added after mixture is partly frozen Flavors: Orange, grape, cherry, pineapple, and straw- berry. If lemon is desired, use only 2 quarts of lemon juice with 1 quart of orange juice. 79. Lacto *. — This is the only receipt in which sour milk is used. Receipt : 48 lbs. good starter just nicely coagulated 18 " sugar 24 eggs, whites and yolks beaten separately 2 qts. grape juice l}/2 qts. lemon juice Mix in the order given in the formula. Other flavors may be substituted for the grape juice. *Ia. Exp. Sta. Bui. No. 140. CHAPTER VII EQUIPMENT The size and kind of equipment will depend on the extent of the business and the available capital. It is not considered economical to install a mechanical refrigerating system unless at least seventy-five gallons of ice-cream are manufactured a day. Certain factors should be considered when purchasing machinery; the construction and adaptability of the machine for the type of work it is intended to do; the ease of making repairs; the ease of cleaning; the durability of the machine; the protection to gearing from ice and salt. 80. Freezers. — The general principle of the ice-cream freezer is the same in all makes; however, the application may be varied. The unfrozen ice-cream or mix is placed in a container, usually called the freezing-can. This can is surrounded by the freezing material, either cold circu- lating brine or an ice and salt mixture. In the can is the beater or dasher. To this is attached two scrapers which, when rotated, scrape the frozen ice-cream from the sides. The can itself may revolve or stand still, depending on the type of freezer. The dasher may revolve or stand still, depending on whether the can revolves or stands still. In most freezers there is another part of the dasher which revolves to help beat up the ice-cream. The freezers may be divided into two general classes. The 81 82 THE BOOK OF ICE-CREAM Fig Fig. 8. — Hand freezer with tub and can cut away showing ice and salt mix- ture and beaters and scrapers in the can. 9. — Hand freezer with fly wheel, using salt and ice mixture for freezing. The ca- pacity is five gallons. Fig. 10. — Power driven tub and can freezer, using a salt and ice mixture. The can, dasher, cover and gears are shown removed. EQUIPMENT 83 one class consists of a tub and can in which an ice and salt mixture is used between the tub and can. This type of freezer is made to run by hand or mechanical power, Fig. 11. — Horizontal brine freezer attached to salt and ice brine box. The pump is behind the box. and varies in size from a few pints to ten gallons. The largest hand size is usually five gallons; these have a flywheel. The types of hand freezers are shown in Figs. 8 and 9. A power-driven tub and can freezer, using a 84 THE BOOK OF ICE-CREAM salt and ice mixture in the tub for freezing, is shown in Fig. 10. The other class is the brine freezer. In this, cold brine is forced around the freezing-can. The freezer Fig. 12. — Vertical belt driven brine freezer connected to ice and salt brine box. Pump is shown between freezer and box. runs by mechanical power, either belt-driven or directly connected to an electric motor. The brine may be made from an ice and salt mixture, or it may be cooled by an artificial refrigerating system. There are two general types of brine freezers. One has the freezer in a horizontal EQUIPMENT 85 position and the other in a vertical. Advantages are claimed for both. The arrangement of brine freezers when the brine is obtained from a salt and ice mixture is shown in Figs. 11 and 12. The brine as it comes from the freezer is sprayed over the ice and as it trickles through Fig. 13. — ^Perfection brine freezer, direct motor drive. is cooled again. It is then pumped around the freezer again. The ice is held in the box by means of a heavy wire screen; otherwise, it would clog the pump. Some of the types of brine freezers in common use are shown in Figs. 13, 14, 15, and 16. Most of these may be either belt or direct motor-driven. The usual size is ten gallons. In some cases they have been made larger but 86 THE BOOK OF ICE-CREAM these are not in common use. It is the usual practice to have a supply tank just above the freezer-can which can Fig. 14. — Progress vertical belt drive brine freezer. be filled, while one can is freezing. The mix for the next freezer is placed in this supply can and will then run quickly from it into the freezer. Another brine freezer is the disc which may be used EQUIPMENT 87 either as a batch or continuous freezer. A front view of this is shown in Fig. 17. The supply can is seen on one Fig. 15. — Emery Thompson vertical direct motor drive brine freezer. side and the delivery spout on the other. A glass plate over the freezing discs allows the process to be seen at 88 THE BOOK OF ICE-CREAM any time. A side view is seen in Fig. 18, showing the brine box and pump. The freezing discs are illustrated in Fig. 19, also the scrapers to remove the ice-cream Fig. 16. — Fort Atkinson horizontal belt drive brine freezer. from the discs and the screw to force the ice-cream along. When used as a batch freezer, the ice-cream is drawn from the bottom. 81. Mixers. — When large quantities of ice-cream are EQUIPMENT 89 ■:^%4KJS(l(l!r^^l^$«ib,,,,_ Fig. 17. — Disc brine freezer either continuous or batch. Fig. 18. — Side view of freezer shown in Fig. 17. Arrangement of brine tank and pump are shown. 90 THE BOOK OF ICE-CREAM made, a container of some sort, with a mechanical agitator to stir the contents, is used to mix the ice-cream ingredi- FiG, 19. — Freezing discs of freezer shown in Figs. 17 and 18. The scrapers for removing the ice-cream from the discs and the screw to force it out of the delivery spout are shown. ents. Some of these mixers are provided with coils in which water or brine may be circulated to control the Fig. 20. — A pasteurizer or ripener used as an ice-cream mixer. Strips are attached to the coils to prevent the settling of the sugar on the bottom. temperature. Some may be operated as a pasteurizer. An ordinary cream ripener might be used as a mixer if the sugar could be prevented from settling to the EQUIPMENT 91 bottom. Some manufacturers have accomplished this by placing a strip of iron on the coils which will reach almost to the bottom of the ripener. Such an arrange- ment is shown in Fig. 20. An ordinary starter can might be utiHzed as a mixing vat or can. (Fig. 21.) A number of ice-cream mixers are conmionly used, as shown in Figs. 22, 23, and 24. Most of these have coils which carry cold water or brine to cool the mix. In some these coils act as the agitator and in others they are placed in a jacket around the mixer. In order to keep the materials properly mixed if the coils themselves do not serve as the agitator, there is some form of me- chanical agitator. These agitators may be belt or direct motor-driven. 82. Gelatine kettles. — In most plants where much ice-cream is made, a special kettle is employed to dissolve the gelatine. (Fig. 7.) This consists of a copper steam-jacketed ket- tle. With this the gelatine and water may be heated without danger of burning. The size of these kettles depends on the amount of gelatine used. 83. Hardening the ice-cream. — Some means of keep- ing the ice-cream cold after it is removed from the freezer must be provided. This may be a specially cooled room known as a hardening room or the ice-cream may be packed in a mixture of salt and ice. These methods of hardening will be discussed later. 84. Packing-cans. — In order that the freezer may be kept in use, as soon as the ice-cream is sufficiently frozen. Fig. 21. — Minnetonna starter can or ice- cream mixer. 92 THE BOOK OF ICE-CREAM Fig. 22. — Alaska ice-cream mixer. The side is cut away showing the coils and insulation. The mechanical agitator is seen at the bottom. By means of the tight fitting cover and the air pump, the mix may be forced to the freezer by air pressure. Fig. 23. — Wizard ice-cream mixer. Fig. 24. — Emery Thompson ice- cream mixer. EQUIPMENT 93 it is removed and placed in other cans to harden. These are known as packing-cans (Fig. 25) and are made of heavy iron and tinned and fitted with a cover. The cans vary in size from one quart to five gallons and the ice-cream is hardened and delivered in these. When ready for de- livery, these pack-cans are placed in tubs which should be a little higher than the pack-can to allow for ice over the top. There should be a space also of 2-4 inches be- tween the sides of the can and the tub to allow for the ice and salt. The ice-cream may be packed in small oblong con- ice- tainers known as bricks, usually ^^" ' ^°i .-^^^^ ° . cream packmg-cans, containing one or two pints. The ice-cream may be hardened in a larger brick mold which will make several smaller bricks. When hard the ice-cream is cut into the smaller bricks, wrapped in parch- ment paper and placed in a paper carton. This is the usual method of handling brick ice-cream. Several dif- ferent layers may be placed in each brick. 85. Ice crushers. — The ice must be broken into small pieces for freezing or packing the ice-cream. This may be done by hand with an ice spud or cracker. (Figs. 26 and 27.) If much ice is to be cracked or crushed, a me- chanical crusher should be used. (Fig. 29.) The small ones run by hand power but turn rather hard. The crushers run by mechanical power are more frequently seen in ice-cream plants. These vary in size. 94 THE BOOK OF ICE-CREAM I Fig. 26.— Ice spud. Fig. 27. — Ice cracker. Fig. 28.— Perforated ice shovel. Fig. 29. — Ice crusher with tight and loose pulley for mechanical power. The teeth or picks on the drum may be seen. Fig. 30. — The perfection ice-cream can-washer and sterilizer. EQUIPMENT 95 Fig. 31. — Fort Atkinson ice-cream can- washer and sterilizer. 86. Ice-cream can-washers. — The washing of the ice- cream pack-cans by hand in an ordinary sink consumes much time. In the larger plants an ice- cream can-washer is used. This consists of sprays of water and revolving brushes. The cans are usually brushed both on the inside and outside. Some types of ice-cream can-washers and sterilizers are shown in Figs. 30 and 31. When washed, the cans should be sterihzed. 87. Emulsors, creamers, and homo- genizers. — These ma- chines vary consider- ably in mechanical construction as shown in Figs. 32, 33, 34, 35, and 36. Neverthe- less, the making of cream from butter, milk powder, con- densed milk or skim- milk is accomplished by each machine. The force used to break up Fig. 32.-De Laval centrifugal emulsor. ^^^ ^^^ ^^e materials varies with the different machines. One type which uses 96 THE BOOK OF ICE-CREAM steam as the force to break up the material is illustrated by Fig. 33. The amount of steam pressure required varies Fig. 33. — Perfection cream-maker and emulsifier. with the different makes. Another type of machine which uses centrifugal force as the means of breaking up EQUIPMENT 97 the materials is illustrated by Figs. 32 and 36. In this type, the materials are broken up or mixed by being thrown by centrifugal force through a very small opening or narrow space. The other type of machine, which is operated by valve pumps, is illustrated in Figs. 34 and 35. By means of the pumps the materials are forced through a very small opening against some hard material. Fig. 34. — Progress homogenizer. This machine, known as a homogenizer, breaks the ma- terials into very small particles; for example, cream that has been homogenized cannot be re-churned in butter because of this. A good quality of cream may be made from any of the following combinations according to the DeLaval Separator Company: Skim-milk powder — water — butter — (preferably un- colored and unsalted). Whole-milk powder — ^water — butter. Condensed skim-milk — water — butter. 98 THE BOOK OF ICE-CREAM Condensed whole milk — ^water — butter. Skim-milk — skim-milk powder — butter. Skim-milk — condensed skim-milk — butter. Whole milk — skim-milk powder — butter. Whole milk — condensed skim-milk — butter. Fig. 35. — Gaulin homogenizer. One should never lose sight of the fact that the better the quality of the materials used, the better will be the flavor of the cream. It is impossible to make first-quality cream from poor materials. The whole milk and skim- milk must be clean and sweet. Skim-milk powder should be dry, loose, and fluffy. The condensed milk should be EQUIPMENT 99 clean flavored and fresh. Off-flavored condensed milk or milk that is grainy or gritty should never be used. The manufacturers of the various machines send specific directions for their operation. To insure success, these directions should be followed carefully. It is the usual practice first to put the milk powder into solution, then to cut the butter into small pieces and put it into the milk. If skim- milk is used, the butter is put directly into it. The milk and butter are then heated to a tem- perature high enough to melt the butter, usually 130° to 150° F. It is then run into the machine. Because of the tendency of the butter to rise to the top, the ma- terials must be kept in constant agitation until run into the ma- chine. Otherwise, the butter would be at the top and would not run into the machine until the other materials had all run through. Some makers emulsify or homogenize the whole ice-cream" mJxT' Tn tEis~"case,"~the flavoring extracts and fruits are not added until after the mix has been through the machine. It^is the general opinion that the emulsifying or homogenizing of the whole mix makes a smoother body and texture in the product. Advantages in the use of emulsors and homogenizers: 1. Smoother body in ice-cream. Fig. 36. — Sharpies centrif- ugal emulsor. 100 THE BOOK OF ICE-CREAM 2. Less time required for ageing cream, especially pasteurized. 3. Not necessary to carry so large a stock of raw materials. 4. Ice-cream of more uniform composition. Disadvantages in the use of emulsors and homogenizers: 1. The disadvantage in the use of the homogenizer is in its abuse since a homogenized cream will appear richer than it really is. There is a tendency to use less solids, especially fat. 2. Danger of using inferior materials. 3. If cream is not needed for ice-cream and has been homogenized, it cannot be churned. 88. Cost of equipment. — Because of the constant change in price, it is impossible to give even estimates of cost of equipment. The price might be correct to-day and incorrect to-morrow. The cost of equipment based on the gallonage of ice-cream is usually higher for the smaller plant. In order to obtain accurate prices, the various dairy supply houses should be consulted. CHAPTER VIII REFRIGERATION AS APPLIED TO ICE-CREAM- MAKING In the making of ice-cream, refrigeration is necessary. In the following discussion only the underlying principles as apphed to operation will be taken up. The details of construction are discussed by refrigerating engineers in various text-books.* Refrigeration is the interchange of heat units. The cooUng for ice-cream-making may be obtained either from natural ice or from mechanical refrigerating ma- chines. These will be discussed under their separate heads. 89. Terms used. — In order easily to comprehend the principles of refrigeration, it is necessary to under- stand the terms used.f ''British thermal unit.— A British thermal unit (B. T. U.) is the quantity of heat required to raise 1 pound of pure water 1 degree Fahrenheit, at or near its maximum density, 39.1° F. Some authorities consider a British thermal unit as the heat required to raise 1 pound of pure water from 61° to 62° F. For practical purposes, however, it may be considered the heat required to raise the temperature of 1 pound of water 1 degree Fahrenheit. *Audels, "Answers on refrigeration," 700 pages; Cooper, Madi- son, " Practical cold storage," 800 pages. t Bowen, John T., *' The application of refrigeration to the hand- ling of milk," U. S. Dept. Agr. B. A. I., Bui. 98. 101 102 THE BOOK OF ICE-CREAM ''Sensible heat. — Sensible heat is the heat that may be felt by the hand or measured by a thermometer. ''Latent heat. — Latent or 'hidden' heat is the heat which is expended in molecular work of separating the molecules of the substance and can not be measured by a thermometer. Every substance has a latent heat of fusion, required to convert it from a solid to a liquid, and another, latent heat of vaporization, required to convert it from a liquid to a gas or vapor. Thus, if heat is applied to a pound of ice at 32° F. it will begin to melt, and no matter how much heat is applied, the ice will not get any hotter. After every particle of ice has melted, we will have 1 pound of water at 32° F., the same temperature as the ice before heat was applied. Experiments have shown that it requires 144 British thermal units to melt 1 pound of ice at 32° F. into water at 32° F.; hence the latent heat of fusion of ice is said to be 144. "If heat is applied to 1 pound of water at 212° F., the water will remain at 212° F. under atmospheric pressure until all of it has been evaporated into steam at 212° F. This has been found to require 970.4 British thermal units; hence the latent heat of vaporization of steam at atmospheric pressure is said to be 970.4 B. T. U. "Specific heat. — The specific heat of a substance may be defined as the ability of that substance to absorb heat compared to that of water. Water being one of the hardest of all substances to heat, its specific heat is taken at unity. A better understanding of latent and specific heat may be had by studying the diagram in figure 42 which shows graphically the relation of heat to temper- ature. "Ton refrigeration. — Refrigeration, or ice-melting ca- pacity, is a term applied to represent the cold produced, REFRIGERATION 103 and is measured by the latent heat of fusion of ice, which is 144 B. T. U. per pound. In other words, it is the heat required to melt 1 pound of ice at 32° F. into water at the same temperature. The capacity of a machine in tons of ^ice melting' or 'refrigeration' does not mean that the machine would make that amount of ice, but that the cold produced is equivalent to the melting of the weight of ice at 32° into water at the same temperature. There- fore 1-ton refrigeration is equal to 144 x 2,000, or 288,000 B. T. U. A 1-ton refrigerating machine is a machine that has a capacity sufficient to extract from an insulated bath of brine 200 B. T. U. per minute, 12,000 B. T. U. per hour, or 288,000 B. T. U. per 24 hours. *' Absolute pressure. — Absolute pressure is pressure reckoned from a vacuum. Pressure gauges in general use are arranged to indicate pressure in pounds per square inch above atmospheric. To convert gauge pressure to absolute pressure, 14.7 pounds, the weight per square inch of air pressure at sea level, must be added." NATURAL ICE Only in the cold or northern latitudes can a supply of natural ice be obtained. In the warm regions a refriger- ating machine or ice made by an artificial refrigerating system must be used. The harvesting of ice is a very simple process, yet it involves a large number of details. Success in obtaining a crop of ice requires careful atten- tion to each detail. 90. The ice field. — It is important that the water from which the ice is to be made be free from contamination. If weeds grow in the pond in the summer, they should be removed in the fall. If green spawn or algae grow pro- fusely, they can be eliminated by the use of copper sul- 104 THE BOOK OF ICE-CREAM fate.* The crystals may be placed in a cloth sack, which is hung to a pole and trailed through the water until the salts are dissolved. One or two treatments of the sulfate in the season, at the rate of 1 pound to 100,000 gallons (13,000 cubic feet) of water will be suffi- cient to keep down such growth and make the water clear and pure. The area of the ice field or pond should be large enough to fill the ice-house at a single cutting, some allowance being made for waste. The water should be deep enough so that there will be at least from eighteen inches to two feet under the ice at the time of harvesting. Snow often interferes with the ice formation. If the ice is thin, and the fall of snow heavy, the latter may sink the ice. If the snow remains on the ice, it acts as an insulator and so prevents the freezing. The snow may be handled in either of two ways; it may be scraped off the ice by hand or with a horse scraper, or the snow may be soaked with water. In the latter practice, there is danger of a crust forming and so preventing the formation of ice and hindering future scraping. 91. The ice-house. — The main essentials of a good ice-house are insulation, ventilation, and drainage. The house should be so located that there will be good drain- age. If proper drainage is not provided, the water acts as a conductor of heat and so causes the ice to melt faster. It is desirable, but not necessary, that the ice-house have a north exposure and shaded with trees to keep off the heat of the sun. It should be located as near the place where the ice will be used as possible. There is a wide range of variation in type of construction and cost of materials in the erection of a satisfactory ice-house. The * Corbett, L. C, " Ice houses," U. S. Dept. Agr., Farmers Bui. 475, 1915. REFRIGERATION 105 walls may be insulated so that the ice is simply piled in the house. This is the most expensive type of construc- tion. In contrast to the insulated house, a bin may be built and the cakes of ice piled close together in it so that there will be a space about one foot to eighteen inches around the sides between the ice and the bin. This space should be filled with sawdust or hay and an equal amount placed over the top, which acts as an insulator. This is the cheapest form of construction and is somewhat waste- ful since the top of the pile is exposed to the direct rays of the sun and the rains. The usual type of ice-house is a form of construction between the two extremes men- tioned above. It consists of a cheap board frame to hold the insulation on the sides and a roof. The gables should be partly open to give a circulation of air. A cubic foot of ice weighs about 58 pounds and re- quires about 35 cubic feet for a ton. Allowance for the spaces between the cakes of ice should be made when figuring the capacity of the house. The usual practice is to figure from 43-46 cubic feet for each ton of ice. 92. Harvesting and storing. — Ice is not usually har- vested until at least 8-12 inches thick. This will depend on the location and the season. The size of the cakes vary, but the usual sizes are 22 x 32 inches; 20-22 x 28; 22 X 42-44. The cakes of ice may be sawed with a hand- saw. (Fig. 37.) On a large field, the ice may be cut with an ice-plow drawn by horses. (Fig. 38.) On this plow is a marker to show where the next cut should come. Thus if the first cut is straight, a straight mark will be made to be followed for each succeeding cut. The ice-plow does not cut en- tirely through the ice, but it should be adjusted to cut 106 THE BOOK OF ICE-CREAM nearly through. This will make the breaking off of the cakes easy. If the field is large enough, it is usually plowed each way. This cuts the ice into cakes. There- fore, after plowing all that is necessary is to separate the cakes. This is accomplished by breaking or splitting with a spHtting-fork. (Fig. 39.) On a small field, the ice is sometimes plowed only one way. In this case the cakes are sawed off with the hand-saw. Either a perpendicular or inclined elevation with their conveyors should be used to put the ice into the house. Only regular shaped cakes should be stored, all broken Fig. 38. — Ice-plow with marker. ones being rejected because they do not pack closely, hence allow too much waste and air space. The cakes should be packed closely together and yet allow air cir- culation. In order to secure this, it is best to run the rows of cakes one way in one tier, the other way in the next tier and so on. Each tier should be planed smooth before the next is placed on it. This may be done by a large planer on the ice incline or by hand in the house. The REFRIGERATION 107 insulation should be put around the sides as the house is filled. When all the ice is in the house, the insulation, either hay or sawdust, should be immediately placed over the top. The ice should be watched and if the hay or sawdust has settled so that the ice is ex- ^ p— ' 1 — ' Q posed to the air, more ^^^ 39.-Splitting fork, should be added. It is best to fill the house when it is freezing temperature. If it is thawing the cakes of ice will have water on them, later this will freeze and it will be almost impossible to remove the cakes without breaking them. When taking the ice out, each tier should first be removed before the one be- low is disturbed. After each removal of ice the covering over the top should be replaced. 93. Amotint of ice needed. — It is difficult to know exactly how much ice to store to meet the needs of the summer. Some ice goes farther than others; some years there is more waste than others. The following figures compiled by the ''Ice Cream Trade Journal" will give a fair idea of the amount required to a gallon of ice-cream: Amount of ice used for 100 gallons, 1,928 pounds. This was divided as follows: freezing, 614 pounds; hardening and storing, 914 pounds; shipping, delivering, and icing cabinets, 400 pounds. 94. Use of ice and salt mixture. — Under normal con- ditions ice melts slowly. In order to obtain a quick change of temperature and one below that of the ice, a salt and ice mixture is used. Bo wen * gives the following discussion of cooHng by salt and ice mixtures: "When two solid bodies, as salt and ice, mix to form a liquid a * Bowen, John T., " The application of refrigeration to the hand- ling of milk," U. S. Dept. Agr. B. A. I., Bui. 98. 108 THE BOOK OF ICE-CREAM certain amount of heat becomes latent, called the latent heat of solution. Since this latent heat is taken from the mixture itself the temperature falls correspondingly. 30 \ 25 \ \ 20 1 \ /5 i \ /O 1 \ \ 5 1 \ \ 1 '5 ^ «: T \ '/O X % or sa \Lr \ o Fig. 40.- /O /5 PO 25 30 -Approximate temperatures obtained with different proportions of ice and salt. The temperature obtained by a salt and ice mixture de- pends principally on the relative proportions of the mix- ture, and to a less extent on the rate at which the heat is REFRIGERATION 109 supplied from the outside, the size of the ice lumps and salt particles, and the amount and density of the resulting brine. Hence it is impracticable to give other than approx- imate temperatures with fixed ratios of salt and ice. The following curve (Fig. 40) shows the approximate tempera- ture obtained with different proportions of salt and ice. ''One pound of ice, in melting, absorbs 144 B. T. U. This is known as the latent heat of fusion of ice. Salt in dissolving also absorbs heat, called the latent heat of /-f5 /40 kj /20 //O 1 \/05 "^ *-. t ^ V^ t ^ \ v^ ^ J^ \ \ \ ^ \ N ^ \ «j % or s. ALT J A/ A// XTO RE 2^ 6 <3 /O /2 M /6 /8 20 22 24 Fig. 41. — Refrigeration available with different percentages of salt. solution, which varies in amount, depending on the density and temperature of the resulting brine. "The heat of solution of salt in water at 32° F. varies from 58 to 16 B. T. U., depending on the final strength of the brine obtained. "The following curve (Fig. 41) shows the amount of refrigeration available per pound of ice and salt mixture. The figures were calculated from the melting of ice at 110 THE BOOK OF ICE-CREAM 32° F. into a liquid at the same temperature. If, however, the salt is added to the ice at a temperature varying from 32° F. or, if the resulting brine is allowed to escape at a temperature other than 32° F., the amount of available refrigeration must be corrected accordingly. These corrections are determined by multiplying weights, in pounds of salt and brine, by their respective specific heats and by their difference in temperature from 32° F. The specific heat of dry salt may be taken as 0.214, as the specific heat of salt brine varies with its density. "Usually salt when added to ice is of a higher temper- ature than that of the ice; consequently the correction for its heat above 32° F. must be subtracted' from the available refrigeration shown by the curve, Fig. 41; and if the brine is allowed to escape at a temperature below 32° F. the re- frigeration lost in the discharge brine must be subtracted, while, on the other hand, if the discharge brine is at a tem- perature higher than 32° F. the correction must be added. "If given amounts of ice and salt, at a temperature of 32° F. are mixed together and the mixture supplied with sufficient heat to melt the ice and dissolve the salt and raise the temperature of the resulting brine to the original temperature of 32° F., then the total amount of heat absorbed by the reaction will be the sum of the latent heat of the ice and the heat of solution of the salt to form the resulting brine of the density which will result from the particular proportion of salt and ice chosen. As an example, under the foregoing conditions, if 100 pounds of dry salt are added to 900 pounds of ice the total available refrigeration is 1,000 x 133= 133,000 B. T. U. The avail- able refrigeration per pound of mixture, 133 B. T. U., is taken from the curve in Fig. 41. If the salt added is at a higher temperature than 32° F., say 60° F., then the REFRIGERATION 111 available refrigeration will be 133,000 -[100 x 0.214 (60- 32) ] = 132,401 B. T. U., or 132.4 B. T. U. per pound of mixture. If the resulting brine is allowed to escape at 25° F., the available refrigeration is 133,000- [1,000 x 0.892 (32-25)] = 126,756 B. T. U., or 126.7 B. T. U. per pound of mixture. Or, in other words, there is lost in the first case 100 x 0.214 (60-32) =599 B. T. U., and in the second case, 1,000 x 0.892 (32-25) = 6,244 B. T. U., or a total loss, if the salt is added at 60° F. and the brine allowed to escape at 25° F., of 599+6,244 = 6,843 B. T. U. Under these conditions the available refrigera- tion is 133,000-6,843 = 126,157 B. T. U., or 126 B. T. U. per pound of mixture." MECHANICAL REFRIGERATION A large number of small ice-cream plants do not use mechanical refrigeration, but natural ice. It is not con- sidered economical either in labor or cost to attempt to' employ ice if seventy-five or more gallons of ice-cream are made a day. The size of the mechanical refrigerating ma- chine varies, but the underlying principles are the same. 95. Principles of mechanical refrigeration. — Bowen gives the following concise but plain description of these principles: * ''When a solid or a liquid changes its state or condition, as when a solid is converted into a liquid or a liquid into a gas or vapor, the change of state or condition is in each case accompanied by the absorption of heat. This ab- sorption of heat, as previously explained, is called ' Latent Heat'; that is, heat that cannot be measured by a ther- mometer; and in order to transfer a substance from one * Bowen, J. T,, " The application of refrigeration to the handling of milk," U. S. Dept. Agr. B. A. I., Bui. 98. 112 THE BOOK OF ICE-CREAM state to another it is only necessary to supply or extract heat. For instance, if we take 1 pound of ice at zero temperature, Fahrenheit scale, and apply heat, the tem- perature will rise until it reaches 32°. If we continue the appHcation of heat, the ice will begin to melt, and after we have supphed sufficient heat the 1 pound of ice will have changed to water at 32° F., the same temperature at which the ice commenced to melt. If the application of heat is continued the water will grow warmer, but at a slower rate. It now takes about double the amount of heat to raise the 1 pound 1 degree as water that it did to raise the 1 pound 1 degree as ice. In other words, the specific heat of water is approximately double that of ice. ''When sufficient heat has been added to raise the 1 pound of water to a temperature of 212° F., another critical point is reached at which further application of heat to the water, under atmospheric pressure, will not increase its temperature, but changes it into steam at a temperature of 212°. The relation of heat to temperature is shown in Fig. 42. ''It will be noted from Fig. 42 that to raise the temper- ature of the 1 pound of ice from zero to the melting point (32° F.) 16 B. T. U. were expended; in melting the ice, 144 B. T. U.; in raising the water to the boiling point, 180 B. T. U.; and to evaporate the water, 970.4 B. T. U. If the operation is reversed, the heat being extracted instead of being added, the curve will follow backward on itself to the starting point. "The latent heat of fusion and the latent heat of vapor- ization are represented on the diagram by the two lines parallel to the horizontal base line, the length of the lines representing to scale the amount of heat expended in molecular work in separating the molecules of the sub- REFRIGERATION 113 stances. Starting from the left, the rising Hnes represent the heat required to raise the temperature of the ice, water, steam at constant volume, and steam at constant pressure, respectively." 96. Materials used in mechanical refrigerating sys- tems. — "The same law applies to liquified anhydrous ammonia, carbon dioxid and sulphur dioxid, which are ^'^n ... ~ ~ Jl\ ^PO SreAM CO/VS7>!\A/r l/Oli/Af£— / "^00 5T€A/^ COA/STANT F'/^SSSORE- / F»n ?6n P'iO ??n is ^ 1 ?oo IfitO i- / f6n / /4n /?o ,^ too f so 60 t ^n /Cl / / pn / L QU. ^A/T/T) •< OF J- ^SA T/ V J ?. Z U PM 300 400 500 600 700 SOO 900 /OOO //OO /SOO /300 Fig. 42. — Diagram showing relation of heat to temperature. the substances most commonly used in commercial re- frigerating machines. These liquids are extremely volatile, their change of state takes place very rapidly, and their latent heat is absorbed at a corresponding rate. Their boiling point is sufficiently low, under atmospheric or other conveniently produced pressure, to give the tem- perature desired. Although the same principles underlie the use of all such fluids, their physical properties vary, and consequently demand different treatment in order to produce the best results. 114 THE BOOK OF ICE-CREAM "The theoretical requirements of a good refrigerant are: A low boiling point at ordinary pressure, a large latent heat of vaporization, and a small specific volume. A low boiling point is desirable, because it makes opera- tion possible with comparatively low pressure in all parts of the system; therefore, the machines and accessories may be of lighter construction, with smaller loss of gas by leakage. As the latent heat of vaporization is, to a cer- tain extent, a direct measure of the cooling effect, it is obvious that the greater the heat of vaporization the better the refrigerant. The specific volume of the refrigerating agent determines the volume of the cylinders of the com- pressor, consequently the size and weight of the machine. ''In comparing the three refrigerating agents which are considered apphcable to the dairying industry, viz., ammonia, carbon dioxid, and sulphur dioxid, it will be noted by referring to tables giving the main character- istics of the agents that, assuming the limits of operation are between 5° F. and 85° F., the absolute pressures are: Ammonia from 27 to 175 pounds, carbon dioxid from 290 to 1,000 pounds, and sulphur dioxid from 9 to 65 pounds. Taking the boiling points of the liquids at the temperature at which the liquid boils under atmospheric pressure, it will be noted that there is a wide difference in their boiling points as well as their latent heats of vaporization. Ammonia boils at 28.5° F. below zero and has a latent heat of vaporization of 572.8 B. T. U. Car- bon dioxid boils at 110° F. below zero and has a latent heat of vaporization of 140 B. T. U. at a pressure of 182 pounds per square inch absolute. The latent heat at atmospheric pressure is not definitely known. Sulphur dioxid boils at a temperature of 14° F. and has a latent heat of vaporization of 162.2 B. T. U. REFRIGERATION 115 'Tor practical purposes the value of a refrigerant depends upon its boiling point, its latent heat of va- porization, and upon the pressure at which it can be used. ''To maintain a zero temperature with ammonia as the refrigerant an absolute pressure of 30 pounds per square inch is required in the evaporating coils; with carbon dioxid, 310 pounds absolute; and for sulphur dioxid, 10 pounds. "Ammonia has a much greater latent heat of vapor- ization and the working pressures are not excessive, but it has the disadvantage that it corrodes brass or any other copper alloy; consequently only iron or steel can be used in the construction of those parts of the machine with which the agent comes in contact. The pressures of carbon dioxid are so' high as to cause trouble in keeping the stuffing box and joints tight. A relief valve is often placed in the high-pressure side of the system in order to protect it from excessive high pressures. It is noncor- rosive, nonexplosive, and is not dangerous to life when diluted with air. The high pressures necessary, combined with the small specific volume of the gas, make it suitable for use with a very compact machine. As the lower pressure of sulphur dioxid is below the atmospheric, any leakage of air will be into the system and will cause cor- rosion of the metal by forming sulphurous acid. The low pressures required in using sulphur dioxid as a re- frigerant in connection with its large specific volume makes a large and cumbersome machine necessary. The ratios of the volumes of the cylinders necessary for a given capacity of machine, taking that of carbon dioxid as one, are approximately as follows: Carbon dioxid 1, ammonia 4.4, sulphur dioxid 13." 116 THE BOOK OF ICE-CREAM 97. Operation of refrigerating machines. — The re- frigerating material commonly used in ice-cream plants is ammonia. There are two types of ammonia machines, the compression and the absorption systems. 98. The compression system. — The following, Fig. 43, shows the simplest compression system of refrigeration. The liquid ammonia in the small container is allowed to evaporate but it really boils. In order to boil or to change from a liquid to a gas, it must absorb heat. This heat is taken from the surrounding material, in this case brine. This cools the brine in the container in which the vessel of ammonia is placed. In this case, there is no control of the rate of evaporation of the ammonia. An arrangement by which the evaporation or escape of gas can be controlled is shown in Fig. 44. The flow of liquid is regulated by an expansion valve and the liquid is carried into a brine tank or refrigerating room and from the coil of pipe in there gas is allowed to escape in the atmosphere. The change from a liquid to a gas in this coil of pipe cools the surrounding substance, either brine or air. Tiiis is the usual arrangement of the compression system; the remainder of the system is to return the evap- orated liquid or gas back to a liquid in the ammonia tank. Fig. 43. — Simplest compression system of refrigeration. REFRIGERATION 117 99. Parts of a compression system. — The functions and principal parts of a compression system of refrigera- tion are as follows : Compressor, — This is a specially designed valve pump. It takes the gas from the evaporating coils, compresses Fig, 44. — Compression system of refrigeration in which the flow of liquid is regulated by the expansion valve. The liquid changes to a gas in the coil of pipe, thereby cooling the brine. The gas finally passes off into the atmosphere. it and forces it into the condensing coils. This reduces its volume and produces heat. Oil-traps. — In the compressor, there is danger of some oil becoming mixed with the ammonia. The purpose of the trap is to separate the oil from the ammonia. It is usually placed next the compressor. Condensing coils. — This consists of a double coil of pipe, one within the other. Cold water is circulated in the inner pipe and the ammonia in the space between the inner and outer pipe. In the condensor the heat is 118 THE BOOK OF ICE-CREAM taken up by the water and the ammonia again becomes a liquid. Ammonia receiver or storage tank. — From the condens- ing coils, the liquid ammonia passes into a receiving or storage tank until wanted for use again. Expansion valve. — It is by means of this valve that the evaporation of the ammonia is regulated or, in other words, the rate of flow of the ammonia from the receiving tank is regulated by this valve. EVAPORATING COIL- 0/L SEPARATOR WATER /NLET fl . DOUBIE P/RE AMMONIA CONDENSER AMMONIA RECEIVER Fig. 45. — Complete system of direct expansion refrigerating machine. Evaporating coils. — These coils are usually located in the material to be cooled, ordinarily the air of the re- frigerator or a brine tank. In these coils, because of the reduced pressure, the ammonia liquid evaporates or boils and in doing so takes up heat. This, as has been explained before, causes the cooling. From the evaporating coils the ammonia gas goes back to the condensor. This makes a complete circuit for the ammonia. 100. Operation of direct expansion compression sys- tem. — The following diagram. Fig. 45, shows the complete system of direct expansion refrigerating. When the evaporation coils are placed in the refrigerator and the REFRIGERATION 119 heat is taken directly from the air, it is known as the direct expansion system. The Kquid ammonia passes from the ammonia re- ceiver (R) through the expansion valve (X) into the evaporating coils (E). Here the ammonia changes from a liquid to a gas and in so doing takes up heat from the refrigerator. The ammonia gas passes to the compressor (C). From the expansion valve to the compressor is what is usually known as the low pressure side because here the pressure is reduced in order that the ammonia can boil or evaporate. For this reason the expansion valve is sometimes called the reducing valve. The gas is compressed in the compressor (C), then passes through the oil-trap (S) where the oil is taken out and then through the condensing coils (W) where the heat is absorbed and the gas changed to a liquid and back to the ammonia receiver (R). From the compressor to the expansion valve is what is known as the high side because of the pressure caused by the compression. 101. Location of evaporating coils. — As explained above, the location of the evaporating or expansion coils in the refrigerator so that the heat is taken directly from the air is known as the direct expansion method of re- frigeration. In order to keep a refrigerator cold with this method, it is necessary to run the compressor almost continuously. In some cases the evaporating or expan- sion coils are placed in brine tanks. The heat is then taken from the brine which in turn cools the air. By the use of th,e brine tanks, the compressor may be stopped and the cold brine will tend to maintain a more uniform temperature in the refrigerator while the compressor is not running. A combination of the direct expansion and brine storage 120 THE BOOK OF ICE-CREAM tanks is shown in Fig. 46. This is a common arrangement in refrigerators where a low temperature is desired and it is not economical to run the compressor continuously. The brine storage tanks are sometimes called congealing tanks. In some cases it is desirable to have refrigeration in some place where it is not possible to use either the direct expansion or the brine storage system; for example, to freeze ice-cream. In this case the expansion coils are located in a brine tank and the cold brine pumped to the place where refrigeration is desired. Such an arrange- £^/APORATir\lG CO/L- FiG, 46. — Combination of direct-expansion and brine storage tanks. This is the same system as shown in Fig. 45 with the brine tank T added in the refrigerator. ment is shown in Fig. 47. The brine flows from the tank (T) in the refrigerator to the pump (P) . It is then pumped through the ice-cream freezer (I) and back to the brine tank. The latter may be separate from the refrigerator and contain cans of water for the making of artificial ice. Most plants make artificial ice for packing the ice-cream for delivery. . 102. Notes on operating compression system. — In order to operate a refrigerating machine economically, certain factors must be given constant attention. When ammonia is passing through the expansion valve, it REFRIGERATION 121 should be covered partially with frost or the part where the pressure is reduced will be frosted as will the pipe leading from it into the refrigerator. This cannot be prevented. The proper adjustment of the expansion valve is very important. If too wide open, the flow of liquid will be too rapid, it will not all vaporize in the evaporating coils and so will take heat from the air after leaving the refrigerator, causing the pipe from the re- frigerator to the compressor to become covered with Fig. 47. — Arrangement where it is desired to use cold brine in some machine such as an ice-cream freezer. This is the same refrig- erating system as shown in Figs. 45 and 46. frost. This is a waste and may cause a high pressure on the low side. Usually the low pressure side carries 10-20 pounds pressure and the high side 125-150 pounds. If the ammonia passes the expansion valve too fast, as mentioned above, it may cause the compressor to labor too hard and so cause pounding. If not enough ammonia is passing the expansion valve, the rate of re- frigeration is reduced. The cost of operating a refrigerating machine varies. The principal items are: 1, Power; 2, water; 3, incidentals (refrigerant oil, and the like); 4, repairs. No figures can 122 THE BOOK OF ICE-CREAM be given for the cost of a ton of refrigeration because of the variation in the price of each of the items mentioned. Some very compact refrigerating systems are on the market especially adapted for making ice-cream in places where space is limited. The principle of operation of these machines is the same as all other expansion systems. ABSORPTION SYSTEM The absorption system is not as common -as the com- pression. When used, it seems to be very satisfactory. 103. Operation of absorption refrigerating system. — The following principles of operation, and Fig. 48 of an absorption refrigerating machine, are contributed by Henry Vogt Machine Company. "The first step is pumping a strong charge of what is technically known as aqua ammonia, or, in plain terms, a solution of water and anhydrous ammonia, from the absorber into the bottom pipe of th6 rectifier. It is then forced upward through the inner pipes or tubes and out from the top through a pipe connected to the top of the exchanger where the strong liquid passes down through the inner pipes or tubes and out at the bottom through a pipe connecting with the ammonia generator. ''Within the generator the ammonia gas is driven off from the strong solution by the heat in the steam coils, leaving a weak solution of aqua ammonia in the lower part of the generator. "The generated gas, under pressure passing out at the top of the generator, enters the rectifier through the top connection and is forced downward through the outer pipes. In, transit through the rectifier, the strong aqua absorbing some of the heat in the gas, condenses whatever moisture is in it. The gas passes out of the bottom of the REFRIGERATION 123 U3 1 J 1X33)1 01 SV9 124 THE BOOK OF ICE-CREAM REFRIGERATION 125 1. H. P. gas; 2. Purge; 3. Water outlet; 4. Purge; 5. H. P. trap; 6. H. P. gas; 7. Purge; 8. Water; 9. to sewer; 10. Purge; 11. Purge drum; 12. Equalizing main; 13. Purge; 14. Steam coils; 15. Trays; 16. Pump-out; 17. Drain; 18. Gauge board; 19. Oil trap; 20. Exhaust steam; 21. Trap; 22. Weak aqua main; 23. Strong aqua main; 24. Boiler steam; 25. Aqua ammonia pump; 26. Exhaust; 27. Drain; 28. Pump-out; 29. Pump-in; 30. Pump-out; 31. Gauge lines, 32. Equalizing main; 33. S. A. Draw-off; 34. Charging connection; 35. Charging connec- tion; 36. Drain; 37. Check; 38. L. P. Gas; 39. Ammonia liquid ; 40. Weak aqua; 41. Regulating valve; 42. Water outlet; 43. W. A. Draw-off; 44. Check; 45. Liquid mains; 46. Accumulator W. A. Draw-off; 44. Check; 45. Liquid mains; 46. Accumula- tor; 47. outlet; 48. Drip; 49. Fresh water main; 50. check; 51. Expansion valve. 126 THE BOOK OF ICE-CREAM o o fl el o O -9-^ o3 -t-j ^ h « ^ ^ (/J a a 03 u >J 0) +j fi PI OJ a QJ bO C crt Jh tn 03 03 }-i (V SH O) 1 1 d »o d PIH REFRIGERATION 127 1. Water main; 2. Purge; 3. Purge; 4. H. P. Trap; 5. H. P. Gas; 6. H. P. Gas; 7. Drip; 8. Check; 9, Strong aqua; 10. Drip; 11. Pump-out; 12. Weak aqua; 13. Gauge; 14. Traj^s; 15. Steam coils; 16. Gauge glass; 17. Boiler steam; 18. Exhaust steam; 19. Grease trap; 20. Drain; 21, Gauge board; 22. Liquid main; 23. Strong aqua main; 24. Weak aqua main; 25. Gauge; 26. Trap; 27. Aqua ammonia pump; 28. Exhaust; 29. Drain; 30. From boiler; 31. Air chamber; 32. Pump-in; 33. Equalizing main; 34. Charging connection; 35. Pump-out and blow-in; 36. Drain; 37. Charging connection; 38. Blow-in line; 39. Gauge line; 40. Liquid main; 41. Accumulator; 42. Ex- pansion valve; 43. Purge; 44. Purge drum; 45. Water main; 46. EquaHzing main; 47. Gas main; 48. Check; 49. W. A. main; 50. W. A. Draw-off; 51. Strong Aqua tank; 52. Gauge glass; 53. S. A. Draw-off; 54. Check. 128 THE BOOK OF ICE-CREAM rectifier into a separator where baffle plates separate the moisture from the gas. "The moisture is trapped back to the generator while the dry gas continues to the condenser, where it enters at the top of the shell or coils. Being brought into con- tact with the water cooled surface of the condenser, the sensible as well as the latent heat of the ammonia is ex- tracted, and the gas quickly liquifies. This liquid am- monia is conducted to the brine cooler or refrigerating coils where it evaporates by absorbing the heat contained in the brine or air surrounding the coils, thus performing the work of refrigeration. The vapor or gas thus formed is piped to the bottom of the absorber. ''The weak aqua ammonia, in the meantime, passes from the bottom of the generator to the bottom of the exchanger and flows upward through the outer pipes for the purpose of exchanging the heat with the strong aqua ammonia flowing downward through the inner pipes. ''From the top of the exchanger the weak aqua is conducted to the bottom of the weak aqua cooler, flowing up through the outer pipes to be further reduced in tem- perature by cooling water passing down through the inner pipes. Finally it flows in the top of the absorber where the ammonia vapor from the refrigerating coils, owing to its great affinity for water, is rapidly absorbed by the weak aqua, forming again the strong solution of aqua ammonia. The double cycle of circulation is thus completed. The same operation is repeated indefinitely." 104. Arrangement of double pipe and atmospheric absorption machines. — There are several types of the absorptiqn machines. The general arrangement and the direction of the flow of gases and liquids are shown in Figs. 49 and 50. CHAPTER IX PREPARING THE MIX Mix is a term applied to the unfrozen ice-cream. It is sometimes called ^' batch" or '^batter." The amount of mix prepared at one time may be enough for one or sev- eral freezers or for a whole day's freezing. 105i Importance of preparing the mix. — The pre- paring of the mix is one of the most important phases of the ice-cream business, because of the control of flavor, the effect on the body and texture, and financial consider- ations. If the flavors were always uniform, it would be a simple matter to prepare the mix. This not being the case, it requires considerable practice and skill to know exactly how to blend them. The mixer of the different materials should know which must be rejected and which used and in what flavors of ice-cream. The sour or acid flavor can be determined easily in the milk products by means of the acid test. For its use, see Chapter XIV. Besides this, many other undesirable flavors are present in the ma- terials. For example, it would be unwise to try to mix acid fruits with cream already high in acid, since this probably would cause a pronounced sour taste and might curdle the cream. Some makers believe that the flavor added to the ice-cream will cover up any bad flavors in the milk products, but this is not the case. If there is any undesirable flavor in the materials it can be detected in the ice-cream. Of course the person preparing the mix 129 130 THE BOOK OF ICE-CREAM has the receipt or formula but this is only a general guide; the final test is the taste. Each mix should be tasted before it is frozen to make sure that the flavor is correct. If not palatable in the mix, it will not be in the ice-cream. In some cases, it is necessary to have the flavor more pronounced in the mix than is desired in the finished product because the flavor may freeze out or become less pronounced. From the financial viewpoint, mixing is one of the most important parts of the whole enterprise. Here the ques- tion of whether the business is to be a success or failure is largely determined by the cost of the materials. After the materials have been determined, it is necessary to see that the exact amount is used in each mix. This means that each mix must be standardized, both for fat and total solids. For method of standardization, see Chapter XIV. An example may illustrate what a small loss will amount to in dollars and cost a gallon. Suppose 1000 pounds of cream testing 20 per cent fat were desired and instead of this it tested 20.5 per cent fat. This would use 5 pounds more fat which at $1.00 a pound would equal $5.00; the wages for a good man. This 1000 pounds of cream would make approximately 250 gallons of ice- cream. The $5.00 additional cost for 20.5 per cent cream would make the ice-cream cost 2 cents a gallon more. This shows that a small divergence in cost a gallon may make a big total difference especially noticeable if near the dividing line between profit and loss. Another ex- ample indicates how carefully the mix may be standard- ized to reduce cost. An ice-cream plant found that the mix could contain .21 per cent of acidity without injury to the quahty of the product. Each material was tested for acidity (see Chapter XIV), and because there was an PREPARING THE MIX 131 abundant supply of buttermilk for which there was no market, the mix was standardized to .21 per cent acidity by the use of buttermilk. This reduced the cost by using a material for which there was no market. The body and texture are largely determined by the materials employed, although the freezing and subsequent handling has a decided influence on the quality. Too much study cannot be given to the question of the materials to be used in the mix nor too much pains taken to see that each mix is properly standardized. 106. Usual procedure in preparing the mix. — Much detail variation in preparing the mix is possible and yet obtain accuracy and good quality of ice-cream. The usual procedure is as follows: The milk products are first put into the container in which the mixing is to be done. In a large ice-cream plant some type of the me- chanical mixer, Figs. 20, 21, 22, 23, and 24, is used. A view of a mixing-room is shown in Fig. 51. The mixers are just above the level of the floor, making it easy to put materials into them. In this case, the mixers are above the freezers so that the mix flows by- gravity. Each material should be weighed or measured accurately. After the materials are mixed together, it is often desirable to test them to make sure that the desired standardiza- tion has been obtained. The sugar is weighed next into the mix. The amount will vary according to the flavor and materials used. For example, with sweetened con- densed milk, less sugar will be required. Time should be allowed before freezing for the sugar to dissolve. This can be hastened by stirring, which may be done by a mechanical or hand agitator, depending on the size of the mix. Whichever method is employed, care should be exercised not to stir the mix enough to cause the fat 132 THE BOOK OF ICE-CREAM to churn. This would cause lumps of fat or butter in the ice-cream. The stabilizer is added next. In some cases, such as the prepared ice-cream powders, it should be mixed with Fig. 51. — Mixing room in large ice-cream plant. the dry sugar and added with it. If gelatine or gum tragacanth is used, it should be applied slowly and the mix agitated to prevent lumps forming. For method of preparing gelatine, see Chapter IV. If color is desired, it should be put in just before the flavor. This will pre- vent streaks in the ice-cream. Lastly, the flavor should be added, care being taken to use the exact amount. In PREPARING THE MIX ' 133 the case of fruit ice-cream, the fruit may not be put in until the mix is partly frozen. If acid fruits are stirred in the mix before partly freezing, the cream might curdle. If the fruit is added to the mix and then frozen in an upright freezer, there is danger of it settling to the bottom. If it is desired to emulsify or homogenize the whole mix, this should be done before the flavoring materials are added. The flavoring might be lost during the proc- ess and pieces of fruit would clog the machine. When ready to freeze, the mix should be tasted to make sure that everything has been added and that the mix has the proper flavor. Of course little can be told about the body and texture of the resulting product by tasting the mix. But the flavor is a good index of that of the ice-cream. 107. Temperature of the mix. — As will be pointed out in connection with over-run, the temperature of the mix when it enters the freezer is very important. If too warm, the cream will churn before it will beat up or whip. Most of the mechanical mixers possess some means of controUing the temperature of the mix. But the operator should make sure that the mix is at the desired temper- ature. It should never enter the freezer above 60° F. and the nearer 40° F. the better. CHAPTER X FREEZING PROCESS The principles of freezing are the same whether a large or small freezer is employed. It is usually harder to control the process in a small receptacle. In a large plant the freezers are arranged in a row or battery, as shown in Fig. 52. One man operates six to eight, with a helper to carry the ice-cream to the hardening-room. 108. Purpose of freezing. — Freezing is for the purpose of cooling the mix and getting it in such condition that it is edible while frozen. If frozen without agitation it would be icy and grainy. If the mix is placed in the freezer too warm, it is liable to churn. Freezing incorpo- rates air into the ice-cream and so gives pore space. The increase in volume due to freezing is known as "swell" or ''over-run." 109. Rate of freezing. — If the freezing is not properly done, the result is a loss in both quality and quantity of ice-cream. The rate or time required to freeze is af- fected by different factors, depending on the type of machine used. In the brine freezer, the rate is dependent on the follow- ing factors: 1. Temperature of brine; 2. rate of flow of brine; 3. temperature of materials when put into freezer; 4. materials in mix; 5. speed of the freezer. In the tub and can freezer the rate is dependent on the factors: 1. Proportion of salt and ice; 2. amount of brine; 3. mixture of salt and ice and brine; 4. speed of freezer; 134 FREEZING PROCESS 135 136 THE BOOK OF ICE-CREAM • 5. temperature of materials when put into freezer; 6. materials in mix. Ice-creani should not be frozen too fast or too slowly nor for too long or short a period. If the extremes occur, the quality and quantity are affected. Results of freezing too rapidly: 1. Cannot obtain swell. 2. Causes cream of poor quality. 1. Soggy or heavy — due to lack of air space. 2. Grainy in texture. 3. Does not hold well in storage. Results of freezing too slowly: 1. Cream is liable to churn, causing chunks of butter in the ice-cream. 2. Greasy ice-cream. 3. Cannot obtain swell. 4. Ice-cream usually lumpy. . Results of not freezing enough: 1. Ice-cream is watery. 2; Ice crystals separate while hardening 3. Do not obtain proper swell. 4. Fat rises to surface of the ice-cream. Results of freezing too much or too long: 1. Liable to churn cream. 2. Lose swell. 3. Ice-cream is liable to be greasy. 4. Ice-cream is soggy and heavy. The rat^ of freezing can be regulated much easier in the brine than in the tub and can freezer. In the former FREEZING PROCESS 137 the condition of the ice-cream can be seen without stop- ping the machine, and also the temperature taken. On the other hand, with the tub and can freezer, the machine must be stopped each time and the cover removed in order to see the condition of the ice-cream or to take the temperature of it. With the brine freezer the rate of flow of the brine can be regulated. The temperature of the brine alone is not important, but the rate of flow must be considered. In the tub and can freezer the pro- portion of -ice and salt can be regulated, but this is not very satisfactory. The ratio of salt to ice regulates the rate of freezing. (See page 108.) Usually one part salt to twelve to eighteen parts of ice is the correct proportion. The finer the ice and salt, the more rapid the freezing. The rate of freezing is also affected by the amount of sugar and solids in the ice-cream. The effect of sugar on the temperature is shown in Table V. Table V Effect of sugar on freezing Percentage of sugar Temperature of freezing in solution Degrees F. Skim-milk 31.03 5 per cent solution of sugar 30 . 40 10 per cent " " " 29.70 14 per cent " " " 28.60 25 per cent " " " 27.07 The effect of a large percentage of sugar on the freezing is especially noticeable in the case of sherbets and ices. These freeze much slower than ice-cream. 110. Proper method of freezing. — The question might be asked as to the proper way to freeze ice-cream. Be- cause of the many factors involved, the only direct answer is to state that the process should result in a mellow body, 138 THE BOOK OF ICE-CREAM smooth texture and medium swell. The colder the mix when it enters the freezer, down to 40° F., the better the control. It should take from twelve to twenty minutes to freeze. The mix should be cooled quickly to 32° F., then the flow of brine partly shut off and the cream al- lowed to whip. When the cream is nearly whipped, the brine should be turned on gradually and the cream allowed to freeze. When the mix is partly frozen, the fruit should be added, soon enough so that there will be time for it to become uniformly distributed in the mix. It is the usual practice to crush the whole fruits before putting them in the freezer. This can easily be done by forcing them through a food chopper. The cream should come from the freezer at a temperature of 26° F.-28° F. The appearance of the ice-cream and its temperature is a good index when frozen enough. It should have its peculiar characteristic (dead) not shiny appearance. When the thermometer is placed in the freezer and drawn out, the ice-cream should adhere to it and the part re- maining on the thermometer should retain its identity for a few minutes. Experiments * show that between 29° F. and 26° F., the volume of the ice-cream increases as the cream whips. The flow of brine, therefore, should be regulated so that the cream will be at the temperature at which it will whip, for the maximum of time. If the freezer is run with the mix too warm, the cream will churn, and if the mix is too cold, the cream will not whip. In a tub and can freezer it is difficult to control the factors regulating the rate of freezing. When the mix begins to thicken and so turns hard, the speed of the * Washburn, R. M., "Principles and practice of ice cream mak- ing," Vt. Exp. Sta., Bui. 155, 1910. FREEZING PROCESS 139 freezer is increased. This beats up the ice-cream and causes more swell. When the dasher and ice-cream are removed, the freezing-can will float in the brine, causing considerable difficulty when the next mix is ready to be frozen, since it will not easily go back in place. If the freezing-can cannot be centered in the tub, the cold brine should not be wasted, but should be dipped out and poured back after the can is in place. This saves con- siderable ice. In many plants, no attempt is made to center the can in the brine, this being dipped out as soon as the ice-cream is removed. One of the important factors in freezing is to obtain the proper swell. So far as this is concerned, the time to draw the ice-cream from the freezer can be told by the over-run tester. (See Chapter XIV.) 111. " Over-run " or " swell." — It should be the aim of the person freezing the ice-cream to obtain the proper over-run with each freezer. A large number of factors affect the amount of swell, and the possible combinations of these must be known. If too much swell is obtained, the ice-cream will be very porous, light and fluffy, and have a grainy texture; if not swell enough, it will be very' heavy and soggy and may or may not be grainy in tex- ture. For the best results, a medium swell is to be desired. The factors affecting swell * may be divided into two general classes: kind and preparation of materials used, manner or method of freezing. * Washburn, R. M., " Principles and practice of ice-cream-mak- ing," Vt. Exp. Sta., Bui. 155, 1910; Baer, A. C, " Ice-cream making," Wis. Exp. Sta., Bui. 262, 1916; Mortensen, M., " Factors which in- fluence the yield and consistency of ice-cream," la. Exp. Sta., Bui. 180, 1918; Ellenberger, H. B., " Swell in ice cream," Thesis, Grad- uate School, Cornell Univ., 1915. 140 THE BOOK OF ICE-CREAM I. Kind and preparation of materials used. 1. Age, viscosity, acidity, and fat-content of milk and cream. 2. Size of fat globules in cream. 3. Ageing of mix. — 4. Pasteurizing of milk and cream. 5. Use of homogenizer. 6. Use of emulsor. 7. Methods of mixing. ,.^-S-. Use of condensed mix. 9. Amount of sugar. 10. Different kinds of flavoring. 11. Fillers and binders. 12. Total solids in mix. The older the milk and cream and the more acidity they contain, the more viscous they will be. This is to be desired since it will whip more readily. For test for viscosity, see Chapter XIV. The more fat present in the milk and cream the more viscous they will be and the smaller the fat globules, the more the cream and milk will whip. It is commonly known that in order to obtain viscosity and swell, aged cream must be secured. Instead of ageing the milk and cream, some manufacturers age the whole mix. If only the former are aged and these should sour, they could be churned into butter. How- ever, if the sugar and flavoring are added to the mix and the whole aged and in the process become sour, the cream would not make good butter when churned. Therefore, there is danger of greater loss when the whole mix is aged. Pasteurization temporarily destroys the viscosity of the milk and cream and as a result pasteurized cream must be aged longer to restore the viscosity. The homogenizer and emulsor breaks the solids of the milk and cream into FREEZING PROCESS 141 smaller particles. In some plants the whole mix is homog- enjzed_or_ emulsified before going to the freezer. This increases the viscosity and because of this and of the smaller particles, more swell is possible without sacrificing quality. With the emulsor, cream can be made from butter and skim-milk, but it lacks, the force of the homogenizer, and so cannot break up the solids as can the latter. Emulsi- fied cream is more viscous than raw cream of the same age. While mixing, care should be exercised not to churn the cream. If churning takes place, it reduces the solids and so the possible swell. By the use of condensed or powdered milk, the amount of total solids in the mix is increased. Condensed milk usually causes the mix to become more viscous. The amount of sugar is important only because of its bulk; the more sugar added, the more solids in the ice-cream. The swell is affected by the flavoring since some flavors add more bulk. Authorities disagree as to the effect of binders and fillers on swell. If some cause an increased swell, this is very slight. The total solids in the mix have a decided influence on the amount of swell that can be obtained without injury to the quality of the ice-cream; the more solids in the mix, the more swell. II. Manner or method of freezing. 1. Speed of dasher in freezer. 2. Temperature of mix entering the freezer. 3.- Temperature of brine and rate of flow. 4. Temperature of mix while whipping. 5. Time of whipping. 6. Total time to freeze. 7. Temperature of ice-cream when drawn from freezer. 8. The amount of mix in the freezer. 142 THE BOOK OF ICE-CREAM The manufacturers of the different freezers have studied their machines and determined the speed at which they should run. The ice-cream-maker should see that the freezer runs at the speed indicated. The nearer the temperature of the mix to 40° F. when put into the freezer, the easiej; it is to obtain the swell. Mortensen * says "that a temperature of about 6° F. for the circulating brine would be the most desirable when using a 20 per cent raw cream. For pasteurized cream a temperature of from 8 to 10° F. gave the best results, while for emulsified cream about 10° F. and for homogenized cream 14° F. proved the most satisfac- tory." No record of the rate of flow of brine is re- corded. The temperature and flow of the brine should be such that the desired swell is obtained together with the quality. Washburn f shows that the mix whips at certain tem- peratures, usually from 32° F. to 29° F. The length of time of whipping has a decided influence on the quality of the ice-cream and the amount of swell. The total time to freeze has a noticeable effect on the quality of the ice-cream and the amount of swell. If frozen too quickly, swell will not be obtained and if too long, swell will be lost. Washburn { proves that the temperature at which the ice-cream is drawn from the freezer has a marked effect on the swell. If frozen too cold, the swell is lost. * Mortensen, M., " Factors which influence the yield and consist- ency of ice-cream," la. Exp. Sta., Bui. 180, 1918. t Washburn, R. M., "The principles and practice of ice-cream- making," Vt. Exp. Sta., Bui. 155, 1910. J Washburn, R. M., "The principles and practice of ice-cream- making," Vt. Exp. Sta., Bui. 155, 1910. FREEZING PROCESS 143 According to Mortensen,* the amount of mix in the freezer influences the swell. For the best results, the freezer should be about half full. Certain combinations of the factors mentioned above will increase the swell, while certain ones will decrease it. To obtain swell: 1. Have viscous milk and cream. 2. Age the milk and cream or mix. 3. If pasteurized milk and cream are used, they should be aged until viscous. 4. The cream and milk or whole mix should be homogenized or emulsified. 5. Condensed milk in the mix would aid in obtaining swell. 6. The mix should contain at least 30 per cent of total solids. 7. The dasher should run at the required speed. 8. Mix should enter freezer as near 40° F. as possible. 9. There should be a . supply of cold brine, from 6° F. to 10° F. 10. The cream should be whipped for a moderate time in the freezer. 11. The mix should fill the freezer half full. 12. It should require 12-20 minutes to freeze. 13. The ice-cream should not be below 27° F. when drawn from the freezer. The converse of these conditions will cause a decrease in the amount of swell. 112. Condition of ice-cream when removed from freezer. — ^When taken from the freezer, the ice-cream is in a semi-solid condition. It is soft enough to flow * Mortensen, M., " Factors which influence the yield and con- sistency of ice-cream," la. Exp. Sta., Bui. 180, 1918. 144 THE BOOK OF ICE-CREAM from one container to another and yet hard enough to retain the incorporated air. In order to use the freezer over and over, the ice-cream is usually placed in pack- cans to harden. A parchment paper is put over the top of the can before going to hardening-room. The ice-cream can be drawn from brine freezers directly into the pack- cans. With the tub and can ice freezers, it is necessary to dip the ice-cream from the freezer into the pack-cans. This is more easily done if the dasher is first removed. 113. Freezing sherbets and ices. — The foregoing state- ments apply to ice-cream and may or may not be applica- ble to sherbets and ices. Because of the higher percentage of sugar and water, the latter usually freeze more slowly. Any difference in procedure is noted under the receipt for sherbets and ices. CHAPTER XI HARDENING ICE-CREAM Ice-cream which is of good quahty up to this stage in the manufacturing process may be spoiled or the quahty impaired by improper hardening. The object, as its name indicates, is to harden the semi-frozen product after it is frozen in the freezer. During the time that the ice- cream is hardening, the flavors of the different ingredients blend to give the desired characteristic flavor. 114. Methods of hardening. — The ice-cream may be hardened in the freezer, but this allows only one mix to be frozen and the machine cannot be used again until the product is consumed. This method is ordinarily followed with the small hand freezers. With the larger freezers, however, the ice-cream is hardened in pack- cans (Fig. 25) or bricks. (Fig. 58.) This allows the freezer to be used over and over. The ice-cream can be drawn directly from the brine freezer into the pack-cans or bricks; however, with the salt and ice freezer, the ice- cream must be dipped by hand. Various ladles or scoops have been devised for this purpose. (Fig. 53.) These are more or less rounded on the edge to scrape the sides of the freezing-can. The ice-cream in the pack-cans or bricks may be hard- ened in any one of several ways: packing in an ice and salt mixture, setting in cold brine, setting in a cold room called a hardening-room. The first two are not advisable for a large ice-cream plant because of the work and space required. 145 146 THE BOOK OF ICE-CREAM 115. Hardening in ice and salt mixture. — When the ice-cream is hardened in a salt and ice mixture, the cans are placed usually in a large plank box, Fig. 54, so that there will be a space of four to six inches between the cans and the box. The size of the box will be determined by the amount of ice-cream manufactured. If five-gallon cans are used, it is advisable to build the box in com- partments which will hold six. This will require a box 26 inches wide by 32 deep by 36 long, outside measurement, with a hinged cover for each compartment. The box should be made of two-inch matched lumber so that it will not leak. There should be a hole in the side near the bottom so the brine can be drawn off. Be- fore beginning to freeze, it is advisable partly to pack the cans in the box. A layer of four to six inches of cracked ice should be placed in the bottom of the box, then the cans placed in position and the box filled about two-thirds the height of the can with cracked ice. Some salt should be sprinkled on the ice and the box filled to the top of the cans with cracked ice. This cools the cans so that there will be no melting when the ice-cream is put in. The ice- cream may be poured directly from the freezer into the pack-cans or first it may be put into some container which is easier to handle and then poured from it into the pack- can. When all the cans in the compartment are full, Fig. 53.- -Different styles of transfer ladles or scoops. HARDENING ICE-CREAM 147 they should be covered to a depth of four to six inches with ice and salt. These may be mixed before putting in Fig. 54.— Plank box for hardening ice-cream in a salt and ice mix- ture. The cans are placed in perforated cylinders so that they may be changed and the ice will not fall in and fill the space. the box or they may be placed in alternate layers. The proportion of salt to ice for hardening is about one part 148 THE BOOK OF ICE-CREAM of salt to eighteen or twenty parts of ice by weight. Most of the salt should be placed in the upper third of the ice, because as the ice melts the salt goes into solution and so is carried to the bottom of the box where it comes into contact with ice where there is little or no salt. For packing, a coarse salt is to be preferred as it dissolves more slowly. After standing overnight in the pack-cans, the ice-cream should be hard. It may be shipped out or held until wanted. If shipped the cans may be packed in tubs, observing the same precaution of placing the salt in the upper third of ice. Instead of packing in a tub, the cans may be put in a box or cabinet on the delivery wagon. If the ice-cream is to be held in the hardening- box, it should be repacked twice a day. This is done by jamming down the ice and salt. The cans should then be recovered with ice and salt. The brine which forms should be allowed to escape from time to time so that it will not run into the cans or cause them to float. The following figures on the amount of ice and salt used were obtained by the '' Ice-Cream Trade Journal." * They are the average of a number of plants: Average output of ice-cream per day, summer 395 gallons " " " " '' winter 43 " Amount of ice used per 100 gallons of ice-cream. . . . 1928 pounds for freezing 614 for hardening and storage 914 for shipping delivery or cabinets .... 400 Amount of salt used per 100 gallons of ice-cream . . . 190 for freezing 73 for hardening and storage 82 for shipping delivery or cabinets . ... 35 116. The slush-box or brine-box method of harden- ing. — In this method, the pack-cans instead of being * "Ice-Cream Trade Journal," Vol. V, No. 6. HARDENING ICE-CREAM 149 packed in iee and salt are placed in a box or tank of brine. This brine is usually cooled by means of a mechanical refrigerating system, and circulated with a pump. Great care must be exercised or the brine will get into the ice- cream. 117. The hardening-room. — In the large ice-cream plants, a cold room is maintained in which the pack-cans are set to harden. This room is cooled by mechanical refrigeration and the temperature should be very near 0° F. or below. There are three general types of harden- ing-rooms, depending on the location of the evaporating coils and the air circulation. 118. The still-air type. — This type of hardening- room is used in the smaller ice-cream plants. The evapo- rating coils are placed directly in the hardening-room and usually arranged in such a way that shelves are formed with parts of the coils on which the cans of ice-cream are put to harden. (Fig. 55). 119. The gravity-air type. — In this system the coils are placed in a bunker-room directly over the hardening- room and designed so the air will circulate in a natural manner. 120. The forced-air type. — This system locates the eoils in a bunker-room usually, directly over the harden- ing-room, and the air is forced to circulate by means of a fan or blower. (Fig. 56). The forced-air system is con- sidered the most efficient. The effect is the same as the temperature of the air on the body. With the same temperature, the cold is more noticeable and more pene- trating on a windy day than when the air is still. The same is true in the hardening of the ice-cream. The objection to the still-air hardening-room is the longer time required to harden the product. The objection to 150 THE BOOK OF ICECREAM Fig. 55. — Still-air hardeningTroom showing evaporating coils forming shelves on which the pack-cans of ice-cream are placed to harden. Other evaporating coils may be seen on the sides and ceiling. HARDENING ICE-CREAM 151 the forced-air room is the danger of losing too much refrigeration when the doors are opened unless the fan causing the air circulation is stopped before opening. 121. Defrosting the coils.* — "One of the most trouble- some things to be contended with in ice-cream hardening- rooms, cooled by means of refrigerating machines, is the accumulation of frost or snow on the coils, and up to the present' time no thoroughly satisfactory method has been devised which will meet with success under all conditions, taking into consideration, method of operation, design of coils, and the like. "The most serious objection to this accumulation is the loss in efficiency, which may amount to as much as 50 or 75 per cent, depending on the thickness of the coat- ing and the interference with the air circulation. The other objections are of minor importance and need not be considered here." 1. Cooper system. The Cooper system consists of a trough perforated at the bottom and placed directly over each stack of coils, and in which are put lumps of chloride of calcium. This substance, on coming in contact with moisture in the air, will dissolve slowly and drip down over the coils, thereby keeping them practically free of frost at all times. ; It may be asserted that this is not a defrosting device ; however, prevention is better than cure. This system can be applied to the first and second types of rooms, as in these cases the floor under the coils is made water-tight and arranged to catch the drip from the coils. It is not suitable for use in the third type, however, as the drippings would fall upon the cream-cans * Carpenter, M. R., "Defrosting of coils in hardening-rooms." "Ice-Cream Trade Journal," Vol. XI, No. 4. 152 THE BOOK OF ICE-CREAM and on the floor of the room. It is possible to catch these drippings and by boihng or evaporation recover the calcium, which can be used over again or in strengthening the brine in the tanks. Fig. 56. — Forced-air hardening-room. The objection to this system is the labor involved in placing it in the troughs, for usually the coils are close together and are in a room with little space around and over themlfor a man to work; also, the rooms being cold, it is a very uncomfortable task. It may be possible, in HARDENING ICE-CREAM 153 designing rooms, to provide space in which to work, or to fill the cans outside the room and then place in posi- tion. 2. Cold hrine drip system. This system consists of a means of spraying cold brine (calcium or salt) over the coils. Over each stack of coils is placed a trough, slotted or perforated pipe, similar to the water pipe or trough on atmospheric condensers. Brine from the main tank or circulating system is turned into the trough and allowed to drip over the coils either continuously or intermittently as may be required. In this system the brine must be very strong or it will freeze on the lower coils, especially if the frost is allowed to accumulate to any extent before defrosting, or unless the coils are out of commission entirely during the opera- tion. This brine is sometimes allowed to drain directly back into the brine tank, although this is poor policy as it weakens the brine and has a tendency to make it (in the case of calcium brine) acid, owing to its contact with the air. A better way, if it is possible to do so, is to drain it back into a tank, where it can be boiled and thus brought to its proper strength before returning to the main tank. This system has the advantage of being operated with nttle labor and under comfortable conditions, providing the controlling valves are placed outside the room and of easy access. In case the frost is allowed to accumulate to any extent, this system will not work as quickly as may be desired. One great advantage, however, is that it will not warm up the hardening-room, and if operated often and properly it will keep the coils free of frost and not require the room to be out of commission. This system is suitable for use in first and second types of rooms. 154 THE BOOK OF ICE-CREAM 3. Hot brine system. This is arranged the same way as the cold brine drip system as far as interior arrangement on coils is concerned, but instead of using brine from the main tank, a special tank with steam coil is provided and the brine is pumped into the trough in a hot condition and allowed to drain directly back into the tank. This system is quick in its results. A heavy deposit of frost can be removed in this way and it is easily operated. The principal objection is the great amount of moisture it will cause to be deposited on the walls and ceiling of the room. It also requires the room to be out of com- mission a short time while being operated. However, it does not seem to have much effect on the temperature after it is shut off. This method can also be made a cold brine system by boiling off after using, then letting it stand until it is cold before utilizing again. However, it will still deposit some moisture and it has been found best to keep the room out of commission while operating. Another tank with refrig- erating coil placed so as to cool this brine before using might be beneficial, although in this case it resolves itself into sys- tem No. 1. This can be applied to first and second types. 4. Air blast system. In this system the air is so designed that the bunker- room can be shut off from the hardening-room and open- ings arranged so that the circulation fan can draw warm air from outside, blow it across the coils and discharge it at the opposite end. This is a very satisfactory and quick method, although it leaves some moisture deposited on the walls of the room and has a tendency to warm things up a little. This system, of course, needs a fan and is suitable for the first type only. HARDENING ICE-CREAM 155 5. Hot gas system. This is a radical change from those systems considered, as it works from the inside out. The success of this system depends on the design of the coils, headers and connec- tions. The coils are arranged in such a way that they are, by opening and closing a few valves, converted into an ammonia condenser with the hot ammonia gas from the discharge of the compressor entering the top pipe of coils, and, as it is liquefied, running by gravity back to the ammonia receiver. In operating, it is necessary to have the room out of commission unless the coils can be arranged in independent batteries. This system can be applied to any type of room pro- vided the coils are properly designed and the receiver on a level below the lowest coil. Also, there must be enough additional refrigeration to enable the compressor to continue in operation in order to supply the hot gas. 6. Warm liquid system. The coils, headers and piping are so arranged that the liquid ammonia on its way to other rooms can be passed through coils which are to be defrosted. It is self-evident that it is necessary to maintain the same pressure on these coils as obtains in the main liquid line, also that a considerable amount of ammonia must be expanding at other points in order to keep a quantity of liquid flowing through the coils. When conditions are right, this system is very satis- factory, as it can be operated with a minimum of labor and has the advantage of conserving all the energy previ- ously expended in freezing the ice on the coils. In apply- ing, special consideration must be given to the method by which the ammonia is fed into the coils. It is more easily applied to the flooded system, as in this case it is 156 THE BOOK OF ICE-CREAM only necessary when defrosting is completed to cut off the flow of hot liquid, open the suction line from coils and allow the liquid remaining in the coils to expand or evapo- rate to accumulator, without danger of flooding over into the compressor. After this liquid is partly evaporated, the valve on the feed line from accumulator is opened, and the coils are again in full operating condition. In applying this system to direct expansion coils, care must be exercised to provide means either to drain the liquid back into the ammonia receiver before opening the outlet from coils into the main suction line, or to expand this liquid through other coils; otherwise, the liquid is Hable to reach the compressor with disastrous results. The application of this system should be attempted only by those thoroughly competent to consider all phases of the situation and if properly applied is one of the most efficient and satisfactory methods of defrosting yet de- vised. It can be applied to practically any type of room providing, as stated, the other conditions are suitable. It has been the writer's experience that the coils in forced-air circulating types give the most trouble, due to the heavy frost, partly from the very rapid accumulation and partly for the reason that these coils being out of sight are more hkely to be neglected, and after the ice has become very heavy it is exceedingly difficult to get it all off, without keeping the room out of use for a long time. The gravity system also gives some trouble, but is not affected quite so quickly as the forced-air type, owing partly to the design of the coils which necessitates greater space between pipes. The still-air type causes very little difficulty and some of these have been run a whole season without being defrosted and without having their effi- ciency materially reduced. HARDENING ICE-CREAM 157 A large percentage of hardening-rooms have no arrange- ments for defrosting and as a result it is often necessary to shut down and remove the ice. All kinds of methods are used, such as scraping by hand, spraying with water by means of a hose, placing salamanders in the room or simply leaving the doors open and allowing the temper- ature of the room to rise to such a point that the frost will melt. 122. Time required for hardening.— The time neces- sary for hardening varies, but usually .twelve hours is sufficient. The time depends on the rate of removal of heat or the amount of cold supplied and the insulation. The refrigerating boxes should be well insulated. This is especially necessary because of the great difference between the temperature of the hardening-room and that of the surrounding atmosphere. Undoubtedly cork makes the best insulation. The thickness varies, but it should be at least six or eight inches thick. Cork should be kept dry or it is not a good insulator. When the ice-cream becomes hard, it should be held at a low enough temper- ature so that it will not soften or melt. After hardening, if the ice-cream melts or sdftens it is liable to cause the separation of the ice crystals and so result in a grainy textured product. If it becomes soft, the fat is likely to rise unless the cream has been homogenized. Ice-cream should not be held in the hardening-room for more than seven days. When an ice and salt mixture is employed to harden -the ice-cream, the rate of hardening is determined by the amount of salt used. The coarse, slow dissolving salt is to be preferred for hardening. 123. Effect of hardening on quality. — The two quali- ties of ice-cream affected by hardening are the flavor and 158 THE BOOK OF ICE-CREAM body and texture. While hardening, the flavors of the different materials used blend to give the desired charac- teristic flavor. Some flavors, especially vanilla, will freeze out while hardening. The body and texture are affected only through neglect. If the paek-cans are allowed to stand after they are filled, before being placed in the hardening-room, some of the ice-cream next to the sides and bottom will melt, causing a grainy or icy texture. The same may occur if there is water in the bottom of the pack-cans when the ice-cream is put in. 124. Fancy molded ice-cream. — There are two kinds of fancy molded ice- cream, bricks and molds to represent various objects. The ice-cream is the same with the exception of the form in which it is hardened. Some- times a little more stabilizer is used to make the cream more firm. The brick offers many possible combinations. Each kind of ice-cream is put into the brick in a layer. Each layer is leveled with a brick trowel. This trowel is square on the end and just the width of the brick. (Fig. 57.) A different flavor and color of ice-cream forms each layer. In some cases the center is a sherbet or pudding. Mortensen suggests a center layer of solid frozen fruit and calls such ice-cream Aufait. The size of the brick varies from a pint to several quarts. (Fig. 58.) It is the custom- ary practice to use sectional bricks (Fig. 58) which are the exact size to hold six to eight quart bricks. These may have a single or double lid. When hard, the ice- FiG. 57. — Brick ice-cream trowels. Straight and bent handles. HARDENING ICE-CREAM 159 cream is taken from the sectional brick and cut into either quart or pint sizes. In a large factory, a special hardening-room is employed for brick ice-cream, which is kept as near 0° F. as possible. (Fig. 59.) The contents Fig. 58. — Quart and sectional brick molds. The sectional bricks hold several quarts. are taken from tbe brick mold by applying cold water until sufficient frost has been drawn from the mold to allow the ice-cream to slide out. When a large number is made, a special brick-cutting machine may be used. This will cut the bricks much faster and more uniform in size than by hand. Sometimes if a knife is run around the 160 THE BOOK OF ICE-CREAM sides of the brick it will help loosen the ice-cream. Care should be taken not to melt the ice-cream too much. In some instances the bricks are packed in square, in- stead of round pack-cans for delivery. In this case a large number of bricks would be delivered to the same place. The bricks are wrapped in parchment paper, put into paper cartons and packed in ice and salt for delivery. Fig. 59. — Brick hardening-room. By means of a specially devised mold or brick known as a center mold (Fig. 60), any letter, figure or form of object may be made in the center of the ice-cream. To accomplish this, two different colored ice-creams must be used. The form is produced by having one cover of the mold with a tube of the desired shape to form the center figure. The space around the tube is filled with one colored ice-cream and the tube or center with the color desired in the center. When the brick is sliced, this design is in the center of each piece of ice- cream. HARDENING ICE-CREAM 161 By means of special molds, ice-cream may be hardened to represent almost any object. (Fig. 61.) These molds Fig. 61. — Individual ice-cream molds and ice cave for packing molds. are hinged pewter metal. They vary in size from one or two quarts to an individual service. These cannot be 162 THE BOOK OF ICE-CREAM packed in an ordinary pack-can without jammingo They usually are wrapped separately with waxed paper and hardened and delivered in an ice cave (Fig. 61), which consists either of a round or square pack-can into which a frame with shelves fits. The molds of ice-cream are placed on these shelves. CHAPTER XII JUDGING AND DEFECTS OF ICE-CREAM The judging of ice-cream is the comparing of one product with another or of the one in question with the ideal. In order to make this comparison more simple, a score-card has been devised. This gives a numerical value to each of the characteristics of the material to be judged and makes comparisons easy. The judge should be familiar with the various qualities and defects of the material under his inspection. 125. Score-cards. — Several score-cards * have been suggested for ice-cream, but no one is in universal use as is the case with both butter and cheese. In the New York State College of Agriculture at Cor- nell University, two score-cards are used. They are as follows: Score-card No. 1 Score-card No. 2 Flavor 45 Flavor 40 Body and texture 35 Body and texture 25 Richness 10 Bacterial count 15 Appearance 5 Richness 10 Package 5 Appearance 5 Package 5 Total 100 Total 100 * Baer, A. C, "Ice-cream-making," Wis. Exp. Sta., Bui. 262, 1916; Mortensen, M., "Classification of ice-creams and related frozen prod- ucts," la. Exp. Sta., Bui. 123, 1911; Washburn, R. M., "Principles and practice of ice-cream-making," Vt. Exp. Sta., Bui. 155, 1910; Frandsen, J. H,, and Markham, E. A., "The manufacture of ice- cream and ices," Orange Judd Company, 1915. 163 164 THE BOOK OF ICE-CREAM These score-cards consider the same characteristics except that No. 2 includes the bacterial count. Naturally the inclusion of another characteristic changes the nu- merical value of the others. Score-card No. 1 is for use only when there is not time to make a bacterial count, such as for laboratory work. When an exact comparison is desired, the bacterial count should be made. If un- desirable or large numbers of organisms are present, they affect usually the flavor and body and texture, although this is not always true. For this reason, the numerical value given to bacterial count has been taken from flavor and body and texture. 126. Explanation of characteristics mentioned in score- card. — If the ice-cream is to receive a perfect score, the characteristics should be as defined. If not, the ice- cream is defective and the score should be cut. Flavor. — The ice-cream should have a pronounced flavor which will blend with that of the cream to give a clean, desirable typical flavor. Body and texture. — The body should be firm and mellow. It should not be tough or rubbery, neither soft or mushy. The texture should be smooth and velvety and entirely free from graininess and lumpiness. Richness. — If the ice-cream meets the legal require- ments, it should be given a perfect score. If it falls below, it should be scored zero. Appearance. — The ice-cream should have an attractive appearance and be of the characteristic uniform color. Package. — The package should be neat and clean and, if for long shipment, some provision should be made to protect the ice on top of the packing-tub. Bacterial count. — An ice-cream which has a count of 20,000 should be considered perfect. For each increase JUDGING AND DEFECTS OF ICE-CREAM 165 of 20,000 above this, one point should be deducted from the score. If a number of samples is to be scored, it is the usual custom to examine several to gain an idea of how the quahty runs. This is called establishing a key or stand- ard. When this has been done, all the samples can be scored and the best will not be rated too high nor the poorest too low. 127. Defects in ice-cream. — It is almost impossible to make an ice-cream which does not have some defect. These can be discussed best under the characteristics as given in the score-card. 128. Defects in flavor of ice-cream are largely due to objectionable flavors in the materials employed, or to the use of too much or too little of certain ingredients. Some of the common causes are: 1. Use of cream of bad flavor. 2. Use of cheap flavoring extracts. 3. Use of too little or too much sugar. 4. Use of materials which do not give the character- istic flavor. 5. Disagreeable. flavor due to use of poor fruits. 6. Lack of flavor due to use of too small an amount of flavoring materials. 7. Too pronounced a flavor or not pronounced enough. 8. Condensed milk flavor. 9. Salty ice-cream. 10. Gelatine or gum tragacanth flavor. . Of the ten causes mentioned all but number one are within the control of the ice-cream manufacturer. How- ever, the flavor of the cream is a very vital question and the one usually causing the greatest difficulty. 166 THE BOOK OF ICE-CREAM 129. Defects in body and texture. — The texture refers to the molecular structure. As the ice-cream is an emul- sion of materials of varying specific gravities^ it is difficult always to get these different ingredients to mix in the same manner. The greatest defect in the texture of the ice-cream is graininess. This may be caused by the incorporation of too much air or the separation of the water crystals. After the ice-cream has been transferred from the freezer to the pack-cans, the latter should be placed at once in cold surroundings; if not, the cream around the outside and bottom of the can will melt and on being hardened will be grainy, due to the melting and separation of the water crystals. Graininess may be due to a lack of binder or sometimes to the crystallization of the sugar in the condensed milk. The body of the ice-cream refers to the structure as a whole. The common defects in body are hard, brittle, soft or watery. In order to obtain an ideal body, the ice-cream must contain a certain amount of milk-fat and other solids; also this cream must be frozen properly. If the ice-cream lacks solids, the body is very likely to be soft or watery. The age of the cream, whether or not it has been pasteurized, and method of freezing, have a decided effect on the body. Sometimes in freezing the fat becomes churned; this results in chunks of fat in the ice-cream. It is caused by the freezer running too fast or by putting the cream into the freezer too warm. The following summary of two bulletins gives the effect of solids on the smoothness and keeping qualities of ice-cream and the effect of binders on the melting and hardness. These directly affect the body and texture. JUDGING AND DEFECTS OF ICE-CREAM 167 Effect of solids on smoothness and keeping quality of ice-cream: * ''1. Smoothness and keeping quality or stability of texture of ice-cream are closely associated. "2. Smoothness depends upon the amount and fine- ness of division of solids present other than those in true solution, within limits, that is, the smoothness depends upon the size and distribution of ice crystals which in turn depend upon the number and nearness together of minute sohd particles which interfere with crystallization and reduce the size of the ice crystal. ''3. Colloidal solutions of solids other than fat are best adapted to ice-cream-making. The finer the division the better. "4. The finer the emulsion of the fats the better the homogenizer has its application in this respect. "5. The keeping qualities of ice cream depend upon the stabihty of the mix. That is, the keeping qualities of ice cream made from a given mixture will depend upon the disposition of the solids in that mixture to separate from the liquid, which in turn depends upon the fine- ness of division of the solids. The finer the division, the better the keeping qualities up to the point at which the solid merges into a true solution." Effect of binders on the melting and hardness of ice- cream: t "Plain ice-cream. — In plain ice-cream (control) as the per cent of fat increases the cream becomes softer. A *Brainard, W. K., "Smoothness and keeping qualities in ice- cream as affected by solids," Va. Exp. Sta., Tech. Bui. 7, 1915. t Holdaway, C. W., and R. R. Reynolds, "Effect of binders upon the melting and hardness of ice-crean," Va. Exp. Sta., Bui. 211, 1916. 168 THE BOOK OF ICE-CREAM medium amount of butter fat, combined with other mate- rial than milk solids, produces a stiff cream. When too much fat is present whipping takes place, producing a cream that is soft and fluffy in appearance. Ice-cream made from eight per cent cream is no harder than from nineteen per cent cream, while thirty per cent plain cream is much softer than eight per cent or nineteen per cent cream. In plain ice-cream the presence of fat increases the power to resist melting. This resistance is most noticeable between the melting of the eight per cent and nineteen per cent cream. Thirty per cent cream shows the power to resist melting to a less degree. ^^ Cream containing gelatine. — Gelatine in a large or small quantity produces similar effects, depending upon the richness of the cream used. The power to withstand pressure and the melting resistance increases as the amount of gelatine increases, when compared with the control ice-cream with a similar fat content. The hardest and most heat resisting ice-cream is produced with a medium per cent of fat and a large amount of gelatine. With gelatine, the presence of fat seems to be essential to produce hardness and melting resistance until a point is reached where whipping affects the texture. After whip- ping begins the incorporated air reduces the hardness and melting resistance. Ice-cream containing one ounce of gelatine per gallon has more the appearance of pudding than ice-cream. Four ounces of gelatine gives about the same hardness as four ounces of cornstarch, but it is much better, producing a smoother cream which is more stable under ordinary conditions. ^^ Cream containing gum tragacanth. — Gum tragacanth with a low per cent of fat produces an ice-cream that is slightly harder, with slightly more power to resist heat JUDGING AND DEFECTS OF ICE-CREAM 169 than plain ice-cream. As the per cent of fat is increased with this filler, the power to resist pressure and heat de- creases, falling below plain cream, showing that gum tragacanth acts as a filler and not as a binder. Its most noticeable effects are on the texture of the ice-cream, be- cause of the nature of the gum, is to impart a smoothness which becomes sliminess when large quantities are used. ^^ Cream containing cornstarch. — When cornstarch is used as a filler a slight increase in hardness and melting re- sistance is noticeable with nineteen per cent when com- pared with eight per cent, ice-cream. Also it produces an ice-cream that has more resistance to heat than plain ice- cream of the same per cent fat. When used as a filler it compares favorably with a similar amount of gelatine but the starch ice-cream is more granular than the gelatine, while gum tragacanth produces a smooth soft cream. '^ 130. Defects in richness. — The only defect in richness is a lack of fat and sohds not fat. The ice-cream should meet the legal standards; if not it is defective. 131. Defects in appearance. — Many times the ice- cream does not have an attractive appearance. It may be rough, grainy and coarse, or partly melted. Often it will melt on the outside and run while the inside will be very hard. The ideal ice-cream is one which will have the same degree of softness throughout. The color is not always characteristic as the fruit may not be distributed uniformly. 132. Defects in package. — Anything which detracts from the neatness of the package is a defect. Badly dented or rusted cans are not attractive. The tubs may not be clean or neatly painted or lettered. The parch- ment paper circles being omitted from the top of the can constitutes a defect. CHAPTER XIII BACTERIA IN RELATION TO ICE-CREAM Much might be written regarding the factors affecting the growth of bacteria, the preparation of the media, the incubating temperature, the counting; this is all discussed in the various text-books on bacteriology. Here only the relation of bacteria to ice-cream will be considered. It is commonly recognized that ice-cream contains large numbers of bacteria. The table No. VI * on page 171 shows the average bacterial count of ice-cream and the highest and lowest counts in various cities and at different times in the same city. This table indicates that ice-cream made in different sec- tions of the United States has some extremely high counts and the average is comparatively high when one considers the count of milk and cream produced under clean condi- tions. The redeeming feature is that ice-cream can be produced with low bacterial count. This shows the need of a bacterial as well as chemical standard. 133. Sources of bacteria in ice-cream. — :There are two sources of bacteria in ice-cream, the materials employed and the utensils which come in contact with the ice-cream. The latter source is entirely under the control of the manufacturer. If materials used have a low bacterial count, there is no reason why the ice-cream should not be low in bacteria. If this is the case and the ice-cream * Hammar, B. W., "Bacteria and ice cream," la. Exp. Sta., Bui. 134, 1912, 170 BACTERIA IN RELATION TO ICE-CREAM 171 t-5 ooooooooo ^, OOOOOOOOQ ;s o"o"i>-'~o'^o"o~o"o'^o'" > < o c3 PQ o 03 QOQOOOOOO COOOOOOQO ^ so <^^P.<^ o o o o o^o^ •^ o o^o^o^o^o^o^o^o^o 05 crLf:rio"cro"o"<^ c^ t^iOO. T-H CO T— I T-l (M O rt -cS lO 5- CO ■O CO ^co <^co o O i-H '^ o o O t^ CO o o O^CO^i-H^O o o'^f^rofr-To'^ O 1— I O o o o^cq^cq^T-fH oo co'^co'cD^Lo'T-r (M (M T-i tH g^^ ;^ S Oi LO CO oo o S ^ CO CO 00 oo I <^« CO 5^ ' o '^ t^ J^ ' -^ O Q O oo O lO O Oi CO O (M (M T-l 7-1 "to §.lO CO CO Oi O rH ^O O O O ^ rH O^ O'i Oi <3:> (^ (^ o 1— I I T-\ 1— I 1—1 T—t 05 Oi o3 m IX) l^h'ojJ^ooo'^p - 172 THE BOOK OF ICE-CREAM has a high count, it would indicate that the maker was careless and the utensils dirty. EUenberger * found the minimum and maximum num- ber of bacteria in the materials used in the mix as given in Table VII: Table VII The Minimum and Maximum Bacterial Content of the In- gredients used in the Mix Minimum Maximum Standard cream per c. c. . 1,150 37,600,000 Condensed milk per c. c 31,500 59,800,000 Sugar per gram 20 255 Gelatine 48 891 Flavoring vanilla 10 321 The important fact brought out by the above table is that the milk products are the source of most of the bacteria in the ice-cream. This emphasizes the need of dairy products manufactured and marketed under the most cleanly conditions. The ice-cream-maker in most cases has little control over these factors. For the produc- tion and handling of milk, see Chapter 11. The numbers of bacteria may be reduced materially by pasteurization.! This destroys the viscosity so that milk or cream that has been aged and then pasteurized must be aged again to regain it. There is great danger while ageing either pasteurized or raw cream of a material increase in the numbers of bacteria. Great pains must be taken to cool * EUenberger, H. B., "A study of the bacterial growth in ice- cream," Thesis, Cornell Univ., 1917. ' . t EUenberger, H. B., "A study of the bacterial growth in ice- cream," Thesis, Cornell Univ., 1917; Hammar, B. W., "Bacteria and ice-cream," la. Exp. Sta., Bui. 134, 1912; Hammar, B. W., and Goss, E. F., "Bacteria and ice-cream," Part II, la. Exp. Sta., Bui. 174, 1917. BACTERIA IN RELATION TO ICE-CREAM 173 and hold or age it at a low enough temperature so that the organisms will not develop. If this is not done, the result would be practically the same as if it had not been pas- teurized, so far as numbers of organisms are concerned. Hanmiar gives the count of different samples of gelatine as follows: Table VIII Bacterial Count of Samples of Gelatine Bacteria in 1 c. c. Bacteria per of ice-cream due Sample No. gram to gelatine 1 113,000,000 565,000 2 14,000,000 70,000 3 35 0.2 4 4,200 21 5 85,000 425 This table shows the need of testing to make sure that the supply of gelatine is low in number of bacteria. Usually in the better or more expensive grades, the bacterial con- tent is lower, but this is not necessarily true. The method of preparation has much influence on the bacterial content of ice-cream. (See Chapter IV.) Sugar contains very few organisms. The greatest danger is that dirt may get into the sugar due either to exposure or sifting through the cloth sacks. The flavoring materials may have a decided influence on the bacterial content of the ice-cream. Vanilla contains very few organisms, but such flavors as fruits may have large numbers of bacteria, especially if they are not sound. Hammer * reaches the following conclusions regarding the bacterial content of the materials used in the manu- facture of the ice-cream : * Hammar, B. W., " Bacteria and ice-cream," la. Exp. Sta., Bui. 134, 1912. 174 THE BOOK OF ICE-CREAM 1. The cream unless pasteurized is the greatest source of the bacteria in ice-cream. 2. After pasteurization cream can be stored at 0° C. for several days with no important increase in the number of bacteria developing at 37° C. on agar. 3. The bacterial content of gelatine is very valuable and some probably add large numbers of bacteria to ice-cream in which they are used. 4. The vanilla extract plays a very small part in de- taining the bacterial content of ice-cream. 5. The sugar is comparatively unimportant as regards the number of bacteria in the ice-cream made with it, if it has been properly protected from dirt. All the utensils, unless clean, may be a source of con- tamination to the ice-cream. When machines are selected, the ease of cleaning should not be overlooked. All seams should be flushed with solder. This leaves no crevices in which bacteria and dirt can lodge, and makes cleaning easy. The cleaning of the freezer should receive special attention. 134. The effect of freezing and hardening on the bac- terial count. — Authorities agree that there is an increase in the number of organisms in ice-cream during the freezing process, as determined by the plate method. This may be accounted for by the agitation in the freezer breaking up the clusters of bacteria. This cluster would give only one colony on a plate, but after being broken up might result in several colonies. This is not a real increase in the number of bacteria. The same holds true with other machines, such as the clarifier.* * Hammar, B. W., " Studies on the clarification of milk," la. Exp. Sta., Res. Bui. 28, 1916; Mclnerney, T. J., "Clarification of milk," N. Y. Cornell Exp. Sta., Bui. 389, 1917. BACTERIA IN RELATION TO ICE-CREAM 175 Ellenberger found that there were no radical changes in the total number, of bacteria in ice-cream during harden- ing. There seems to be a tendency toward a slight de- crease in the first two or three days with a more noticeable increase and corresponding decrease again between the sixth and twentieth days, after which there is only a very gradual falling off in numbers. The lower temperatures may have a destructive effect on some types of organisms. There may be a reorganization with the survival of the fittest. 135. Types of organisms in ice-cream. — The bac- terial flora of ice-cream in summer and winter was studied by Ayers and Johnson.* They divided the samples into summer and winter and the bacteria into groups by the milk-tube method of differentiation. Table IX Showing the Groups of Organisms and the Percentage in Each Group 28 Winter samples per cent .30.84 .38.03 . 4.81 . 5.42 .20.90 71 Summer samples per cent Acid-coagulating group 49 . 82 Acid-forming group 20 . 72 Inert group 13 . 98 Alkali-forming group 1 . 86 Peptonizing group 13 . 62 136. The total-acid groups. — ''As seen in Table No. IX of the average bacterial flora of summer ice-cream 70.54 per cent is made up of the total group of acid- forming bacteria, and during the winter 68.87 per cent. While using the milk-tube method of differentiation the * Ayers, S. H., and Johnson, W. T., Jr., "A bacterial study of ice- cream," U. S. Dept. Agr., Bui, 303, 1915. 176 THE BOOK OF ICE-CREAM reactions of the litmus milk tubes are recorded after 2, 5 and 14 days, and the total acid-forming group is composed of those bacteria which produce acid in litmus milk during the 14 days' incubation. Those bacteria which form acid and peptonize the milk are included in the peptonizing group. The total-acid group can be further divided into those which produce acid and coagulate the milk and those which simply form acid within 14 days. Since the reaction is recorded after 2, 5, and 14 days, the rapidity of the growth of the acid-forming bacteria can be determined, and this serves as an additional means of separating the group. In Table No. X the percentages of the acid- coagulating and the simple acid-forming groups of bac- teria are shown, based on the 2, 5 and 14 day reaction in litmus milk." Table X Changes in the Percentage of the Total-acid Group of Bacteria in Ice-cream when Determined by Litmus-milk Reactions after Various Lengths of Incubation Per cent reacting after incubation for Bacterial group 2 days 5 days IJf. days per cent per cent per cent Averages of 71 summer samples: Acid-coagulating 26.31. . . .41.52. . . .49.82 Acid-forming 35.43. . . .25.58. . . .20.72 Average of 28 winter samples: Acid-coagulating 8.20 25.02 30.84 Acid-forming 44.51 41.30 38.03 "An examination of Table No. X shows that among the summer samples 49.82 per cent of the bacteria pro- duced acid and coagulated the milk after 14 days. After 2 days 26r31 per cent produced this reaction. This shows that a little more than half, or 52.81 per cent of the bacteria BACTERIA IN RELATION TO ICE-CREAM 177 which were in the ice-cream produced the reaction within 48 hours. The remaining 47.19 per cent coagulated milk more slowly and may represent a different variety of acid- forming bacteria. Turning again to the table and con- sidering the acid-coagulating group of the winter series, it will be seen that of the 30.84 per cent which produced the reaction only 8.20 per cent produced acid and coag- ulated milk in 2 days. Therefore only 26.69 per cent of the acid coagulating group of the winter samples were active enough to produce the reaction in 48 hours, while 52.81 per cent of this group in the summer samples brought about the change in 2 days. ''There is little to be said regarding the acid-forming bacteria which simply produce acid. Many of them grow slowly and do not show an acid reaction for several days in litmus milk. The milk-tube method furnishes a means of determining the difference in the rapidity with which the bacteria produce acid. As may be seen in Table No. X the percentage of the acid-forming group of bacteria was highest when determined by the 2-day reactions and lowest when based on the 5 and 14 days' reactions. This is explained by the fact that many bacteria have simply formed acid after two days in litmus milk and later may coagulate or peptonize the milk, and are therefore thrown into another group." 137. The inert group. — "The inert group of bacteria in ice-cream comprises those which produce no change in lit- mus milk during the 14 days' incubation at 30° C (86° F.). By this method of grouping there are, of course, included in the inert group those cultures which fail to grow in milk and tubes of litmus milk, and which would also be included even though the lack of growth were caused by failure to inoculate the tubes properly. However, this 178 THE BOOK OF ICE-CREAM last possibility is small. The inert group is of little in- terest, on the whole, since the bacteria produce no apparent change in milk, and in all probability the same is true of ice-cream.'' 138. The alkali group. — "The alkali-forming group of bacteria is made up of organisms capable of producing an alkaline reaction and no other apparent change in litmus milk during the 14 days' incubation at 30°C (86°F) . This group does not include bacteria which produce an alkaline reaction together with visible signs of peptonization. While there are in the literature references which deal with types of alkali-forming bacteria, this group has rarely, if ever, been considered when the flora of milk has been under discussion. The authors in some previous work on bacteria in milk showed that considerable numbers of this group were present in milk. In a later piece of work we have shown the numbers of this type of bacteria in milk, together with some of the cultural reactions of the alkali-forming bacteria. These bacteria, however, give very few positive reactions with the usual cultural media, and it is impossible to give much information regarding this group. A detailed bacteriological and chemical study of these organisms is under way in the research laboratories of the Dairy Division. "It will be seen from Table XI that during the summer series of ice cream samples the average sample contained 1.86 per cent of the alkali group of bacteria, and during the winter series 5.42 per cent. In general, the alkaline reaction is not noticeable until after four or five days' incubation in litmus milk. Occasionally, however, the reaction is in evidence in 48 hours. This group percentage for the summer season was 1.86 after 14 days and only 0.15 per cent based on the 2-day reaction. Therefore, BACTERIA IN RELATION TO ICE-CREAM 179 only 8.06 per cent of the bacteria of the alkali group pro- duce an alkaUne reaction within 48 hours. Among the samples collected during the winter season only 3.13 per cent of the bacteria of this group were capable of producing the reaction within two days. Whether this indicates a different variety of organism can not be said with assur- ance." Table XI Changes in the Percentage of the Alkali Group of Bacteria in Ice-cream when Determined by Litmus-milk Reactions after Various Lengths of Incubation Per cent reacting after incubating for Alkali group 2 days 5 days U days per cent per cent per cent Average of 71 summer samples . 15 ..... 1 . 03 1 . 86 Average of 28 winter samples 17 4.00 5.42 ''At present we are unable to state the significance of this group of bacteria in milk and ice-cream, but it is evident that they are not present in ice-cream in large numbers, as are the bacteria of other groups. ''Alkali-forming bacteria were not found in each sample examined, but this does not prove that there were none present in the ice-cream. Since these organisms are present in small numbers compared to the rest of the , bacteria, it is not surprising that none should be found on plates in which the dilution had to be high in order to take care of the large total number of organisms." 139. The peptonizing group. — "The peptonizing group is probably the most interesting if not the most important group of bacteria in ice-cream. This group consists of what are commonly known as the putrefactive bacteria; that is to say, they attack primarily the proteins, decom- posing them into less complex organic bodies. Bacteria of 180 THE BOOK OF ICE-CREAM this class are usually considered undesirable in articles of food, and it is to them that intestinal troubles are some- times attributed, perhaps with or without justification. Whatever their true effect is will not be discussed in this paper, but because bacteria of this group are looked upon with suspicion it is therefore of great importance. ''Among this group there are a large number of different types of organisms. Many rapidly peptonize the casein of milk and render milk alkaline or slightly acid, while others first attack the lactose and only produce a slight pep- tonization after several days' growth. From the milk- tube method of differentiation of the bacterial groups it was possible to gain some information as to the extent of these different classes of peptonizers. In Table No. XII are shown the average percentages of the peptonizing group in summer and winter samples of ice cream. Based on the 14-day reaction among the summer samples, 13.62 per cent of the bacteria belonged to the peptonizing group. According to the 2-day reaction, there were 5.93 per cent. Therefore 43.54 per cent of the peptonizing bacteria were sufficiently active! to produce a peptonization within two days. Among the winter samples 34.06 per cent of the peptonizing bacteria were sufficiently active to peptonize milk within 48 hours. These active peptonizing bacteria are more important than the slower-acting^ varieties, since their peptonizing action is usually more complete than that of the latter-named varieties, and if any harm is produced by this group, they are most likely to be the organisms concerned." BACTERIA IN RELATION TO ICE-CREAM 181 Table XII Changes in the Percentage of the Peptonizing Group of Bacteria in Ice-cream when Determined by Litmus-milk Reactions after Various Lengths of Incubation Per cent reacting after incubation for Peptonizing group 2 days 5 days I4. days per cent per cent per cent Average of 71 summer samples 5 . 93 9 . 76 .... 13 . 62 Average of 28 winter samples 7 . 12 .... 13 . 58 20 . 90 140. Colon bacilli in ice-cream. — Since the presence of colon bacilli has been understood in water analysis to indicate fecal contamination, many investigators and boards of health apply the same tests to milk and nat- urally then to ice-cream with the same idea. In water analysis, lactose-bile fermentation tubes are employed for the examination for colon bacilli. By using different dilutions, the maximum number of gas-forming bacteria in a given amount of water may be determined. This preliminary test has to be followed by confirmatory ones in which cultures are isolated and their characteristics studied in order to prove the presence of colon bacilli. Ayers and Johnson used this method to some extent but endeavored to prepare a synthetic medium which would restrict the growth of the larger number of bacteria in ice- cream and at the same time would allow colon bacilli to develop and produce characteristic reactions. Ice-cream contained a much larger number of gas-forming organisms in the summer season. A large number of media were used in an attempt to devise a suitable medium for the detec- tion of Bacillus CoH in ice-cream and the results show that there is no entirely satisfactory method known at present. 141. Difficulties in studying the bacteriology of ice- cream. — ^As has already been pointed out, one of the great- 182 THE BOOK OF ICE-CREAM est difficulties in studying the bacteriology of ice-cream is the lack of a suitable culture media. Because of the low temperature at which the ice-cream is hardened and held, some investigators believe that there is a gradual change of the types of organisms or the survival of the fittest. This brings up the question as to the temperature at which the cultures should be incubated. Until a suitable media is prepared and a uniform temperature of incubation used, the counts of the organisms in ice-cream made by different investigators will not be comparable. CHAPTER XIV TESTING The determination of the composition of dairy products is a very simple yet important part of the ice-cream business. The fat and the solids not fat are the constit- uents usually determined. The most accurate method by which to buy all raw materials is on the basis of their composition. The finished product should be tested to de- termine its composition, regardless of whether or not it is sold on this basis. The testing of the finished product is necessary to check up the amount of materials used. By this means an accurate cost account can be kept and any variation in the composition of the product quickly discovered. THE BABCOCK TEST * The amount of fat in milk, cream and skim-milk can be ascertained quickly and accurately by means of the Babcock test. The essential requirements are that the operator be careful not to break the glassware and that the measurements are accurately made. 142. Testing whole milk for fat. — The sampling is the most important operation of the test. "The sample to * Troy, H. C, " The Babcock test and testing problems," Cornell Reading Course Lesson 118, 1916; Ross, H. E., and Mclnerney, T. J., " The Babcock test with special reference to testing cream," N. Y. Cornell Exp. Sta., Bui. 337, 1913; Hunziker, O. F., " Testing milk and cream for butter fat," Ind. Exp. Sta., Circ. 42, 1914. 183 184 THE BOOK OF ICE-CREAM be tested should be thoroughly mixed before it is measured out. Mixing is done by shaking the vessel in which the milk is contained, or better still, by pouring the milk from one vessel into another. The fat in milk is lighter than the other constituents and soon rises to the surface. Unless great care is exercised an unfair sample will be taken. If the sample is an old one, such as a composite sample, it should be heated to a temperature of not over 85° F. in order to soften the fat. The sample should not be heated above 85° F., since the fat is likely to separate in the form of an oil and when so separated it is impossible to remix it evenly throughout the sample.'^ 143. Composite samples of milk. — The purpose of taking composite samples is to reduce the labor and ex- pense of testing. The true composite sample consists of aliquot portions of milk of several deliveries from the same patron. Composite sample jars must have a tight seal in order to prevent evaporation of moisture. Pint jars sealed with glass stoppers, cork stoppers, metal caps or screw tops may be used for this purpose. Bottles with paper caps and jelly glasses with tin lids do not furnish tight seals; they should not be employed. A separate jar is used for each patron and each jar must bear the respective patron's number. The jars should be thoroughly clean and, in order to guard against errors, they should be arranged on convenient shelves near the weigh-can in numerical order, grouping the jars of patrons of the same route together. Correct composite samples may be obtained by the use of a milk thief or a graduated pipette. If the milk thief is used, it is inserted into the weigh-can of milk of the entire delivery of one patron. The milk in the tube rises to the level of that in the weigh-can. The milk thief is then emptied into TESTING 185 the sample jar. In case the graduated pipette is employed, a certain quantity of milk is taken for every pound delivered by the patron (usually about .1 cubic centimeter for every pound of milk delivered). The milk thief is the handier instrument of the two, but when the amount of milk delivered by different patrons varies con- siderably, the samples of milk from the larger producers are often too ample to be practical. Other so-called composite samples are taken by using the same measure for all milk receipts. In this case a small dipper holding about one ounce is commonly employed. With this dipper a sample of milk is taken daily from the weigh- can of each patron's milk and transferred into the sample jar. This method of composite sampling is not mathematically correct and the results tend to be less reliable, although experi- mental data show that the results average practically the same as when ahquot portions are taken. Evaporation causes the percentage of fat and other solids to increase, yielding mis- leading tests. It also tends to dry the milk on the surface, causing the formation of a tough, leathery layer. In this condition it is difficult to secure a representative portion for the test. This can be prevented: by giving the sample jar a gentle rotary motion after each addition of milk; by replacing the stopper properly after each addition of the milk; and by protecting the sample from excessive heat. Fermentation -^If -.^^'T may be prevented by the addition of a small ^^^k pi- amount of preservative, such as corrosive subli- pette. 186 THE BOOK OF ICE-CREAM mate, potassium bichromate or formaldehyde. It is usually best to have the temperature of the milk from 60° to 70° F. when measured into the test bottle; however, variation within reasonable limits will not affect the test since the coefficient of expansion of the milk is not high enough appreciably to affect the amount measured by the pipette. 144. Measuring the sample. — The instru- ment for measuring the milk for the test is called a pipette. (Fig. 62.) It has only one graduation, 17.6 cubic centimeters, equiva- lent to 18 grams. The sample is measured by drawing the milk above the graduation and then placing the index finger over the end of the pipette. By carefully releasing the fin- ger, the column of milk can be lowered ^^_ ^_ until the bottom of the meniscus is on a B 1 ia level with the 17.6 c. c. mark on the pipette. l;;|. i^3^ >fl It is absolutely necessary that the mark on l;-l^^ft^M the pipette be held on a level with the eye, i^^j^^ so as to show when the column of milk is Ifli^HU on a level with the mark. The milk is then ^ge==:y transferred from the pipette to the test- FiG. 63. — Bab- bottle. (Fig. 63.) The pipette and the test- cock whole bottle should be slanted so that the milk will run down the bottle neck and not be forced out by the air coming from the bottle. Whole-milk test-bottles are of two kinds, those reading as high as 10 per cent and graduated in fifths, and those reading as high as 8 per cent and graduated in tenths. In each case the graduations give readings directly in terms of percentage, since the graduated part of the neck is made to hold a column of fat milk test- bottle. TESTING 187 which is a definite percentage of the weight of the milk taken. 145. Adding the acid. — Sulfuric acid is added to the milk in the test-bottle, by means of a special measure which has only one graduation, 17.5 cubic centimeters. (Fig. 64.) The purpose of adding the acid is to destroy all the milk solids except the fat, which it does by moist combustion. In this process great heat is produced. This is advantageous, since the fat must be kept in a liquid condition in order to perform the test properly. The neck of the test-bottle gives percentage readings only when the fat is in a liquid condition. In adding the sul- furic acid, the bottle should be slanted, the same as in adding milk. As the acid is poured in, the bottle should be revolved so that the acid will wash down any milk that adheres to the neck, milk dries on Fig. 64. — Acid measures for Babcock test. If this is not done, the the neck and is lost in the test; it also causes a cloudy bottle-neck and obscures the fat column when the test is completed. The acid and milk should be mixed thoroughly as soon as the acid is added to the bottle, else portions of the sample might be charred and so lock up small particles of fat. It is well to mix the contents of the bottle for at least half a minute after all the milk has apparently been dissolved by the acid. The mixing is done by holding the bottle by the neck between the thumb and the index finger, and giving 188 THE BOOK OF ICE-CREAM / \ it a rotary motion from the wrist (Fig. 65) ; if an up-and- down motion is used, the contents of the bottle are likely to be spilled. The strength of the acid is reckoned in terms of its density, which should be 1.82 to 1.83. A special instru- ment is used for testing the density, and, since this in- strument is seldom available in a dairy or a creamery, one of the best ways of testing the acid is actually to ^^ perform a test with it and \ note the results. The acid \^\ should be of such strength V\ that it will turn the con- '\^-.„^ tents of the bottle to a dark brown as soon as mixed, and the mixture should turn an intense black after standing for about one minute. The best acid is colorless, yet it may be fairly dark and yet be fit for use. The acid should never contain any undissolved material, since this is likely to rise with the fat and obscure the reading. 146. Whirling the sample. — ^After the acid and milk are thoroughly mixed, the samples are ready for whirling. The centrifuges used are of three main types (Fig. 66), those driven by hand power, by steam, and by electricity. The steam machines usually are considered best, since with them it is easy to maintain the proper temperature during the process of whirling. The hand and electric machines should perform equally as good work, provided a high enough temperature is maintained to keep the fat in a liquid condition. The frame of the hand machine should Fig. 65. — Diagram showing the motion and position of a test-bottle while mixing the milk and the acid. TESTING 189 always be filled with hot water before the bottles are whirled. In case of the four-bottle machines, which have no frames, the bottle cups, which are made large for that purpose, should be filled with hot water. Great care should be taken to have the machines balanced; by this is meant that for every bottle on one side of the machine there should be a bottle on the opposite side. The machines should also be well oiled, especially those driven by steam, which, because of the heat, soon dry out. Fig. 66. — Hand and power Babcock centrifuges. The sample is whirled for five minutes and then filled with hot water to the base of the neck, then whirled for two minutes and hot water again added so as to bring the fat within the graduated part of the neck. The sample is then whirled for one minute in order to bring all the fat into the graduated neck. Some operators of the Babcock test make two separate runs instead of three, filling the bottles to within the graduated neck after the first run. While this may give fairly good results, it is better to make three separate runs as indicated above and fill to the base of the neck the first time. This washes the fat free from 190 THE BOOK OF ICE-CREAM any sediment and gives a clearer reading than would other- wise be obtained. 147. Reading the test. — The sample should be read at once, before the fat column has had time to cool. In reading, the bottle should be held between the thumb and the index finger and the fat column should be on a level with the eye. The fat column in a whole-milk bottle is not large enough to be greatly affected by temperature unless it is extremely hot or cold. With a steam cen- trifuge, the temperature may be extremely high and thus the reading may be slightly increased. This danger may be avoided by allowing the bottles to stand for a minute at room temperature before reading. There is greater danger of reading the fat column at too low than at too high a temperature. It does not take long for the fat column to harden, and if the room is at all cold it is safer to set the test-bottles in water at about 140° F., having the water come above the fat column in the bottle. The ex- treme points of the column should be included in the read- ing (Fig. 67) since this method makes up very closely for minute particles of fat which are not brought to the sur- face during the process of testing. There are two methods of reading the percentage of fat in the neck of the bottle. The first is to obtain the difference between the bottom and the top of the fat column; if, for example, the bottom of the fat column rests on the 1.7 per cent mark and the top on the 5.8 per cent mark, the percentage of fat is 4.1 (5.8 — 1.7 = 4.1). The second method of reading is to count the whole per- centage and the tenth percentage marks covered by the fat column. Some operators make use of dividers in reading the fat column. The exact space covered is obtained, and one point of the dividers is placed on the TESTING 191 5.8fT8 TO ADD, AND HOW TO SHAKK. How /uge Reagents to water after c CTION — Use no entrifuging as i idicated. A few How long to centri- fuge 1 How to to keep samiile in oven and cooler in Howto weigh solid sample .S(--e of sample to take for solids Amount M add to sample in dish Hoio tested Water A>nmo7!M Alcaluil Ethyl ether Petroleum ether make a much more distinct dividing line. satffein Alcohol Elh:,l ether Petroleum ether oven and cooler Frc3k milk Mix thoroughly Measure with 10 gram pipette. Drain pipette 15 seconds 10 grams No water 1.5 cc. Shake thoroughly 10 c.c. Shake hall Add 25 c.c. Shake for one minute Add 25 c.c. Shake tor one 30 turns .Shake 20 sec. 15 c.c. Shake 20 sec. 15 c.c. Shake 20 sec. 30 turns If necessary to 5 _,:„ :^ raise di\'iding o,,„„ '( line, add the , .,=0 ^ necessary 7 „:„ ■ distilled water ' ,S „■ , Use cross and 2 gram pipette or pipette about 2 grams diroctb- into dish upon balance 2 grams none 10 min. in lOO" C. 5 min, in cooler at room temp. Skim-milk Mix thoroughly. Get represen- tative sample 1,5 c.c. Shake very thor- oughly Wkeu 1.5 c.c. Use more if whey is acid. Shake thoroughly BuUermilk Mix thoroughly 1.5 c.c. Shake thoroughly Evaporated milk Shake in can very thoroughly Use cross and 5 gram pipette Weigh about 5 grams Use 4 c.e. Shake thoroughly 25 c.c. Shake 20 sec. 25 c.c. Shake 20 sec. Use cross and 1 gram pipette, or pipette about 1 gram directly into dish upon balance 1 gram lc.„. Bulk UTl- awectened condensed milk Mix very thoroughly. Get represen- tative sample Bulk, extra sweetened condenaed milk Use cross and one S gram pipette About 3 grams 7 c.c. Shake very thor- oughly. Hot water preferred Shake ' very thor- oughly 10 c.c. Shake one Use cross and 5grampipetto, or pipette about 5 grams directly mto dish upon balance 50 gram 2C.C, Sweetened condensed milk Proceed without diluting. Mix thoroughly Use cross and 5 gram sample About 5 grams 8 c.c. hot Shake until thor- oughly Shake' thor- oughly 60 turns GO turns Use cross and pipette, or pipette about directly into dish upon balance no min. lOO" C, or 20 min. and dciliict ,.30% from lotal. cnolcr'at Ice-cream Mix thoroughly. Heat slightly to melt fat Use cross and 5 gram pipette and weigh rap- idly or weigh directly into flask Oc.c. Shake thoroughly 30 turns 30 turns Use crusts ntid 1 gram pipette, or pipette about 1 gram directly into dish upon balance Igram Icc. 10 min. in joo"c. Cream teatino less than £5% b. f. Mix thorouRhly. Heat slightly to melt fat Use weigh cross with 2 gram pipette. If necessary use boat or weigh directly About 2 grams e c.c. Shake thoroughly 1.5 c.e. Use 3.0 c.c. Shake thoroughly 10 c.c. Shake liajf minute Add 25 c.c. Shake tor one Add 25 c.c. Shake for one 30 turns Sc.c. Shake 20 sec. Rha'ko'20 sec. 25 c.c. Shake 20 sec. 30 turns raise dividing line, add the distilled water just before pourin? off oven at 135° C. 7 min. in cooler at room temp. 1 gram pipette, or pipette directly into dish upon balance 1 c.c. oven at 100° C. cooler at room temp. Cream teslino more than S5% b.f. About 1 gram Sc.c. Shake thoroughly Use cross and 1 gram pipette, or pipello about half grnni directly into dish iipon balance ~ Malted milk Mix thoroughly. Get represen- tative sample Use butter boat, or weigh directly into flask .5 gram 10 c.c. hot. Shako thor- oughly 1.5 c.c. Shake very thor- oughly Weigh enmplo directly into dish upon balance .30 gram 2 c.c. "00" C. cooler at mom Icmp. Milk chocolate Pulverize in close grained mortar. Transfer to Cocoa Mix thoroughly. Get represen- Cheese tzB^' 1 .0 gram 50 gram .5 c.e. Butter Sec detailed directions Use butter boat Igram none KJ0°°C.. cooler at 10 min. in Skimmed- milk Pvdveri7.e in close grained mortar. Tranafer to sealed jor Use butter boat or weigh directly into flask About 1 gram S..') c.c. Hot water. Shako thoroughly 1.5 c.c. Shake thoroughly' 10 c.c. Shake one minute 15 c.c. Shake 20 sec. 15 c.c. Shake 20 sec. 30 gram ' c.c. 00° C. min. in oolcr at 00m temp. Whotr- ,ni!k Shake 20 sec. 25 c.c. Shake 20 sec. TESTING 245 185. Savings and economies. — ^By using the Mojonnier over-run tester intelligently, the operator can insure the management an even uniform product from day to day, at an economical cost. Many plants have increased their over-run test, and at the same time turned out a more satisfactory product. Success depends on how carefully and consistently the tester is operated. The operator can soon make himself very valuable to the management of the ice-cream factory. The tester removes guess-work from the freezer-room practice and places it on a scientific basis. CHAPTER XV MARKETING AND BUSINESS MANAGEMENT The question of a market for the product is most vital. If the ice-cream is manufactured and a market cannot be found, the business is a failure. This is more especially true with ice-cream than the other dairy prod- ucts since practically no middle-men or commission merchants will handle it. Another vital question is the cost of marketing; if too high, the apparent profits of manufacture may be required to meet this cost and again the business is a failure. 186. Demand for ice-cream. — The growing demand for ice-cream is indicated by the figures in Chapter XVII. The question might naturally be asked why this demand is increasing. There are three possible answers to this. The consumer in the past regarded ice-cream as a delicacy to be indulged in only on special occasions. Now the food value is recognized and it is being consumed in large quantities as a food. In the past it was often difficult to secure ice-cream in a satisfactory condition. This was due to a poor delivery system and a lack of knowledge regarding the handling. At present, however, these difficulties have been over- come largely. In the hot summer weather, persons like to eat or drink some substance which is pleasing to the taste and at the same time has a cooling effect on the body; and no dish can replace ice-cream for this purpose. This condition, namely, the demand for ice-cream in 246 MARKETING AND BUSINESS MANAGEMENT 247 summer and the lack of it in winter, is a matter of great concern to the manufacturer. It gives him an unequal distribution of his business throughout the year. This is a decided disadvantage for several reasons: 1. It is hard to secure satisfactory help for a short period of time; 2. It is difficult to obtain milk products in sufficient quantities only for the hot weather; 3. It requires a large investment in equipment which is used only a part of the year. The usual result is that the ice-cream manufac- turer is forced to pay a higher price for his milk products, if he takes them only during the summer. On the other hand, if the milk products are purchased by the year, a profit is realized during the period of large demand and the balance of the year they are handled in some other way with a view of breaking even or reducing the loss as much as possible. In order to be sure of help for the rush season, it is usually necessary to keep at least a part of the necessary summer force during the slack season. They can be employed in cleaning the plant and making the necessary repairs for the next rush season. The creating of a market for ice-cream in the winter is an unsolved problem. It has been overcome partially in some plants by making fancy or special ice-creams. They usually require more labor and hence sell at a higher price and are in demand for various society functions which are more common in the winter. 187. Food value of ice-cream. — Up to the present no investigations have been made dealing with the food value or healthfulness of ice-cream. It would seem that the previous statements about the food value of milk, cream, and butter would apply to ice-cream. Miss Rose * * Rose, Flora, "Milk a cheap food," Cornell Reading Course, Lesson III, 1917. 248 THE BOOK OF ICE-CREAM gives the following summary regarding the value of milk as a food: ''With all the evidence in, no food bears the investiga- tion of nutritive properties better than does milk. It is impossible to escape the conviction that not only is it a cheap food, but it is one whose value can hardly be esti- mated in terms of dollars and cents. It has been pointed out that: 1. Although milk is not the cheapest source of energy that can be bought, it is nevertheless an important source of energy, and the energy-yielding substances, the pro- tein, the milk-sugar, and the milk-fat, have special value. 2. Milk is a cheap source of protein because the pro- tein that it contains is of a kind particularly valuable for building tissue. 3. Ordinarily milk is the cheapest and most valuable source of lime, unless it is discovered that lime in water can take the place of lime in milk. 4. Milk is a valuable and cheap source of phosphorus. 5. Milk is deficient in iron, but the iron that it contains is particularly well utilized by the body. 6. Milk is the most important of the three foods, milk, eggs, and meat, which are the chief sources of a factor in foods that is soluble in fat, that is essential to growth and health, and that is called "fat-soluble A." 7. Milk is one of the most important sources of a factor in foods that is soluble in water, that is essential to growth and health, and that is called "water-soluble B." Jerome Alexander * shows the effect of gelatine on the * Alexander, Jerome, ''The beneficial effect of gelatine upon the digestion of milk and cream," "Ice-cream Trade Journal," Vol. 5, No. 2. . MARKETING AND BUSINESS MANAGEMENT 249 digestibility of milk products. The chief constituents of ice-cream are crystalloids; that is, substances that can form crystals, whereas gelatine is a most characteristic member of the group of non-crystallizing substances known as colloids. Research has shown that colloids or hydrosols as they are sometimes known may be divided into two classes or groups; depending on the way they behave when they dry out. The first group which in- cludes those that can be redissolved after being dried, such as gelatine, are called the reversible colloids or reversible hydrosols. The second group, which includes those that cannot be redissolved after drying, such as pure colloidal metals, oxides and the like, are known as irreversible colloids or irreversible hydrosols. The re- versible colloids are not sensitive but will stand the addi- tion of most substances without coagulation. In the case of ice-cream, the addition of gelatine tends to prevent the coagulation of casein, which is an irreversible colloid and the important proteid or nitrogenous constituent of cows' milk. For this reason gelatine renders ice-cream more readily digestible and therefore more healthful; as is well known, milk is immediately coagulated on coming in contact with the acid juices of the stomach. But in the presence of gelatine the casein is either prevented from coagulating or if it does coagulate the clots or curds are so fine grained that they dissolve very easily in the process of digestion. The composition of ice-cream varies with the materials used. The flavoring material affects the percentage com- position. The following are fair examples of the chemical composition of commercial vanilla ice-cream containing different percentages of fat: 250 THE BOOK OF ICE-CREAM Table XIV Composition of Ice- cream Containing Different Percentage 5 of Fat Sample Carbo- Number Fat Protein hydrates Water Ash 1 .. 8.5.. ....3.0... ...22.50... ...65.0..... .1.0 2 ..14.0.. ....2.2... ...20.00... ...63.0 .0.8 3 .. 8.0. . ....4.0... ...21.10... ...66.0 .0.9 Ice-cream is often considered a possible source of pto- maine poison and typhoid fever. If not properly handled and allowed to melt and then returned and refrozen or made from poor materials, there may be danger of disease. But under the sanitary condition of most of the plants, especially the large ones, there is no more danger from ice-cream poisoning than from any other class of food. 188. Locating a market'. — Believing that there is a general demand for ice-cream, the question naturally follows where is the most desirable location or market. Because of the large number of consumers, the city natu- rally^ offers the best market. If a large plant is planned, the usual system is to wholesale the ice-cream to the retailer. If a smaller plant is desired, the market may be a retail business only; in this case it may be a hotel, drug-store, soda fountain or summer resort. Several creameries are located on trunk lines of improved roads and make ice-cream as a side line, catering entirely to automobile parties. 189. Method of delivery. — For the retailer the ques- tion of delivery is very simple, but for the wholesaler it is a very perplexing problem. • There are three ways by which the wholesaler may make delivery: by express, automobile truck, wagons and horses. If the plant is in a large city, the ice-cream may be shipped by express to retailers in the surrounding small MARKETING AND BUSINESS MANAGEMENT 251 towns. The distance that shipments can be made by express depends on the facilities of the railroad. If on a main line with fast trains, shipments may be sent 300- 500 miles. Ice-cream should not be shipped so far that it will soften before it reaches the retailer. In the city, the manufacturer must decide which is the more economical, to use horses and wagons or automobiles. Each has its advantages and disadvantages, some of which are as follows : Advantage of automobile truck: 1. Can make quicker delivery than horses and wagon. 2. Can carry larger load. Disadvantage of automobile truck: 1. Large initial cost. 2. Requires higher salaried person to operate it than to drive horses. 3. Cannot be used year round in some snowy localities. 4. Engine may be left running while making delivery. This is expensive. 5. Large loss in case of accident. Advantage of horses and wagons: 1. Can be used year around. ■ 2. Easy to get person to drive horses. 3. Not as expensive as large truck to purchase. Disadvantages of horses and wagons: 1. Slower than automobile truck. 2. Liable to tire out in hot weather. 252 THE BOOK OF ICE-CREAM 190. Cost of delivery. — This is so variable that even average figures would be misleading. The cost of delivery should be based both on the cost a gallon and the cost a load. These figures should be watched and a reason found for a marked increase. Otherwise, the cost of delivery may grow so that it will consume all profits. One of the large items is the ice necessary to pack the ice-cream in the retailer's cabinets. 191. Packages used for delivery. — When drawn from the freezer, the ice-cream is placed in pack-cans or brick molds. When delivery is made to the retailer, the ice- cream is usually left in the pack-can. For delivery by express or to the individual consumer, the can is packed in a tub with ice and salt. The size of the tub varies with that of the pack-can. (Fig. 77.) The small tubs usually have bails and the large tubs handles on the side. For city delivery of wholesale ice-cream, the wagon or auto truck (Fig. 78) is equipped with a cabinet and the cans packed in these cabinets. This eliminates the heavy tubs. Ice and salt are carried for packing the ice-cream in the retailer's cabinet. Most manufacturers furnish the retailer with a cabinet (Fig. 79) in which the ice-cream is packed until retailed. These cabinets are usually insulated. They are made in various sizes to hold one or several pack- cans of ice-cream. In the cabinet is usually a form which fits around each can so that it may be removed and an- other full one put in without the ice caving in. This Fig. 77. -Ice-cream packing tubs. MARKETING AND BUSINESS MANAGEMENT 253 form has numerous holes in it so that the cold air and brine can get to the pack-can. The cabinet is fitted with a large cover in which are smaller openings and covers for each can. These smaller openings are used when dip- ping the ice-cream. Before delivery to the consumer or the retailer, the brick ice-cream is usually taken from the mold and wrapped Fig. 78. — Auto delivery truck for ice-cream. in paper. This eliminates the return of the metal form. These bricks may then be packed in ice and salt or simply wrapped in additional paper, depending on how long the ice-cream must be kept before it is to be consumed. Sev- eral paper carriers have been devised, but they are not in general use. The retailer makes his deliveries directly to the con- sumer, either to be eaten immediately or carried home. 254 THE BOOK OF ICE-CREAM When delivery is made to be consumed immediately, the ice-cream is dished with a measuring disher and placed in an individual dish. There are a large number of styles of these dishers. (Fig. 80.) Each has some sort of a knife or scraper to remove the ice-cream from the disher. The size is expressed in the number that it takes to make a quart. The disher is used as the measure whether the ice-cream is sold by the dish, in the soda glass or cone. A large amount is sold in the latter. There is no objection to the cone itself if it is made of pure harm- less materials. It is Fig. 79. — Ice-cream cabinet with sides often sold from push cut away showing insulation and ^^^^^ ^^^ venders' perforated cyhnders in which the pack-cans of ice-cream set. wagons, where there is great opportunity for dirt to get into the ice-cream both before and after it reaches the consumers' hands. Another device through which a large amount of ice-cream is sold is the ice-cream sandwich machine. This places a slice of brick ice-cream between two wafers. When the ice-cream is sold by the retailer to the con- sumer to be carried away and consumed later, it is packed in a heavy manilla paper pail. These vary in size from a pint to two quarts. If the ice-cream is hard and the MARKETING AND BUSINESS MANAGEMENT 255 pail wrapped in paper, it may be held for an hour or more before it begins to melt. While the ice-cream may be made of high grade mate- rials and under the most sanitary conditions, many of the places where it is retailed are not clean. The single- service paper plate and spoon are to be desired in prefer- FiG. 80. — Different styles of ice-cream dishers. ence to the dish and silver-plated spoon which is rinsed off in cold water. It is to the advantage of the manu- facturer to see that the places where his ice-cream is sold are kept in a clean sanitary condition. 192. Advertising. — The manufacturer must keep the attention of the pubhc centered on his ice-cream. This can be done only by advertising. There are several ways, but the best is to let the product advertise itself. If an 256 THE BOOK OF ICE-CREAM ice-cream appeals to the desires of the consumer and is uniform, it will be in demand. The newspapers may be employed also as an advertis- ing medium. In some localities the advertisement has appeared for so long in some particular space in the paper that the consumer has become accustomed to look there to learn what special ice-creams will be made for holidays and Sundays. The paid reading advertisement in the newspaper is a form conamonly used. This differs from the ordinary form in being printed the same as any news item. It should not be too long and should be concise and clear to the reader. The society columns should be watched and an effort made to sell one's ice-cream at any large gathering. This is especially true of church functions. The person in charge may be communicated with either by telephone or a neat attractive letter. Extra effort should be made to have the ice-cream of good quality. It may not be profitable to furnish ice-cream at these functions, but if the advertising feature is considered it will be very valuable. The bill-board is another means of advertising and is very effective in impressing the name of the ice-cream on the public. It is usually expensive. The results of advertising are ordinarily hard to measure exactly, but it is a necessary part of the business. The value of advertising in the winter, when there is not a large demand for ice-cream and many specialties have to be manufactured, should not be overlooked. There are many schemes for advertising, and which will be tried and which rejected will have to be determined by the manufacturer. The underlying principle is the same in all. They should be attractive; they should state some MARKETING AND BUSINESS MANAGEMENT 257 fact about the ice-cream; the wording should be such as to induce the reader to try a dish. The value of adver- tising is especially difficult for a beginner to see. The amount of money that can or should be used for adver- tising will have to be determined by several facts, such as number of local newspapers, number of towns where ice-cream is sold, amount of education necessary to create a demand. Under no circumstances, in any advertisement or in any other way, should a manufacturer run down the qual- ity of his competitors' products. It is often desirable to have some short attractive expression to use with the advertisement. 193. Salesmen.— In the large plants, salesmen are necessary to call on the trade to sell, the ice-cream and adjust any differences that may arise. The kind of sales- man has much to do with the success of the business. He should be neat and clean in appearance; he must have the faculty of getting along with people; he must have good business ability and be able to make sales. It is not the first sale that counts but the repeated orders that are necessary to put the business on a firm foundation. BUSINESS MANAGEMENT The success of a plant is not alone in being able to make ice-cream of good quality, although this may be the major item. The business management is very important. This consists of the buying, handling the workmen, mak- ing the sales and in general keeping track of the financial end of the plant. In many cases it is necessary to check up the losses. 194. Purchase of raw material. — All raw materials used in the ice-cream should be purchased on the basis of their 258 THE BOOR OF ICE-CREAM composition rather than by quantity. For example, it is very poor business to buy milk and cream for a certain price a quart or gallon regardless of the percentage of fat contained. The percentage of fat in the milk is largely influenced by the season of the year and the lactation period. Even more variable is the percentage of fat in the cream, the fat-content varying from the same creamery or same separator. Some of the causes of variation in the test of cream are: 1. Adjustment of the cream screw; 2. Richness of milk separated; 3. Amount of material used to flush the bowl; 4. Speed of the separator; 5. Tempera- ture of milk when separated; 6. Rate of flow of the milk to the machine. The composition of the other materials will vary the same as does the milk and cream. Each shipment should be tested to make sure that it is of the proper composition. This may take some time, but it pays in the end. 195. Price of dairy products. — There is no market quotation for any except the manufactured dairy prod- ucts such as butter and cheese. Ordinarily the price of milk and cream follows that of these manufactured prod- ucts very closely. The price of butter and cheese are quoted daily in New York City in the "Price Current" published by the Urner Barry Company. From this the price of milk and cream can be estimated. In some cases, the price of the fat in the cream is based on the price of butter. 196. Book-keeping system. — A simple yet complete set of books should be kept. A cost system seems best adapted and the most simple. To obtain a cost system it is very essential that every penny should be accounted for and charged to the account for which the expenditure was made. The numerous MARKETING AND BUSINESS MANAGEMENT 259 accounts that will have to be maintained in order to keep this system should be classified under the headings of production costs and sales costs. In opening the accounts for production cost, it is necessary that the following heads should be carried: 1. Milk, cream, butter. Express should be added to the cost of the above where any of the same is shipped. 2. Labor. Salaries for ice-cream maker, mixers, and helper. The remaining help throughout the plant is carried under a different heading which does not apply specifically to the pro- duction department. 3. Supplies used. This account should be carried under several different headings, as: (a) Sugar (b) Milk powder (c) Gelatin3 (d) Gum (e) Fruits (f) Extracts (g) Miscellaneous 4. Ice and salt (when ice and salt are used for the freezing of the cream). But in case mechanical refrigeration is employed for freezing and ice and salt for hardening, it should be charged to the production cost; otherwise it should be figured into the sales cost just the same as delivery or other expense. 5. Water and steam. 6. Sundry expense. By keeping these accounts monthly, the production cost for every month is computed for the year. Sales cost should include: 1. Rent. 2. Salaries. (a) Executive. (b) Office. (c) Salesmen. (d) Delivery drivers. (e) Labor. (Can-washers employed.) . and such other help as is 260 THE BOOK OF ICE-CREAM 3. Advertising. 4. Ice (as used in packing for deliveries). 5. Miscellaneous expenses. 6. Taxes. 7. Insurance. 8. Bad debts. 9. Postage and stamps. 10. Trucks, or horse and wagon expense. 11. Traveling expense. 12. Telephone and telegraphic expenses. 13. Salt. 14. Depreciation. 15. Repairs and replacements. 16. Stationery. 17. Shrinkage. 18. Such other items of sales cost as you may see fit to carry under separate headings. Taking the number of gallons sold, it is an easy matter to divide this into any one of the numerous accounts under either the head of production or sales cost, which will give the cost a gallon of this account and place the manager in a position to keep in touch with every account as to the actual cost a gallon each month. By making comparisons month after month, it will be easy to de- termine wherein the costs are excessive. 197. Shipping clerk. — ^No ice-cream business is too small or too large to have a shipping clerk. In a small plant, the shipping may not require all one man's time so that he may have other duties. The shipping platform and office of the shipping clerk in a large ice-cream plant is shown in Fig, 81. It is the duty of the shipping clerk to see that the orders are properly put up and that they are delivered on time. He must check the ice-cream to the drivers and see that each has the correct amount of salt and ice. It is sometimes the custom of the drivers to take extra ice and salt and sell it on the side. He must MARKETING AND BUSINESS MANAGEMENT 261 also check back any ice-cream returned by the drivers. The position of shipping clerk is one of the most im- portant in the whole' business management. 198. Report blanks. — Every person who has charge of any part of the ice-cream business should make a report. By means of these daily reports, any leaks or losses may be checked up. It also makes easy the keep- ing track of the business. Forms for these reports are Fig. 81. — Shipping platform and office of shipping clerk in a large ice-cream plant. not included because the demand in each plant would probably be different. The receiving-room report should show the amount of milk and milk products received and the percentage of fat in each and the total receipts. The mixing-room report should indicate the amount of ma- terials used. The freezing-room report should show the number of freezers of ice-cream made, the swell obtained in each and the total gallons. The shipping-room report should tell the number of gallons shipped out. The drivers' report should show the amount of ice-cream received, the amount returned and the amount sold, to 262 THE BOOK OF ICE-CREAM whom sold, whether cash or credit, and thq cash and credit should equal the amount sold. These reports may be combined more or less, depending on the size of the plant. A loose-leaf or card system for filing in many cases would reduce the office work. 199. Losses. — In any business there are more or less losses. These are usually inversely in proportion to the efficiency of the business management. In ice-cream marketing, certain leaks or losses are liable to occur and these should receive special mention. 200. Pack-cans and tubs. — Undoubtedly there is no part of the business that causes the manager more anxiety than the return of the empty pack-cans and tubs. This is especially true when a considerable part of the ice- cream is shipped by express. Many schenies have been tried to return these tubs, such as paying the drivers a percentage for the return of a certain number, charging the person to whom the ice-cream was sold for the can and tub, hiring a special man to look up the can and tub, and many others. The one commonly used by manufac- turers is to have a distinctive color on the tub, their name and address and also a number. The shipping tags are made with a stub that is perforated so that it can be detached easily. When the tag is attached to the tub, the number is placed on both the tag and the stub. The stub should contain date and name and address of the party to whom shipped. It is often desirable to have the gallons and kind of ice-cream shipped on both the stub and the tag. This stub is filed in the office and when the tub is returned the tag is taken off and sent in and the stub bearing the same tub number put with it, indicating that tub has been returned. By looking at the stubs for which the corresponding tags have not been returned, it can MARKETING AND BUSINESS MANAGEMENT 263 be seen readily to whom, where, and when the tubs were shipped and what parties are not returning the empties. 201. Rusty pack-cans. — Because of the salt that must be used to harden the ice-cream, more or less gets on to the pack-cans and rusts them, especially if they are not washed as soon as emptied. These rusty cans may be retinned. Another satisfactory plan is to line the can with heavy manilla paper. These liners may be purchased to fit any size pack-can. 202. Soft ice-cream. — Often the top of the can of ice- cream will become soft, due to the lack of salt and ice on top. Sufficient may have been put on but it jarred off while handling. This loss can be avoided by t3dng a piece of heavy paper or burlap over the top of the can. Heavy canvas covers may be purchased. Sometimes a large amount of refrigeration is lost by putting the ice-cream into the hardening-room through the large door where persons pass in and out. A small revolv- ing door (Fig. 82) will reduce this loss. There is a very rapid change of air when the hardening-room door is opened. The greater the differ- ence in temperature, the more rapid the change. Soft ice-cream soon ruins the reputation of the business. 203. Transferring. — ^When drawn from the freezer, the ice-cream should be put into the size pack-can in which it will be delivered to the consumer or retailer. If it is Fig. 82. — Revolving door used for putting the ice-cream into the hardening- room. 264 THE BOOK OF ICE-CREAM necessary to transfer from one can to another, there is a big loss in volume. This loss is probably caused by squeez- ing the ice-cream into the other container, which closes the air spaces. When the ice-cream is handled in the retail store, a loss may be caused by the heaping up of the dishes. Several scrapers or levelers have been devised to insure a uniform sized dish. If the dishers are kept in hot water, they will work much better in hard ice-cream. Some sort of scraper, of which there are several on the market, should be used to scrape the ice-cream from the sides of the can. LAWS Several laws apply to ice-cream. Some of these refer to the production of the milk and the balance are stand- ard of quality based on chemical composition or stand- ards for materials used. 204. Sanitary conditions and adulterated milk and cream. — ^Most of the states have laws dealing with the sanitary conditions under which milk and cream may be produced. The following law * of Wisconsin is a good example : ''Adulterated milk, what constitutes. Section 4607a. In all prosecutions under the preceding section, or any other section of these statutes, or laws amendatory thereof or supplementary thereto, relating to the sale of adulter- ated milk or adulterated cream, the term adulterated milk shall mean: Milk containing less than three per centum of milk fat, or milk containing less than eight and one-half per centum of milk solids not fat, or milk drawn from cows within eight days before or four days after parturition, or milk from which any part of the cream has * Dairy Laws of Wisconsin 1916, section 4607a. MARKETING AND BUSINESS MANAGEMENT 265 been removed, or milk which has been diluted with water or any other fluid, or milk to which has been added or into which has been introduced any coloring matter or chemical or preservative or deleterious or filthy substance or any foreign substance whatsoever, or milk drawn from cows kept in a filthy or unhealthy condition, or milk drawn from any sick or diseased cow or cow having ulcers or other running sores, or milk drawn from cows fed unwhole- some food, or milk in any stage of putrefaction, or rnilk contaminated by being kept in stables containing cattle or other animals. The term adulterated cream shall mean containing less than eighteen per centum of milk fat, or cream taken from milk drawn from cows within eight days before or four days after parturition, or cream from milk to which has been added or introduced any coloring matter or chemical or preservative or deleterious or filthy substance or any foreign substance whatsoever, or cream from milk drawn from cows kept in a filthy or unhealthy condition, or cream from milk drawn from any sick or diseased cow or cow having ulcers or other running sores, or cream from milk drawn from cows fed unwhole- some food, or cream contaminated by being kept in stable containing cattle or other animals, or cream to which has been added or into which has been introduced any color- ing matter or chemical or preservative or deleterious or filthy substance or any foreign substance whatsoever, or cream in any stage of putrefaction; provided, that nothing in this act shall be construed to prohibit the sale of pas- teurized milk or cream to which viscogen or sucrate of lime has been added solely for the purpose of restoring the viscosity, if the same be distinctly labeled in such man- ner as to advise the purchaser of its true character; and providing that nothing in this act shall be construed as 266 THE BOOK OF ICE-CREAM prohibiting the sale of milk commonly known as ' skimmed milk,' when the same is sold as and for 'skimmed milk.' Milk drawn from cows within eight days before or four days after parturition, or milk to which has been added or into which has been introduced any coloring matter or chemical or preservative or deleterious or filthy sub- stance, or milk drawn from cows kept in a filthy or un- clean condition, or milk drawn from any sick or diseased cow or cow having ulcers or other running sores, or milk drawn from cows fed unwholesome food, or milk contam- inated by being kept in stables containing cattle or other animals and cream from any such milk, or cream in any stage of putrefaction are hereby declared to be unclean and unsanitary milk or unclean and unsanitary cream, as the case may be." Most of the states have laws which determine the legal standard of milk. Anyone selling milk which does not meet the legal standard is liable to be fined. The laws of most states prohibit the taking of anything from or the adding of anything to the milk. This prohibits skimming and watering. Skim-milk must be sold as such. 205. Babcock test. — Some states have laws specifying that all glassware used in the Babcock test shall be stand- ardized. Standard glassware shall bear a certain brand to indentify it. This brand is placed on it after being tested by the proper state official. Some of the states have laws requiring the operator of the Babcock test to procure a license. 206. Purchasers or vender's license. — In some states a concern to purchase milk or cream from the producer must have a license. This is to prevent parties not financially responsible from buying milk and later beating the pro- ducer. The license is given only on the filing of a bond. MARKETING AND BUSINESS MANAGEMENT 267 In some cities ice-cream cannot be sold without a license. This is for the purpose of controlling sanitary conditions. 207. Legal standards. — Most states have legal stand- ards for dairy products. The standard for the different states is given in Table * XV. U. S. DEPARTMENT OF AGRICULTURE BUREAU OF ANIMAL INDUSTRY A. D. MELviN, Chief of Bureau LEGAL STANDARDS FOR DAIRY PRODUCTS {Revised to July 1, 1915) In the following statement, prepared in the Dairy Division of the Bureau of Animal Industry, are given the standards for dairy products as established in the several states, including Alaska, the District of Columbia, Hawaii, the Philippines, and Porto Rico. In all cases, unless otherwise expressed, the percentages stated represent minimum standards. The department publishes these figures as given by various state authorities, but does not guarantee the correctness of the standards given. * Melvin, A. D., "Legal standards for dairy products," A8, 1916. 268 THE BOOK OF ICE-CREAM Table XV. — Legal Standards for Dairy Products. States Milk Skim MILK Cream Butter Total solids Solids not fat Fat Total solids Fat Fat Water Salt Alabama ^ Per ct. Per ct. Per ct. Per ct. Per ct. Per ct. Per ct. Per ct. Alaska 2 ArizoDa ' Arkansas ^ California 8.50 3.00 3.00 3.25 8.80 18.0 16.0 16.0 80.0 80.0 Colorado 16.00 (0 Connecticut 11.75 8.50 (■) ^ Delaware 1 District of Columbia. . Florida 12.50 9.00 8 . 50 8.50 's^oo' 8.50 8.50 3.50 3.25 3.25 2.50 3.20 3.00 3.25 3.00 9.30 9 . 25 9.25 '9!3()' 9 . 25 9.25 20.0 18.0 18.0 18.0 18.0 18.0 18.0 16.0 18.0 18.0 (') 18.0 18.0 15.0 18.0 20.0 83.0 82.5 82.5 12.00 5.00 Georgia . 16.00 Hawaii 11.50 11.20 Idaho 82.5 82.5 82.5 80.0 80.0 82.5 V) 16.00 Illinois Indiana 16.00 Iowa 12.00 Kansas 3.25 3.25 3.50 3.25 3.50 3.35 3.00 3.25 "9;25' 8.00 "9;25' "9.30 ie.oo Kentucky 8.50 8.50 8.50 '9!75' Louisiana C) (') Maine 11.75 12.50 12.15 12.50 13.00 Maryland Massachusetts Michigan 80.0 Minnesota 16.00 Mississippi ^ Missouri 12.00 11.75 .8.75 8.50 3.25 3 . 25 3.00 9.25 's.ho' 9.25 18.0 20.0 18.0 18.0 16.0 82.5 82.5 Montana 16.00 Nebraska New Hampshire 12.00 11.50 80.0 82.5 16.00 New Jersey 3.00 New Mexico ' Nevada New York 11.75 11.50 11.75 12.00 12.00 8.50 k'.ho 3.25 3.00 3.25 3.00 3.00 9.25 '9!25' 18.0 18.0 18.0 15.0 82.5 16.00 North Carolina 82.5 North Dakota Ohio V) C) Oklahoma '^ Oregon 11.70 12.00 11.75 8.50 '8.56' 3.20 3.25 3.25 9.25 18.0 18.0 18.0 80.0 82.5 16.00 0) Pennsylvania Philippine Islands. . . . V) Porto Rico 15 Rhode Island 12.00 2.50 82.5 South Carolina 1 South Dakota 8.50 8.50 8.50 8.80 8.50 8.50 8.75 3.25 3.50 3.25 3.20 3.25 3.25 3.25 9.25 9.00 9.25 '9;25' 9.25 9.30 18.0 20.0 18.0 18.0 18.0 18.0 18.0 80.0 82.5 82.5 80.0 82.5 82.5 Tennessee 12.00 12.00 12.00 11.75 15.99 Texas Utah Vermont 16.00 Virginia 16.00 Washington 12.00 West Virginia 1 Wisconsin. . ."". 8.50 3.00 9.00 18.0 82.5 Wyoming ' United States 8.50 3.25 9 25 18.0 82.5 2716.00 See notes on page 269. MARKETING AND BUSINESS MANAGEMENT 269 1 No state standards. 2 No territorial standards. 3 Federal standards for all food products. Fillers in ice-cream may be used if large label is displayed in all places of sale. ^ Percentage of fat based on total solids. 5 Must be labeled. 6 Classed as condensed. 7 United States standard. 8 United States food and drugs act of 1906 applies to the District of Columbia. 9 Should be labeled. 10 Not allowed. 11 Must be so branded. 12 Defined, but no standard. 13 Any amount if fat is maintained. » Solids in fat. 15 Must correspond on stated dilution to state standards for milk. 16 Any less than 30. 17 All below 45. 18 Less than 13 marked skim; 13 to 18, medium skim; 18 or over special skim. 19 Must correspond to 11.5 per cent solids in crude milk; one-foarth to be fat. 20 Two ounces in 10 gallons if labeled gelatine ice-cream. 21 Full cream, 30. Standard, 21. 22 Must correspond to 12 per cent of solids in crude milk; one-fourth to be fat. 23 Less than 7.5, skim; 7.5 to 15, three-fourths skim; 15 to 30, half skim. 2* Three-fourths cream, 24; one-half cream, 16; one-fourth cream, 8. Skim, less than 8. 25 Less than 30. 26 Less than 30; less than 15 not allowed. 27 Less than 16. This applies to all butter made in United States territory. No reports gave standards for powdered milk. 270 THE BOOK OF ICE-CREAM Table XV — Legal Standards for Dairy Products — Continued. States Condensed MILK (sweetened) Alabama i Alaska 2 Arizona ' Arkansas i California . . . Colorado Connecticut Delaware ' District of Columbia. Florida Georgia Hawaii Idaho Illinois Indiana Iowa Kansas Kentucky Louisiana Maine Maryland Massachusetts Michigan Minnesota Mississippi ^ Missouri Montana Nebraska New Hampshire. . . . New Jersey New Mexico i Nevada New York North Carolina North Dakota Ohio Oklahoma i^ Oregon Pennsylvania Philippine Islands. . . Porto Rico IS Rhode Island South Carolina ^ . . . . South Dakota Tennessee Texas Utah Vermont Virginia Washington West Virginia ^ Wisconsin Wyoming ^ United States Total solids Per ct. Fat Per ct. EVAPORATED MILK (un- sweetened) Total solids Per ct. Fat Per ct. Ice cream (plain) Fat Per ct. Gela- tine Per ct. Ice cream (fruit and nut) Fat Per ct. Gela- tine Per ct. 24.5 28.0 28.0 7.70 7.70 43L00 25.5 C) («) 7.80 («) («) 10.0 14.0 0.6 8.0 12.0 28.0 (0 («) 7.70 («) 24.0 («) 7.80 12.0 12.0 («) 10.0 28.0 28.0 34.3 (') 427.60 7.70 7.80 V) 25.5 25.5 7.70 7.80 28.0 (J) 26 . 5 34 . 3 (...) 28.0 427.66 0) 429.50 7.80 (.5) 8.00 28.0 C) 26.5 427.66 429.50 C) 25.5 (0 7.80 14.0 8.0 8.0 12.0 14.0 14.0 10.0 14.0 4.0 7.0 10.0 12.0 (.0) .7 1.0 1.0 (13) .7 12.0 8.0 8.0 10.0 12.0 12.0 8.0 12.0 6.0 7.0 8.0 12.0 28.0 427.67 28.0 427.67 Q) Q) (.') (') 14.0 12.0 14.0 14.0 1.0 12.0 10.0 12.0 14.0 28.0 (19) 25.5 (22) 427.50 (19) 7.80 (0 (22) 25.5 7.80 14.0 12.0 25.5 7.80 10.0 14.0 (20) 8.0 12.0 28.0 C) 427.50 32.3 (J) 25.5 7.80 7.80 12.0 8.0 14.0 1.0 .5 9.0 6.0 12.0 25.0 7.80 25.0 7.80 8.0 1.0 8.0 28.0 25.5 C) {') 28.0 28.0 427.50 7.80 C) U) 427.50 427.50 28.0 25.5 C) V) 34.3 28.0 427.50 7.80 (1 7.80 427.50 14.0 8.0 . 8.0 14.0 8.0 ■(2i)' 12.0 .7.0 6.0 (') 12.0 8.0 28.0 28!6 8.00 '427.56 28.0 8.00 14.0 25.5 7.! 14.0 12.0 12.6. See notes on page 271. 0.6 (») (.0) .7 1.0 1.0 (13) .7 1.0 .2 (20) 1.0 .5 1.0 ■(23)' MARKETING AND BUSINESS MANAGEMENT 271 I No state standards. " No territorial standards. ^ Federal standards for all food products. Fillers in ice-cream may be used if large label is displayed in all places of sale. * Percentage of fat based on total solids. 5 Must be labeled, fi Classed as condensed. ^ United States standard. 8 United States food and drugs act of 1906 applies to the District of Columbia. 9 Should be labeled. 10 Not allowed. II Must be so branded. 12 Defined, but no standard. 13 Any amount if fat is maintained. 14 Solids in fat. 15 Must correspond on stated dilution to state standards for milk. 16 Any less than 30. " All below 45. 18 Less than 13 marked skim; 13 to 18, medium skim; 18 or over, special skim. 19 Must correspond to 11.5 per cent solids in crude milk; one-fourth to be fat. 20 Two ounces in 10 gallons if labeled gelatine ice-cream. 21 Full cream, 30. Standard, 21. 22 Must correspond to 12 per cent of solids in crude milk; one-fourth to be fat. 23 Less than 7.5, skim; 7.5 to 15, three-fourths skim; 15 to 30, half skim. 24 Three-fourths cream, 24; one-half cream, 16; one-fourth cream, 8. Skim, less than 8. 25 Less than 30. 26 Less than 30; less than 15 not allowed. 27 Less than 16. This applies to all butter made in United States territory. CHAPTER XVI CONSTRUCTION AND ARRANGEMENT OF THE FACTORY The exterior construction of the ice-cream plant is of little importance as long as the building is large and strong enough to hold the business, and is neat and clean. The building may be of brick, wood, hollow tile, cement block or any other satisfactory material. The interior arrange- ment should receive careful study and planning. In a new building, devoted to the manufacture of ice-cream, the details usually can be included in the plans. How- ever, it is often necessary to use some building which was not especially constructed or arranged for ice-cream- making. An old building usually can be rearranged so that it will be suitable and fairly convenient. It should be large enough to give sufficient room for the machinery and space for working. If a new building is being con- structed, the plans should be made with a view of possible needs for enlargements. The building should not be so large that there will be waste space. This causes unnec- essary expense and requires useless labor to keep clean. Certain considerations should be kept in mind, whether building a new plant or rearranging an old building. These are discussed in the following paragraphs. 208. Location of the plant. — For the ease of delivery, the plant should be located as near the center of the city as possible. If it is planned to ship much ice-cream by express, a location near the express company is desirable. 272 CONSTRUCTION OF FACTORY 273 If it is a small plant and expects to conduct a retail busi- ness principally, the location should be on one of the main streets of the town in order to reach as many of the con- suming public as possible. Usually sewage connections can be secured in any part of the city so this factor need not be considered. The question of a clean atmosphere about the factory is of much importance; if located in a DRIVE WAY Fig. 83. — Plan of small ice-cream plant. manufacturing section of the city, it is almost impossible to keep the factory clean because of the smoke and cinders. 209. Arrangement of machinery.— Because of the large number of difficult makes of the same kind of machine and the variation in size of the different types, it is impos- sible to make exact plans without knowing the exact size of the machine. In a small plant all the machinery is usually located on the same floor. Such an arrangement is shown in Fig. 83. This is intended as both a retail and wholesale plant. The retail salesroom might be omitted and the plans used for a small wholesale plant. A small 274 THE BOOK OF ICE-CREAM boiler for heating water for washing and sterilizing the utensils might be located in the basement. If desired, tanks for the making of ice might also be placed in the basement. Such a plan is shown in Fig. 84. The arrange- ment should be such as to follow the natural sequence of the process as far as possible. The second story or attic might be used as a storeroom. ^\vv\mvvvvvvvvvvvvvvv\vvv\vvvvvvvvvvv^^^^^ i^'.^'-kk^kk'.W^^V^^kk'^k^kk^W'.^k^^k^W^'-^VW^kk^k^.^^'.W'.W COMPRES.SORS BRINE TAMK ■^"■•""'■i'""^'""^'^ I MEN.'5 LOCKER I ROOM ICE MAKIMQ TAAKS COMPRESSORS ICE STORAGE ROOM / -ICE CRVSHER-s -ICE ELEVATOR- ELEVATOR ^ m\\\\\\\\\^\\^\^^ ;^\\\\\\NW Fig. 84. — Basement plan of large ice-cream plant. The exact location of the machines is not indicated, since this will depend on their size. However, the rooms are large enough so that the exact placing of the machines is not a difficult problem. The basement, first and second floor plans of a whole- sale plant are shown in Figs. 84, 85, 86, For the reasons previously mentioned, the exact location of the machines is not indicated. CONSTRUCTION OF FACTORY 275 5 lit) ■/' en/r,3nce ." .^ I ' ■ '. . 1=T~ TUB STORAGE Sdn^/n express shipmen/s ^ FREEZING •;^.y.fi CREAM STORAGE ' drsin ^vv^v^s.'^ — Kvvvvw^!! — tmv\m\;^w^'s<\s^s\(m^v^^lw^^^ — :-4sV\\vv\^:^?;;^^^:;:;^^ ElEVATOR Fig. 86. — Second floor plan of plant shown in Figs. 84 and 85. 276 THE BOOK OF ICE-CREAM 210. Loading platform. — There should be ample room for the loading of the ice-cream and the unloading of the empties and the returned ice-cream. The loading plat- form should be protected from the storms. Such a plat- form in a large ice-cream plant is shown in Fig. 87; note the chutes for the loading of crushed ice. Often the wagon or auto storage is a part of the same space as the loading platform. 211. Light. — The question of proper light in the ice- cream plant has been neglected. This may be because Fig. 87. — A loading platform in a large ice-cream plant. the buildings in the city are close together and it. is diffi- cult to get light except from the ends of the building which are exposed to the street or alley. Many of the smaller plants are in the basement and in these it is im- possible to have anything but artificial light. The natural light may be secured from windows or skylights. The sacrifice of space for skylights is shown in Fig. 88. Light seems to be a stimulus to keep the plant clean. It also makes it more pleasant and cheerful. It is believed that sunlight tends to disperse disease germs. It would be a great benefit if it were necessary for all ice-cream CONSTRUCTION OF FACTORY 277 plants to have a certain amount of window space in each room. 212. Ventilation. — Next to Hght, the question of proper ventilation is neglected. The windows, doors and sky- lights may serve as a means. If they are used for this purpose and are screened against flies, there is danger of considerable dirt getting in. In some of the large plants. Fig. 88. — The value of skylights is shown by this well lighted freezing- room, considerable floor space above being sacrificed for this purpose. a very extensive system of ventilation is employed. In these, no air is allowed to enter except through this system, and all the entering air is either filtered or washed or both. The air is circulated by a large fan. This insures only clean pure air entering the manufacturing rooms. The importance of pure air about food products cannot be over-emphasized. It is difficult to ventilate a basement properly. All doors and windows should be screened against flies. There should be no stable in connection with the manufacturing rooms. 278 THE BOOK OF ICE-CREAM 213. Floors. — The floors should be of some non-absorb- ent waterproof material that can be cleansed easily. Concrete undoubtedly is the best material, when both cost and adaptability are considered. The floor should slope towards drains which will carry away the water. These should be connected with the city sewage system, septic tank, or cesspool. If sewage connections cannot be obtained, a cesspool or septic tank must be installed, preferably the latter. The drains should have sealed traps to prevent the escape of sewage gas into the plant. Some prefer to have the drain in the center of the floor and others at the side; this is immaterial so long as it works effectively. 214. Ceilings and side-walls. — The ceilings and side- walls should be kept clean. If they are constructed of various tiles or plasters, they can be washed. If made of wood, they should be kept painted. If painted white or light colored, it helps to make the room lighter. 215. Sinks and cupboards. — Proper facilities should be provided properly to wash and sterilize the utensils. There is usually a lack of sinks for washing utensils in the ice- cream plants. After the utensils are properly cleaned, there should be a place where they can be kept until wanted again. Tables, shelves, and cupboards offer suit- able places to keep utensils when not in use. 216. Locker-rooms. — Every plant where food prod- usts are manufactured should be provided with a locker- room in which the employees can change their clothes. Each person should have a separate locker. The locker- room should also contain a lavatory and shower-baths and facilities for washing the hands and face. The locker- room should be kept neat and clean. 217. Cleanliness. — The average consumer appre- CONSTRUCTION OF FACTORY 279 ciates food products produced in clean plants. There is no better advertisement than to invite the public to see the factory. The plant and employees should be so clean that it will make a strong impression and the visitors in turn will tell others. The employees should wear clean white suits-. If the plant is large enough, a laundry for washing may be included in the equipment. 218. Cleaning utensils. — Few ice-cream-makers know how to clean the utensils thoroughly. The following is a good method: (1) Rinse off the milk and grease with lukewarm water. (2) Wash in hot water as hot as the hands can stand. To this water add some washing- powder to cut the grease. There is a tendency to use too much washing-powder. Enough to burn the hands. should not be used. (3) Scrub the utensils in the washing solu- tion with a brush. Do not use a cloth. (4) Rinse with warm water. (5) Scald with boiling water or live steam. The utensils may be dipped in boiling water or boiling water may be poured over them. They may be placed in a sterilizer and live steam applied. The heating kills most of the bacteria and is usually sufficient to dry the utensils. In no case should a cloth be employed for drying. 219. Cleaning the floor. — The proper cleaning of the floor is not considered by many as a necessary part of the manufacturing process. However, it is very impor- tant in the clean appearance of the plant that the floor be clean. Often too much water is used and yet the floor is not clean. The best method is as follows: (1) Rinse the floor with water thrown from a pail; (2) sweep up all loose dirt; (3) make a hot solution of washing-powder, a little stronger than for washing utensils, and spread this on the floor and scrub with floor broom, scrub toward the drain; (4) rinse with clean warm water thrown from 280 THE BOOK OF ICE-CREAM a pail. If the hose is used, too much time and water are wasted. 220. Storeroom and workshop. — No ice-cream plant is complete unless it includes a storeroom and workshop. More or less supplies must be stored and it helps the general appearance of the plant materially if there is a special room for this purpose. More or less repairs are necessary, so that a workshop should be provided. It is desirable to have this near or a part of the storeroom. 221. Sanitary codes. — ^Many states have ice-cream- makers' organizations or associations. The state organ- izations are united in a National Association of Ice- Cream-Makers. Many of these associations have adapted sanitary codes. Following are some samples: Ohio sanitary code: 1. All factories or shops shall be open to the public at all times. 2. Workrooms must be thoroughly clean and free from dust, foul .atmosphere and contamination, and shall be well lighted, to the end that there shall be no dark corners where rubbish or dirt may accumulate. 3. One square foot of glass surface exposed to natural light, unobscured by buildings or other devices nearer than ten feet, for each ten square feet of floor surface of the workrooms must be provided. Basements shall not be used as workrooms unless these provisions can be met. 4. Garbage and all waste material subject to decom- position, must be removed daily to the outside and de- posited in a can provided exclusively for this purpose, composed of impervious material and provided with a tight fitting cover. Covers must be kept on the cans at all times except when entering or removing the material. 5. The side-walls and ceilings of all workrooms shall be CONSTRUCTION OF FACTORY 281 well plastered, tiled or wainscoated or ceiled with metal or lumber and shall be well painted to the end that they may be readily cleaned and they shall be kept free from dust, dirt and foreign matter and clean at all times. 6. The floors of all workrooms shall be impermeable and be made of cement, tile laid in cement, or other suitable non-absorbent material which can be flushed and washed clean with water. Floors shall be sloped to one or more drains which must be properly connected to the sewerage system. 7. Store and storage rooms for materials must be kept clean and free from objectionable odors. 8. Doors, windows and other openings of every work- room shall be screened during the fly season with screens not coarser than 14-mesh wire gauze, or in any other manner equally effective keep the workrooms free from flies and vermin at all seasons of the year. 9. All factories or shops shall have convenient toilet rooms, separate and apart from the workrooms, and no toilet rooms shall be within or connected directly with a workroom, either by a door, window or other opening. The floors of the toilet room shall be of cement, tile or other non-absorbent material, and shall be kept clean at all times. Toilet rooms shall be furnished with separate ventilating flues or pipes discharging into soil pipes or on the outside of the building in which they are situated. Lavatories and washrooms shall be adjacent to toilet rooms and shall be supplied with soap, running water and clean towels and shall be maintained in a sanitary con- dition. Workroom employees before beginning work and after visiting toilet rooms shall wash their hands and armis thoroughly in clean water. 10. No person shall live or sleep in any building used 282 THE BOOK OF ICE-CREAM as a factory or shop, unless the factory or shop is separated by impervious walls, without doors or windows or other openings from the parts of the building used for living or sleeping purposes. 11. No horses, cows or other animals shall be stabled or kept in any building where ice-cream is made, unless the factory or shop is separated from the place where the horses, cows or other animals are stabled or kept by impervious walls without doors, windows or other open- ings. 12. No person suffering from an infectious disease, which can be transmitted through ice-cream, shall work in an ice-cream manufacturing plant. 13. All workroom employees shall be clean in person at all times and shall wear clean washable clothing and caps. They shall not smoke or chew tobacco while at work. They shall not touch the product with their hands at any time. Employees may be specially designated to cut and wrap brick ice cream and to fill fancy moulds and as this work necessitates some handling of the product, such employees must be scrupulously clean and wear clean, washable clothing and caps. 14. All wagons, trucks, drays, cans and tubs, plat- forms and racks, shall be so constructed that they may readily be cleaned and they shall be kept clean. Utensils must be of smooth non-absorbent material, as tin, or tinned copper, the seams of which are flushed smooth with solder. 15. Suitable means or appliances shall be provided for the proper cleansing or sterilizing of freezers, vats, cans, mixing cans or tanks, piping and all utensils used as containers for ice-cream or raw material, and all tools used in making or the direct handhng of ice-cream, and CONSTRUCTION OF FACTORY 283 all such apparatus, utensils, and tools after use shall be thoroughly cleansed and scalded with boiling water or sterilized with steam. The water supply for washing utensils must be free from contamination. 16. No person shall use any vessel used in the manu- facture and sale of ice-cream for any other purpose. 17. Soft or melted ice cream or any other ice-cream shall not be refrozen under any circumstances. 18. Milk and cream must be stored only in clean re- ceptacles in clean refrigerators. Milk or cream which has undergone various fermentations, gaseous, bitter or other- wise, shall not be used in the manufacture of ice-cream. Flavoring extracts, condiments, syrups, fruits, nuts and other materials used as food must be securely protected from dust, dirt, vermin, flies and other contamination, and must be kept and stored only in clean receptacles. Decomposed, decayed, fermented or rancid food material shall not be used. Ice-cream must be stored only in clean receptacles in clean refrigerators. 19. It is expressly declared that the object of this code is to insure a pure and clean product, made, stored and handled under clean conditions, and no technical defect in the construction of any clause shall relieve any person of the obligation of complying with the letter and spirit of this code in its entirety. 20. All creamery and condensery operators, ice-cream manufacturers and all other dealers in milk and cream, and their customers must cleanse all receptacles used in shipping milk and cream as soon as they are emptied, when same are to be returned by railroad, trolley, or boat, in order to prevent the development of dangerous bacteria to threaten the health of the consumers of the product. 284 THE BOOK OF ICE-CREAM Sanitary code of the association of ice-cream manufacturers of New York state. 1. All factories or shops shall be open to the public at all times. 2. Workrooms must be thoroughly clean and shall be well ventilated and well lighted to the end that there shall be no dark or concealed corners where rubbish or dirt may accumulate. 3. The- side-walls and ceilings of all workrooms shall be well plastered or tiled or ceiled with metal. If plastered or ceiled with metal, they shall be kept well painted with oil paint to the end that they may readily be cleaned and they shall be kept clean at all times. 4. The floors of all workrooms shall be impermeable and be made of cement, tile laid in cement, or of other suitable non-absorbent material which can be flushed and washed clean with water. Floors shall be sloped to one or more drains which must be properly connected with the sewerage system. 5. Storerooms for materials shall be kept clean and free from objectional odors. 6. Doors, windows and other openings of every work- room shall be screened during the fly season, and all work- rooms and storerooms shall be kept free from flies at all seasons of the year. 7. All factories or shops shall have convenient toilet rooms separate and apart from the workrooms, and no toilet room shall be within or connected directly with a workroom either by a door, window or other opening. The floors of the toilet rooms shall be of cement, tile or other non-absorbent material, and shall be kept clean at all times. Toilet rooms shall be furnished with separate ventilating flues or pipes, discharging into soil pipes or on CONSTRUCTION OF FACTORY 285 the outside of the building in which they are situated. Lavatories and washrooms shall be adjacent to toilet rooms and shall be supplied with soap, running water and clean towels, and shall be maintained in a sanitary condi- tion. Workroom employees beginning work and after visiting toilet room shall wash their hands and arms thoroughly in clean water. 8. No person shall be allowed to live or sleep in any building used as a factory or shop, unless the factory or shop is separated by impervious walls, without doors or windows or other openings from the parts of the building used for living or sleeping purposes. 9. No horses, cows or other animals shall be stabled or kept in any building where ice-cream is made, unless the factory or shop is separated from the places where the horses, cows or other animals are stabled or kept by im- penetrable walls without doors, windows or other open- ings. 10. No person suffering from an infectious disease, which can be transmitted through ice-cream, shall be em- ployed in an ice-cream manufacturing plant. 11. All workroom employees shall be clean in person at all times and shall wear clean, washable clothing and caps. They shall not smoke or chew tobacco while at work. They shall not touch the product with their hands at any time. Employees may be specially designated to cut and wrap brick ice-cream and to fill fancy molds, and as this work necessitates some handling of the product, such employees must be scrupulously clean, and wear clean, washable clothing and caps. 12. All wagons, truck, drays, cans and tubs, platforms and racks shall be so constructed that they may be readily cleaned, and they shall be kept clean. 286 THE BOOK OF ICE-CREAM 13. Suitable means or appliances shall be provided for the proper cleansing or sterilizing of freezers, vats, mixing cans or tanks, piping and all utensils used as containers for ice-cream, and all tools used in making or the direct hand- ling of ice-cream, and all such apparatus, utensils and tools after use shall be thoroughly cleansed and rinsed with boiling water or sterilized with live steam. 14. Vessels used in the manufacture and sale of ice- cream shall not be employed for any other purpose by any person. 15. No member shall take back any broken package of ice-cream, nor any unbroken package which contains soft or melted ice-cream. No ice-cream shall under any circumstances be melted and refrozen. 16. It is expressly declared that the object of this Code is to insure a clean product, made, stored and handled under cleanly conditions, and no technical defect in the construction of any clause shall relieve any member of the obligation of complying with the letter and the spirit of this Code in its entirety. CHAPTER XVII HISTORY AND EXTENT OF THE INDUSTRY The history of the development of the ice-cream indus- try is only fragmentary. This may be because the in- dustry has developed very gradually. Exact figures showing the size of the industry are lacking, no authentic figures ever having been brought together. The facts relating to the history of the industry have been gathered and very well put together by F. M. Buzzell, in an article in the " Ice-cream Trade Journal," Vol. 5, No. 3. The history as given here is a copy of the above article. 222. Early history. — *'From motives of comfort and health, the instinct of man in all ages and climates has been to maintain his physical (if not his mental) being at a temperature as nearly normal as possible. Thus we find the natives of Iceland and other very cold climates living upon heat-producing foods, fats, tallow candles, and such delicacies, while the South Sea Islander lunches on a little fruit or cereal, or other food producing a minimum of bodily heat. This rule applies also to liquid refreshment. Hot weather creates a demand for cooling drinks, and vice versa. And we, in our day, when we sit in the coolest spot to be found on some sweltering August night, and sip our favorite cold drink, are actuated by the same mo- tive which has influenced our ancestors from the more recent past back to the days of Job and Solomon the Wise. For the Bible tells us indirectly that the people of Palestine knew and appreciated the refreshing quality of snow in 287 288 THE BOOK OF ICE-CREAM time of harvest. The Jews, the ancient Greeks and Romans were all accustomed to the use of snow for cooling wines and other beverages, and it is to-day used in this way in certain parts of Spain and Turkey. ''Only those southern localities which were favored with the proximity of snow-capped mountains could enjoy the luxury of a snow-cooled beverage or dessert. Where snow is not obtainable, liquids were, and still are, cooled in porous jars, and urns exposed to cool breezes, or, in lack of a breeze, swung about to create a current of air. The principle is a familiar one. The most common method of preserving snow was to saturate it with water, having packed it closely into some receptacle, of considerable size probably, and allowing it to freeze into a kind of porous ice, from which blocks could be cut as required for use. To chill a dessert or a liquid, the dish containing it was imbedded in a larger vessel partly filled with snow and particles of ice, and the open space closely packed with it. It was then allowed to stand until it had become as cold as possible or as desired. "Alexander the Great is said to have been very fond of iced beverages, and one of our modern varieties, the Macedoine, it is said, was named for the great Macedonian. Snow and ice were used at the table in the court of Henry III of France in the hot summer months. The Italians, it is claimed, made the first improvement in the original method of cooling, which improvement was to dissolve saltpetre in water and pour a little of the solution in with the snow and ice surrounding the dish to be cooled. Later, it was found that better results were attained by dropping the saltpetre directly into the snow and ice, and at the same time revolving the vessel containing the substance to be chilled. By this means the mixture in the vessel could HISTORY AND EXTENT OF THE INDUSTRY 289 be brought to a fairly solid state. Wines were commonly iced in this way, then water, sweetened and flavored with various juices or other flavorings, was made into a sort of water ice. Water ices and such refreshments are still the rule in the Orient, while ice-cream, as we know it, is rare. ^' There is no reliable record of the first water ices. Dates and places are either lacking altogether in the vague allusions made to them or are so indefinite as to be of no value. It is probable that they were brought to France from Italy by Catherine de Medici, who preferring cookery to which she was accustomed, brought her staff of cooks with her. The date is given as about 1550. Water ices are said to have been made by Contreaux, an Italian who established a famous cafe in Paris. Lemonade was in- vented about 1630: to whom the credit belongs is not known. From water ices to mixtures containing milk or cream and eggs, was apparently a logical progression, but history is vague on the question of who first made ice- cream." 223. Development of ice-cream in the household. — *'It is recorded that in Rome, a certain Quintus Maximus Gurges, nicknamed 'The Glutton,' a well known writer of those times on subjects pertaining to the table wrote a recipe in one of his books for a dish that somewhat re- sembled ice-cream. The name ice-cream is one of modern origin, the original terms being butter ice, or cream ice, the latter being to-day favored in England. The earlier forms, after the ices containing milk or cream, which were really the first ice-creams known, were called butter ice probably because of their rich butter-like consistency, being made from rich cream and spaddled. Cream ice is said to have been known in Paris in 1774. Recipes for 290 THE BOOK OF ICE-CREAM water ices and milk ices, it is claimed, were brought from Asia by Marco Polo, who visited Japan in the fifteenth century. Cream ice is mentioned in an account of a banquet given by Charles I, of England. The dish was made by a French cook named De Mireo, and it is related that the king was so well pleased with the 'frozen milk,' as he called it, that he pensioned the cook with twenty pounds a year on condition that he would not divulge the secret of making the dessert, nor make it for anyone but him. Another account says that the first ice-cream was set before the Due de Chartres on a hot day in August, 1774, by his chef, who had depicted the duke's coat-of- arms on the cream. Again we find in an account of an entertainment given by Louis XIV, of France, that ' toward the end of the feast, his chef caused to be placed before each guest, in silver gilt cup, what was apparently a freshly laid egg, colored like those of Easter, but, before the company had time to recover from their surprise at such a novelty at dessert, they discovered that the sup- posed eggs were a delicious sweetmeat, cold, and com- pact as marble.' It is also claimed that a certain Carlo Gatti first introduced cream ices into England. "A French cook, Clermont, residing in London, gave instructions for making sweet ices in a book he published in 1776. English cook books one hundred and fifty years old give recipes for cream ices in which cream and milk, sugar, eggs, arrowroot or flour and flavoring were used. Recipes have always varied according to the whim or desire of the maker, and there is no similarity in the amounts of cream or milk to be used. "It is. a question whether Germany or England first made ice-cream, but it is generally conceded that the Germans led the English in making fancy moulded creams. HISTORY AND EXTENT OF THE INDUSTRY 291 ''We deduce from the foregoing bits of narrative that ice-cream was not apparently discovered, but rather was the result of a slow process of evolution or development, which was taking place in different localities at about the same time. History states that ice-cream was first sold in New York by a Mr. Hall, at 75 Chatham street, now Park Row. Ice-cream is mentioned in an account of a ball given by a Mrs. Johnson, December 12, 1789, and was introduced to the city of Washington by Mrs. Alexander Hamilton at a dinner at which President Jackson was present. She had become familiar with the dish in New York. The first advertisement of ice-cream appeared in a New York paper, the Post Boy, dated June 8, 1786, and reads as follows: 'Ladies and gentlemen may be supplied with ice-cream every day at the City Tavern by their humble servant, Joseph Crowe.' A negro, one Jackson who had worked at the White House in Washing- ton after Mrs. Hamilton introduced ice-cream to Presi- dent Jackson, learned the recipe and started a confec- tionery. He sold his cream readily at one dollar per quart. Others imitated him, but Jackson held his custom and prospered by making the best goods and died wealthy." 224. Development of wholesale ice-cream. — ^' Jacob Fussell is admitted to be the father of the wholesale ice- cream business. The year 1851 found him in the milk busi- ness at Baltimore. His supply of milk came into Baltimore on the Northern Central Railway from York county. Pa. A few of his customers wanted cream, and finding that satisfactory results were not obtained by ordering cream intermittently to supply an unsteady demand, he made arrangements for a regular shipment. Here again a diffi- culty presented itself, for at times he found his stock of 292 THE BOOK OF ICE-CREAM cream accumulating, which must be disposed of in the best way possible. To utilize this surplus he conceived the idea of making ice-cream, the retail price of which at this time by the few confectioners who sold it was sixty cents per quart. The idea proved an inspiration, for the ice-cream business soon overshadowed the milk business, which was in time disposed of. Mr. Fussell believed in the value of printers' ink and advertised his new business, and then, as now, intelligent advertising paid. Devoting his entire attention to the ice-cream business, he prospered in it, and built up a large business, the success of which has continued through three generations to the present day. In 1852 and 1853 he tried out a scheme for making his ice-cream at the source of supply of his raw material, rather than at the distributing point, but it did not prove successful, for while the ice-cream was actually produced cheaper in the country, the fact that his own attention was divided between the two establishments, and that the stock at the selling end could not be readily controlled, counteracted the lesser manufacturing cost, and the re- sult was that the project was abandoned and not repeated. In 1856 the Baltimore business was left with a partner and a factory was opened in Washington, D. C. In 1862 Boston was added to the chain of plants. Here a large exporting firm, who had made considerable money shipping ice to London, India, and Brazil, saw a new outlet for ice in the ice-cream business. They attempted to induce Mr. Fussell to go to Brazil and start a factory there, and offered to back him with the necessary capital if he wanted it, but he was not interested. Failing to get him to send one of his men over, they arranged for one of their own men to learri the art of making ice-cream, and paid a modest 1500 for the formula. How the South American venture HISTORY AND EXTENT OF THE INDUSTRY 293 fared is not recorded. In 1864 the New York house of Fussell was started and continued with the usual success. Here the prevaihng price among confectioners was $1.25 per quart. A Mr. Brazleton, of Iowa, a friend of Mr. Fussell, losing his fortune in the panic of 1857, came to Washington and learned the ice-cream business. He went back west and opened a factory in St. Louis, later going to Cincinnati and Chicago. "American enterprise was not long in taking up the new industry, and the growth of the business had com- menced. However, the real development, the day of large figures in the business, had its beginning not over fifteen years ago. The brine or refrigerating system of freezing ice-cream has been efficiently applied only within the past five years, and has now only fairly begun. "The first real progress toward artificial refrigeration is said to have been made by a German in 1867, and it was then used only in breweries, and to a very limited extent. Ice making by artificial means came next. The use of refrigerating processes for making ice-cream was probably begun in a way by chance, for large ice manu- facturing establishments put on an ice-cream department to utihze the broken or waste ice, and the possibility of applying mechanical refrigeration to the making of ice- cream was no doubt thus discovered. "Ice-cream is not today, as in past years, a luxury. Its lowered cost brings it within reach of the masses: no longer is it something which may be enjoyed only by the rich. It is fairly entitled to a place in the class of neces- sities. Ice-cream is in high favor in England, where the climate favors its use the year through. And it is used by nearly all steamship fines, especially those making long trips in warm climates. The passengers, who do 294 THE BOOK OF ICE-CREAM not relish the indifferent quality of most foreign made goods, demand American ice-cream. Every express steamer of the North German Lloyd Line leaves New York with not only a supply to care for the wants of its own passengers, but enough to furnish the Japanese, Chinese, and Australian service of the company. For the far eastern service the cream is carried in refrigerated compartments to Bremerhaven and there transferred to ships sailing for ports in India, China, Japan and Australia. '^It does not seem proper to close this paper without some allusion to our friend of the lawn party, ice-cream wagon, and county fair — the ice-cream cone. I have heard that it was introduced in this country at the St. Louis exposition. I have found directions for preparing a refreshment called 'fried ice-cream,' sometimes known as 'Alaska pie,' or 'Alaska fritters.' The method is, briefly to dip a cube of hard ice-cream into a thin fritter batter and then plunge it into very hot lard or olive oil. The pastry forms a good protector from the heat and hardens so quickly that the cream is not softened in the least. Another more elaborate form is said to be served in certain New York cafes today. The fried ice-cream was introduced at the World's Fair in Chicago in 1893. It occurred to me that these freak varieties may have sug- gested the idea of the ice-cream sandwich and ice-cream cone. Whatever the origin, we will have to admit that the cone has sold many a gallon of ice-cream and made many a 'dollar for those engaged in the business. "And I believe that the future historian of this business, who shall recount the progress of its development during the years from 1900 to 1910, cannot but remark upon that decade as being epoch making in the annals of the trade." 225. Extent of the industry. — While no census figures HISTORY AND EXTENT OF THE INDUSTRY 295 of the industry have ever been assembled, careful esti- mates and surveys have been made by both T. D. Cutler of the ''Ice-Cream Trade Journal" and L. O. Thayer of the " International Confectioner." The results of these surveys are shown in Table XIV. In comparison to the value of ice-cream, the 1910 census gives the follow- ing values for the year 1909, for butter, cheese, and con- densed milk; value of all dairy products, $596,413,463.00; value of butter, cheese, and condensed milk made in fac- tories, $274,557,718.00; total investment in equipment, $71,283,624.00. Regarding the distribution of the whole- sale plants in the United States, the North Atlantic states have the most, with the Middle West a close second. The production of ice-cream in the South is growing very rapidly. This is possible because of the homogenizers and emulsifiers and mechanical refrigeration. 296 THE BOOK OF ICE-CREAM o o o o o o R o o eo' o" fo" Tf< T-H IC (N 00 O ■ 00 in" -j" eo 05 CO tH * o r>r in' o CO 00 ic t> o 10 p^ 2 000 000 000 o' o" o" 000 000 000 000 000 o" o" o* 000 000 00 o CO d o co" CO_ 05 IN- O O o o" 10 co" o o o o o CO CO 00 o o O'O o o o" o" ■* IM d § § 7-^ q_ ^ Tt< hH B -* 5 0" t-h" CO 10 CI 10" CO 0" ^ OS 10 (N" CO 00 IN 05" co" CO CO 1—1 CO l-H (N P5 [ d d ^ d d l-H § < *<-< eo 5 c^ H 03 16 00 CO 00 co_ in" 00 CO CO 00" CO CO I> rt< CO <=■ 2 <=> 2 o o *- fe ^ S - =^113 1 £ P O ^ 0} a; C o c3 (D o > — ai - .9 = ^^M fl.S s -w Q 03 cj 03 03 O S aj > ft {4 tf >^ P^ INDEX Acid-coagulating group, 175 Acid-forming group, 175 Acid test, 200 Adulterated ice-cream, 4 Advertising, 255 Alexander, Jerome, 248 Ammonia machines, 116 Andels, 101 Automobile truck, 251 Available refrigeration, 110 Ayres, S. H., 11, 21 Ayres, S. H., and Johnson, W. T., Jr., 175 Babcock test, 183-197 cream, 192 laws, 266 modifications of, 197 skim-milk, 196 whole milk, 183 Bacilli, colon, 181 Bacteria, 15, 170 acid-coagulating group, 175 acid-forming group, 175 alkali group, 178 conditions for growth, 16 effect of temperature, 20 forms of, 16 freezing and hardening, 174 inert group, 177 number of, 171 peptonizing group, 179 prevention of growth, 18 sources of, 170 total acid group, 175 types of, 175 utensils, 174 Bacteriology, problems of, 181 study of, 181 Baer, A. C, 139, 163 "Batch," 129 Baume scale, 27 Benkendorf, G. H., 213 Benkendorf test, 213 Binders, 51 effect of, 167 Bisque ice-cream, 73 Boiled milk test, 203 Brainard, W. K., 167 Brick-cutting machine, 159 Brick molds, 159 Bricks, 145 Brine Idox, 148 freezer, 84 tanks, 119 British thermal unit, 101 Bookkeeping, 258 Bowen, John T., 101, 107, 111 Butter, 41 Butter testing for fat, 205 moisture, 205 salt, 207 Buying materials, 257 Buzzell, F. M., 287 Cabinet, 253 Can washerSj 95 Caramel ice-cream, 72 Carpenter, M. R., 151 Census figures, 295 Chocolate and cocoa, 46 adulteration of, 49 composition, of, 48 manufacture of, 47 297 298 INDEX Chocolate and cocoa, standard for, 48 Chocolate ice-cream, 72 Chocolate sirup, 49 Clarifier, 22 Cleanliness, 278-280 Clemner, P. W., 21 Coffee ice-cream, 72 Colloids, 249 Color, 132 Composition, 249 Compressor, 117 Condensed milk, 25 marketing, 31 method of manufacture, 25 purchase of, 28 standard for, 27 Condenser, 27 Condensing coils, 117 Condensory, 28 amount of milk necessary, 29 capital necessary, 31 condition of milk, 30 location, 31 supply of milk for, 29 supply of water for, 29 Cook, L. B., 21 Cooked ice-cream, 70, 74 Cooling milk and cream, 18 methods of, 19 Cooper, Madison, 101 Corbett, L. C, 104 Corn sirup, 45 Corn starch, 55, 70, 76, 77, 169 Coumarin, 64 Cow, food for, 13 health of, 14 Cream, composition of, 23 emulsified, 41 homogenized, 41 standard for, 24 Creamers, 95 Crystallization, 167 Custards, 76 Cutler, T. D., 295 Dairy products, legal standards, 267-271 Defects, 165 appearance, 169 body and texture, 166 Defects, flavor, 165 package, 169 richness, 169 Defrosting the coils, 151 air blast system, 154 cold brine drip system, 153 Cooper system, 151 hot brine system, 154 hot gas system, 155 warm liquid system, 155 Delivery, cost of, 252 method of, 250 packages used, 252-254 Disc-freezer, 89 Disease, 250 Dishes, 254 Eggs, 55 Ekenberg Co., 39 Ekenberg process, 39 EUenberger, H. B., 139, 172, 175 Emery Thompson freezer, 87 Emulsors, 95, 141 advantage of, 99 Emulsified milk and cream, 10, 13 English plum pudding, 76 Equipment, 81 cost of, 100 Evaporated milk, 25 Evaporating coils, 118 Expansion valve, 118 Factory, construction, 272 floors, 278 INDEX 299 Factory, light, 276 location of, 272 plans, 273-275 ventilation, 277 Fat, churned, 166 FiUers, 51 starchy, 55 Flavors, 2 Flavoring extracts, 57 Food value, 247-250 Formaldehyde test, 203 Formulas, 45, 71 Fort Atkinson freezer, 88 Frandsen, J. H., 45 Frandsen, J. H., and Markham, E. A., 69, 163 Freezers, 81 brine, 84 disc, 89 Emery Thompson, 87 Fort Atkinson, 88 hand, 83 Perfection, 85 Progress, 86 tub and can, 83 Freezing process, 134 effect of sugar on, 137 proper method of, 137 purpose of, 134 rate of, 134, 137 Fruit, 132 extracts, 68 ice-cream, 73 pudding, 76 Fussell, Jacob, 291 Gelatine, 52, 132, 168 food value, 249 kettle, 53, 91 preparation of, 53 tests for, 52 Gum tragacanth, 132 Guthrie, E. S., and Ross, H. E., 204 Hammar, B. W., 172, 173, 174 Hammar, B. W., and Goss, E. F., 172 Hand freezer, 83 Hardening, 91, 145 effect on quality, 157 forced-air, 149 gravity-air, 149 ice and salt box, 146 method of, 145 time required, 157 Hardening-room, 149 still-air, 149 Heat, sensible, 102 latent, 102 specific, 102 History, 287-289 Holdaway, C. W., and R. R. Reynolds, 167, 215 Homogenizers, 95, 141, 167 advantage, of 99 Homogenized milk and cream, 10, 13 Horses and wagons, 251 Hot well, 26 Hunziker, O. F., 183 Ice, amount needed, 107 field, 103 saw, 106 storing and harvesting, 105 Ice and salt mixture, 107 amount used, 148 Ice-cream, appearance, 164 bacterial count, 164 body and texture, 164 classification of, 69 color, 2, 73, 132 composition of, 249 definition of, 2 demand for, 12, 246 desired standard, 5 factory development, 291 fancy molded, 158 300 INDEX Ice-cream, Federal standard, 2 flavor, 164 household development, 289 ideal standard, 5 materials used, 1 package, 164 poison, 250 richness, 164 standards, 267-271 trowels, 158 when removed from freezer, 134 Ice-cream-making, a science, 6 problems, 6 Ice-cream mixers, 88 Ice-cream powders, 55 Ice-cream receipts, 45, 71 bisque, 73 . caramel, 72 chocolate, 72 coffee, 72 custards, 76 fruit, 73 ices, 78 lacto, 80 maple, 72 milk sherbets, 80 mousse, 73 nut, 73 parfait, 74 puddings, 75 punches, 79 vanilla, 71 water sherbets, 78 Ice crushers, 93 Ice-house, 104 Iceland moss, 55 Ice plow, 106 Ices, 70, 78 freezing, 144 Ice shovel, 94 Ice spud, 94 Irish moss, 55 Joseph Burnett Extract Co., 57 Judging and defects, 163 Keeping quality, 167 Lacto, 71, 80 Lactometer, 198 Board of Health, 199 Quevenne, 199 Laws, 264-271 Lee, C. C, Hepburn, N. W., and Barnhart, F. M., 204 Legal standards, 267-271 Lemon extract, 65 adulteration of, 66 standard forj 65 Lemon oil, chemistry of, 66 preparation of, 65 License, 266 Loading platform, 276 Losses, 262 Machinery, quality of, 81 Manhattan pudding, 76 i. Maple ice-cream, 72 Marketing, 246 /f Market, location of, 250 i Mclnerney, T. J., 18, 174 Mechanical refrigeration, 111 absorption system, 116, 122, 124, 126 compression system, 116 cost of operating, 121 direct expansion system, 118 evaporating coils, 119 materials used in, 113 operating, 120 parts of, 117 principles of. 111 Merrell-Soule Co., 34 Merrell-Soule process, 35 Michigan Agricultural Law, 15 Milk and cream, absorption of odors, 14 INDEX 301 Milk and cream, acidity of, 11 adulterated, 264 ''aged," 12 bacteria in, 15 contamination, 21 neutralization of, 11 proper care of, 22 purchase of, 24 quality of, 11, 13 Milk, composition of, 23 standard for, 24 Milk powder, 33 standards for, 33 Milk powder in ice-cream, 37, 40 Milk products, supply of, 8 method of securing, 9 Milk sherbets, 80 Milk, used, 8 Misbranded ice-cream, 5 VLix, 129 financial viewpoint, 130 step in preparation of, 131 temperature of, 133 Mixers, 88 Mojonnier tester, 218-240 Mojonnier over-run tester, 240 Molds, 15 brick, 159 center, 161 . individual, 161 Mortensen, M., 69, 139, 142, 143, 158, 163 Mousse, 73 National Association of Ice- cream Manufacturers, 3 Nesselrode pudding, 75 New Jersey Agricultural Law, 15 Nut ice-cream, 73 Nuts, 50 Oil traps, 117 Orange extract, 65, 67 Orange extract, adulteration of, 68 standard for, 67 Organisms, disease, 11 Over-run, 134, 139 controlling, 242 factors effecting, 139 to obtain, 143 Over-run tester, 213, 240 Pack-cans, 91, 145 Packing tubs, 262 Parfait, 74 Pasteurization, 11, 140, 172 Peptonizing bacteria, 179 Perfection freezer, 85 Plans of factory, 273-275 Powdered milk processes, 34 "Price Current," 258 Price of dairy products, 258 Progress freezer, 86 Ptomaine poison, 250 Pudding, 75 English plum, 76 fruit, 76 Manhattan, 76 Nesselrode, 75 Punches, 70, 79 Refrigeration, 101 terms used, 101 Rennet, 56 Report blanks, 261 Rice flour, 55 Rose, Flora, 247 Ross, H. E., io, 23, 205 Ross, H. E., Guthrie, E. S., Fisk, W. W., 208 Ross, H. E., and Mclnerney, T. J., 183 Ruche, H. A., 43 Salesmen, 257 Sandwich machine, 254 302 INDEX Sanitary codes, 280-286 Score card, 163 Sediment test, 17 Sherbets, 70, 78, 80 freezing, 144 Shipping clerk, 260 Skimmed -milk, composition, 24 standard for, 24 Slush box, 148 Smoothness, 167 Soft ice-cream, 263 SoHds not fat, 200 Sproule, W. H., 197 Stabilizer, 2, 51, 95, 132 Standard ice-cream, 4 Standardization, 208-212 Stocking, W. A., Jr., 19 Sugar, 2, 43, 131, 173 invert, 43, 46 Sugar-saving substitutes, 45 SweU, 134, 139 Test, acid, 200 Babcock, 183 Benkendorf, 213 hardness, 215 Mojonnier, 218-240 viscosity, 208 Testing, 183 Thayer, L. O., 295 Transfer ladles or scoops, 146 Transferring, 263 , Troy, H. C, 183, 207 ^^ Tub and can freezer, 83 -^ Tubs, 262 f Urner Barry Co., 41 Utensils, cleaning, 279 Vacuum pump, 27 Vanilla beans, 59 Vanilla beans, curing of, 59 marketing, 59 production of, 60 Vanilla, chemistry of, 63 Vanilla extract, 57 adulteration of, 64 ingredients of, 62 Vanilla ice-cream, \ 1 Vanilla plant, 58 Vanillin, 63 Viscosity, test for, 208 Vogt refrigerating machine, 123 Washburn, R. M., 69, 138, 139, 142, 163 Water sherbets, 78 Wisconsin Agricultural Law, 15, 264 Yeasts, 15 Printed in the United States of America.