TP U'tfUiIZATIOIT OF W IOUOR, Canadian Forestry Bulletin 66 ibrar vwri r DEPARTMENT OF THE INTERIOR, CANADA Hon ARTHUR MKIGHEN, Minister ; W. W. CORY, Deputy Minister FORESTRY BRANCH BULLETIN No. 66 R. H. CAMPBELL, Director of Forestry UTILIZATION OF WASTE SULPHITE LIQUOR OTTAWA J. DK LABROQUERIE TACHE PRINTER TO THE KING'S MOST EXCELLENT MAJESTY 1919 491201 Price 50 cents. DEPARTMENT OF THE INTERIOR, CANADA HON. ARTHUR MEIGHEN, Minister; W. W. CORY, Deputy Minister FORESTRY BRANCH BULLETIN No. 66 R. H. CAMPBELL, Director of Forestry UTILIZATION OF WASTE SULPHITE LIQUOR A REVIEW OF THE LITERATURE COMPILED BY Dr. BJARNE JOHNSEN and R. W. HOVEY, B.Sc. f OF THE DIVISION OF PULP AND PAPER FOREST PRODUCTS LABORATORIES OF CANADA Montreal DR. J. S. BATES, Superintendent OTTAWA J. DE LABROQUERIB TACHE PRINTER TO THE KING'S MOST EXCELLENT MAJESTY 1919 491201 ; Agnc.- CONTENTS PAGE. Abbreviations 4 Units (Metric, British, and Money) 5 Preface *;<.*-* ? Introduction 9 Composition 12 Kffluents 35 Binding Material 52 Gums, Adhesives, and Sizing Materials 68 Tanning Materials ., .. .. 78 Alcohol 105 Fuel 126 Fodder ., 136 Fertilizer 141 Dye 148 Sulphur 154 Evaporation . 162 Miscellaneous 168 General 185 Index of Authors. . 193- 43499S 49120 1J ABBREVIATIONS Allgem. Fischerei Ztg.=Allgemeine Fischerei Zeitung Ann.=Annalen der Chemie Arbeit. Kais. Gesundh.=Arbeiten aus dem Kaiserlichen Gesundheitsamte Be.=Baume Ber.=Berichte der deutschen chemischen Gesellschaft Ber. botan. Oes.=tBerichte der deutschen botanischen Gesellschaft Ber. pharm. Ges.=>Berichte der deutschen pharmzeutischen Gesellschaft Biedermanns Zentr.=Biedermanns Zentralblatt fur Agrikultur Chemie und rationellen Landwirtschaftsbetrieb Biochem. Z.=JBiochemische Zeitschrift *Chem. Abs.=Chemical Abstracts *Chem. Eng.=Chemical Engineer Chem. Ind.=lDie Chemische Industrie Chem. Techn. Neuzeit.^Chemische Technologic der Neuzeit Chem. Techn. Ztg.=Chemiker und Techniker-Zeitung Chem. Trade J.=Chemical Trade Journal and Chemical Engineer Chem. Zeitschr.=Chemische Zeitschrift Chem. Zentr.=Chemisches Zentralblatt Chem-Ztg.=Chemiker-Zeitung Collegium (Official organ of the Int. Assn. of Leather Trades Chemists) Comp. rend. soc. biol.=Comptes rendus hebdomadaires des seances de la societe de biologic Compt. rend. trav. lab. Carlsberg=Comptes rendus des travaux du laboratoire de Carls- berg Compt. rend.=Comptes rendus hebdomadaires des seances de Facademie des sciences Deut. Gerber Ztg.^Deutsche Gerber Zeitung Deut. Techn. Ztg.=Deutsche Techniker Zeitung' Deut. Zuckerind.=^Die Deutsche Zuckerindustrie D. Landw. Presse.=Die Landwirtschaftliche Presse Dingler's polytech. J .=Dingler's polytechnisches Journal Engineer=The Engineer Eng. Mining J .==Engineering and Mining Journal *Eng. Record=Engineering Record. Farber-Ztg.=aFarber-Zeitung (Zeitschrift fur Farberei Zengdruck und den gesamten Farbenverbrauch) F&rben-Ztg.=(Farben-Zeitung Gerber="Der Gerber Gesund.-Ing.==5 square inches : cubic centimetre (c.c.)--0-061 cubic inches metre (m.)=-39.37 inches=3-28 feet square metre (sq.m.)=1560 square inches=10-763 square feet cubic metre (cub.m.) (1000 litres)=35-289 cubic feet==1.3079 cubic yards kilometre (km.)=3280-8 feetF=0-621 miles square kilometre (sq.km.)=0.380*square miles=^47-l acres hectare^ -471 acres=115i96-9 square yards gramme (g.)=O.Q35 ounces (av.)==0.0022 pounds (av.) kilogramme (kilo or kg.)=35-274 ounces (av.)=2-204 pounds (av.) metric ton (1000 kilogrammes)=2204.62 pounds (av.)=l'-102 short tons=0-984 long tons 1 litre(l.)=0-2199 gallons (Imp.)=61.023 cubic inches=0.0353 cubic feet 1 hectolitre (hl.)=3.531 cubic feet. inch (in.)=2-54 centimetres square inch (sq.in.)=6.45 square centimetres cubic inch (cu.in.)=L6-387 cubic centimetres foot (ft.)=30-48 centimetres square foot (sq.ft.)=929 square centimetres=0.0929 square metres cubic foot (cu. ft.)=28.317 litres mile (mi.)=1.609 kilometres square mile (sq. mi.)=640 acres=2-59 square kilometres acre=43560 square feet=0- 001562 square mile6=0.4046 hectares=4046 87 square metres Imperial gallon (gal. )=1. 2009 gallons (U.S.)=277.41 cubic inches=4.5459 litres ounce (oz.) (av.)=2S.3495 grammes pound (Ib.) (av.)=453>.59 grammes=0. 45359 kilogrammes short ton=2000 pounds ( a v.) =0.892857 long tons==907 185 kilogrammes=0. 907185 metric ton long ton=2240 pounds (av.)=l-12 short tons=1016.05 kilogrammes=^l .01606 metric tons cord (of wood)=128 cubic feet=3.624 cubic metres FORESTRY BRANCH BULLETIN No. 66 UNITS Concluded. Great Britain Dollars I penny (d)= 1 shilling (s.)= 1 pound ()= Germany 1 pfennig lo a INTEODUCTION The Canadian sulphite pulp industry consumed in 1916, 728,000 cords of pulpwood (see Forestry Branch Bulletin No. 62 B: Pulpwood, 1916). At least one-half of the dry weight of this wood or considerably more than 1,000 tons of wood substance, there- fore, was contained in the waste sulphite liquor which was discharged every day from the mills as a useless waste. This figure is sufficient to show how significant it is for all wood-pulp producing countries to eliminate this waste of material by turning the valuable organic products contained in the liquor into valuable products. That the importance of a proper utilization of the waste liquor has been fully recognized is shown by the great number of references contained in this publication, the author^ register of which contains approximately 350 names of persons who have reported officially on this subject. But in spite of the large amount of work that has already been carried out in connection with this question and notwithstanding the fact that a ifew processes for the utilization of waste sulphite liquor have gained industrial importance in some countries, the problem is far from being solved. It can not be considered to be solved before a process or a combination of processes is established which will utilize all the substances in the liquor so that products will be derived there- from in an economical way and in a quantity and quality which will enable them to compete with present products on the market. The first difficulty in complete utilization of the liquor is presented by the fact that only about 40 per cent of the; total liquor will drain off from the pulp without special arrangements for forced draining, and even with such equipment it would probably be difficult to recover more than 60 per cent. The remaining portions must be removed by water, which means a further dilution and therefore an appreciable 4 increase of the volume, requiring large-sized apparatus for handling. It is of great interest, therefore, to prevent a further dilution of the already very dilute liquor, 'as most of the processes of utilization call for a concentration of the liquor to a certain density. The fact that the economy of many of these processes largely depends upon the cost of evaporation, as the 10 tons of liquor obtained per ton of pulp contain only 11 to 12 per cent of solid substances, has made the question of evaporation one of the most important in the discussion of the waste sulphite liquor problem. Under "Evaporation" p. 162 references have been made to the various methods of evaporation which are as a rule carried out in connection with the simul- taneous recovery of sulphurous acid, but it may be of interest here to point out a few principles of removing the excess of water, which are now in the foreground of the discussion of this point. One of the processes of concentration consists of atomizing the liquor at 100 C., which then in that form is mixed with the hot flue gases at about 270 C. 'The flue gases are thereby assumed to be cooled down to about 180 C., at which temperature one cubic metre of the gases should be capable of taking up and carrying oflf 1 ,000 grammes of water. The' suitability of this principle for sulphite liquors is apparently not sufficiently known to be reported on here. A new evaporator has recently been built by Soderlund^Boberg, which is claimed to give a most efficient utilization of the heat. The idea of this evaporator is to com- press slightly the vapours from the liquor, whereby the temperature of these is raised a few degrees and the heat from the compressed warm steam can be used for the evaporation of further quantities of liquor. Finally, it is worth mentioning the removal of water by freezing as suggested by Oman for the Scandinavian countries with their comparatively cheap water power. The economy of this progress has not been reported on in detail. 9 10 FORESTRY BRANCH BULLETIN No. 66 Among the processes for utilization of waste sulphite liquor only a few are of immediate practical interest to Canada. The manufacture of tanning materials is one of these. The processes of manufacturing have already been reported on and also the suitability of this material for tanning purposes. It will only be mentioned here that Canada imports tannin extracts from sulphite liquor, at a price ranging from three-quarters of a cent to one cent per pound, which are used to a large extent in Canadian tanneries in the preparation of certain leathers, chiefly sole leather. The use of sulphite waste liquor as a road and dust binder and 'as a binder for powdered materials such as peat would seem to be of importance to Canada. The manufacture of ethyl alcohol from waste sulphite liquor is discussed on page 106 and the calculations, which are based upon the experience of operating sulphite spirit plants give a manufacturing cost of $0-185 to $0-32 per Imperial gallon, which is considerably 'less than the cost of production of alcohol from grain. This has been stated by Brecker (in J. Ind. Eng. Chem., vol. 9 (1917), p. 612), for 1916, to be about $0-48 per Imperial gallon, 90 per cent spirit in the United States, and has been estimated somewhat higher for Canada (about $0.60). The main question is, thera- fore, whether there is a sufficient market for this alcohol which without special purifi- cation contains certain impurities, especially menthyl alcohol (about 3 per cent). Recent investigations by the United States Geological Survey (1912) reported on in the United States Bulletin No. 392, and also experiments made in Europe, prove that the alcohol can be used with great advantage for motive power. United States Bulletin No. 392 contains details of this point and in Hagglund's book on Alcohol from Waste Sulphite Liquor, referred to on page 122, an interesting discussion of this problem is contained. It has been found that in motors of special construction a very efficient utilization of heat is obtained. This is at least the case with stationary motors of low speed (not above 300 revolutions per minute) which can give a heat efficiency of 33 per cent in the case of spirit motors, while the heat efficiency in benzine motors as a rule is about 23 per cent. This good result is obtained only when the compression ratio of 10 to 1 is used in the alcohol motor against 4 to 1 with the benzine motor and when cooling water of a suitable temperature, namely about 100 C., is used. But this special alcohol motor with high compression cannot be used for high speed motors in vehicles, and it is a decided drawback that the alcohol motor cannot be used for benzine, without alterations. The usual benzine motor can, however, be operated with alcohol if slight alterations are made with the carburetting device in order to obtain the most favourable proportion of the air-alcohol mixture. The efficiency js considerably in- creased if the air is preheated by utilizing the heat in the exhaust of the motor. One disadvantage is presented in regard to the starting of the motor alcohol or the usual alcohol-benzol mixture. It is necessary in this case to start the motor with benzine before using the alcohol, which makes two containers and two carburettors necessary. Canada produced in the calendar year 1916, 7-5 million gallons of crude petro- leum valued at $39)2,300. The imports of crude and refined petroleum were about 290 million gallons valued at about $14,000,000. It can be seen, that Canada is dependent on foreign sources for her supplies of petroleum and petroleum products. In 1916 the imports of refined and illuminating oils amounted to over 8,000,000 gallons valued at $540,000 and during the same year 18,000,000 gallons of gasoline were imported. If industrial alcohol couid be produced economically in Canada it would mean a saving in imports of over $4,000,000. On the basis of a manufacturing cost of $0.185 to $0.32 per Imperial gallon for 100 per cent alcohol from waste sulphite liquor there ought to be some hope, if suitable markets and legislation were provided, to introduce this alcohol for industrial pur- poses. The total production of alcohol from waste sulphite liquor would be about 3,320,000 gallons of absolute alcohol, which would assist in freeing Canada from dependence on foreign sources as well as utilize a waste product. The manufacture of. alcohol from waste sulphite liquor does not solve the waste liquor problem completely as only about 15-20 per cent of the total solid of the liquor UTILIZATION OF WASTE SULPHITE LIQUOR 11 is utilized. But the residual liquor from the alcohol process may be made useful by employing one of the other processes, for instance in producing binding material, fuel. or using the dry substances for destructive distillation. The use of waste sulphite liquor products for cattle food has not given very satis- factory results, and as a fertilizer the waste liquor has only an indirect value, as it contains the chief chemicals required of a good fertilizer, namely nitrogen and phos- phate, in very small quantity. It may, however, be useful in mixture with other products such as cyanamide, and may improve a soil poor in humus on account of its organic substances which form a good medium for the growth of nitrogen-fixing bacteria. As a mordant the sulphite ligiiin or more correctly the substances precipitated by albumin or gelatin or salted out with sulphate or chloride of sodium, have been pro- posed under names such as lignosin and Rignorosin. Of theoretical interest, but still without any practical value, are the condensation products with aromatic amines and the preparation of azo-dyes by coupling aromatic di-azo compounds with lignin sul- phonic acid or its salts, obtained from waste sulphite liquor. Kecently it was suggested that sulphur dyestuffs might be prepared by heating sulphonic acids or sulphonates with alkali sulphides or other sulphur-containing substances, dissolving the product in water and precipitating with acid, but all the attempts in producing dyestuffs from the waste sulphite liquor are still limited to laboratory experiments. The precipitation of organic substances at high temperature and pressure as suggested by Strehlenert, for use as a fuel or for destructive distillation, is probably, in the present form, not of immediate interest to Canada, but the development of this very interesting process should be followed with the greatest interest by the sulphite pulp manufacturers. It is evident from the facts collected in this publication that only very few of the proposed processes have reached any industrial importance and that there is an immense field open for scientific investigation and practical applica- tion before the problem is solved. A research laboratory has recently been established in Sweden for the purpose of investigating the waste sulphite liquor problem. This laboratory will carry on research on the more important problems connected witli the utilization of the waste liquor and will endeavour to work out new methods for its utilization. COMPOSITION Considering the importance of an exact knowledge of the raw materials "used in any chemical process, "it is surprising that the great sulphite industry reached such a point of perfection before the nature of the chief raw material, the wood, had been thoroughly investigated. The development of special methods for wood analysis in the last few years has allowed a more intimate study of the constitution of the woods, and much important information has been secured regarding the characteristics of various species. However, our knowledge of the exact composition of the woods used in the sulphite pulp industry and, therefore, of the details of the cooking process is still too limited to permit of any definite conclusions with regard to the apparently very* complicated composition of the waste sulphite liquor. On the other hand con-- siderable work has been done by the most able investigators to determine the nature of the substances present in the waste liquor. The results of these investigations, which date back to the early years of this industry, not only furnish a valuable material for a better understanding of the cooking process as well as of the chemical characteristics of the wood but they are also of the greatest importance in the discussion of the value of certain processes for utilization, of the waste sulphite liquor. The chief constituents of European spruce wood are according to Klason: Cellulose.. about 50 per cent Carbohydrates- " 16 Lignin 30 Protein 0*7 " Rosin and fat 3'3 These figures no doubt give an excellent idea of the nature of the average wood material employed in European mills. But there is less uniformity in this raw material on the American Continent, due to the employment of different species such as black, red, and white spruce, balsam fir, hemlock, etc. which vary considerably with regard to their chemical composition. The following table contains average values for the ordinary Canadian pulp woods : Cellulose. Lignin. Resin. Pentosan. White spruce % 55 % 26 % 10 % 11 Black spruce 55 26 75 11 Balsam fir 51 29 1'50 11 Hemlock 49 26 1*75 12 The cellulose is determined by treating the wood, after removal of resins, with acetic acid in glycerin followed by the usual chlorination method, as suggested by Cross and Bevan. This cellulose is not absolutely identical with cottun cellulose, as it still gives the furfural reaction due to the presence of substances which are apparently so intimately attached to the cellulose that they can not be removed without partly destroying the cellulose itself and are not removed even at the high temperature and pressure prevailing in the sulphite digester. In fact it has been found that the amount of furfural-yielding substances in the cellulose residue after chlorination treatment corresponds to that of a high-grade sulphite pulp, about 70 per cent of the total of these substances present in the wood being removed in the cooking process as well as 12 COMPOSITION OF WASTE SULPHITE LIQUOR 13 by this method of cellulose determinations. As the other impurities, chiefly ligndn in both cases, can be completely dissolved out, the figures given for cellulose may be regarded as correct values for pulp obtainable. The lignin is determined by dissolv- ing out all the other substances with 72 per cent sulphuric acid after the resins have been removed. The values for pentosans are calculated from the yield of furfural from the original wood, making allowance for those substances still remaining in the cellulose residue which gives the furfural reaction. This of course is not absolutely correct, as part of the furfural may be traced back to other substances such as pen- toses, furfuroids, etc., but there is no reason to believe that there is much variation in these substances in the different species as the furfural yield is practically the same in all these woods. Assuming Klason's value of 0-7 per cent protein for these woods we obtain a good idea of their chief constituents. It must be remembered that the values given in the table are by no means absolute for all trees of the same species. It has been found that the cellulose content varies in the same tree with the distance from the ground and that in white spruce two samples taken at a distance of 48 feet .apart show a difference in cellulose of as much as 4 per cent. There are also slight variations in the resin content of different parts of the same tree. The lignin content seems to increase with the distance from the ground, but not in proportion to the decrease in cellulose. The remainder of non-cellulose substances in the wood repre- sents chiefly lower carbohydrates which are easily hydrolyzed and can be partially dissolved out with boiling water. The nature of these substances has not been suffi- ciently studied although they are apparently of great importance, furnishing as it seems the chief raw material for the fermentable sugar in the waste liquor. Schorger (J. Ind. Eng. Chem., vol. 9 (1917), p. 554) found that the coniferous woods contain appreciable quantities of mannan and discovered in one white spruce as much as 7 per cent of this sugar. Klason, however, found only 2-5 per cent mannose but 7-9 per cent glucose and 1-3 per cent galactose. It was mentioned above that high-grade sulphite pulps contain very little or no lignin, that, further, a large proportion of the furfural-yielding substances and other lower carbohydrates are removed by hydrolysis in the cooking process. The resins and fats are only incompletely removed. It is therefore possible by means of these analytical data to form an opinion regarding the substances that may be expected in the waste liquor, but the quantity of these sub- stances will naturally depend on many factors such as the species, the size of the wood, and cooking conditions such as condensation, relieving, temperature, and pressure. The quantity of fermentable sugar especially may depend largely on the last two factors, and must evidently be regarded as the residue of sugar present in the wood or formed at an early stage of the cooking process. Great differences would therefore be expected in liquors from Bitter-Kellner cooks as compared with those obtained by the Mitscherlich process, due to the higher pressure and temperature in the former. The variations in method of cooking by the Ritter-Kellner process may also account for the variations in the results arrived at by different investigators. Another point which seems to be of importance is that the liquor may change a good deal when left standing for a considerable period. As the liquors in most cases must be used imme- diately after the end of the cook the analysis of the fresh waste liquor will be of most interest. During the process of cooking, iliquor as well as gas is relieved from time to time. In this way large quantities of sulphurous acid escape and are recovered by special apparatus and returned to the acid system. Besides sulphurous acid the vapours also contain other volatile products, which can be condensed in special apparatus and puri- fied. Bergstrom found that the condensate thus obtained at a certain period of the cook, amounting to 400-600 litres per ton of pulp (79-120 gallons per short ton), con- tains, besides about 100 grammes (0-22 pound) of sulphurous acid, 5-5-5 grammes of methyl alcohol per litre, which is equivalent to about 2-6 kilogrammes per ton of pulp or 5-2 pounds per short ton. The oil which floats on the top of the condensate is a complex mixture consisting largely of cymene and containing a small quantity of furfural and a solid terpene alcohol. 14 FORESTRY BRANCH BULLETIN No. 66- The crude alcohol obtained from the condensate contains acetone, acetaldehyde, and other substances such as traces of acetic and formic acids, but the alcohol can easily be purified. From the oils cymol can readily be produced in a pure state and furfural may be obtained in small quantities and purified. Only about one-third of the total methyl alcohol formed in the cooking process is present in the condensed vapours. The quantity of methyl alcohol as well as of the other substances depends mainly upon the method of relieving and the temperature and pressure, at the time of blowing. Therefore, most of these volatile substances can be found in the waste liquor in greater or less amounts, depending upon- the method of cooking. For example it has been found that the furfural content of the Kitter- Kellner liquor is considerably higher than in the Mitscherlich liquor; in fact the difference is so great that it may serve as a qualitative reaction for the identification of these liquors. The waste liquor, which has a specific gravity of about 1 05 and gives an acid reac- tion, contains about 12 per cent organic and 1-1-5 per cent inorganic substances. The dry residue, in other words, contains 10-15 per cent of ash. Of the 6-10 per cent of sulphur present in the liquor only 2 per cent remains in the ash mainly as CaSO 4 and OaS, as most of it escapes as S'0 2 when the liquor is heated. There is always a small quantity of sulphurous acid in the liquor in the free form and loosely combined with sugar, so that it may be removed to a large extent by heating with or without the addition of an acid. Besides sulphurous acid the liquor also contains small quantities of sulphuric acid, acetic and formic acids, oxalic acid, and traces of citric acid. Among the other substances detected in small quantities in the waste sulphite liquor, according to Tollens and Lindsey, are vanillin, identified by the odour test, and succinic and protocatechuic acid identified by their decomposition products, pjyrrole and pyrocatechin. In the rectification of alcohol from the waste liquor a reddish-brown oil separates out from which Klason and Segerfelt recovered optically inactive borneol similar to that obtained by treating turpentine with sulphuric acid. The borneol may be formed in the digestion process from bornyl acetate (or a similar ester) originally present in the volatile oils of the wood. Cross and Bevan discovered that when glue is added to the waste liquor a precipitate is obtained which is soluble in alkali or sulphites and which may serve as a substitute for rosin size, since the solution may be precipitated by aluminium sulphate. This behaviour towards animal glue has been regarded as a reaction of tannin com- pounds, but it is claimed by the tannin industry that if tannin is present at all it must be in a very small quantity. The carbohydrates and the lignin are the sources of the most important constituents of the waste liquor, namely, the sugars and the calcium salt of the lignosulphonic acid. The liquor gives the reaction of carbohydrates, reduces Fehlings solution strongly and also dyestuffs and chromium salts. Further, it gives an osazone precipitate with phenyl hydrazine and yields furfural on distillation with hydrochloric acid. Krause, who studied the sugars in the liquor from a Mitscherlich cook (indirect cooking) and from a Ritter-Kellner cook (direct cooking), obtained the following results: Ritter-Kellner. Mitscherlich. Total sugars ... % 1'47 % 1'48 Pentoses 0'41 0'47 Mannose . . . 0'48 0-48 Galactose O'Ol 01 Fructose . . . . 0'25 0'28 Dextrose , COMPOSITION OF WASTE SULPHITE LIQUOR 15 More recently Klason has published some results of his investigations of the sugars present in a Ritter-Kellner liquor which differ considerably from those arrived at by Krause, as is shown in the following table: Mannose . . . . 0'526 per cent Galactose . . . . 0'279 Glucose 1*65 Arabinose 0'90 Although the fermentable sugars represent only a very small percentage of the organic substances in the waste liquor they form the raw material for the most promising processes for its utilization at the present time, namely the production of alcohol. By far the greater proportion of the solid matter in the liquor is present as a lignin-calcium compound, the lignin substance of the wood combining with the sulphurous acid during the cooking process to form sulphonic acids. The calcium compound of these sulphonic acids may be precipitated from the concentrated liquor by alcohol, or by sodium chloride or magnesium sulphate. Concentrated mineral acids and lead acetate also precipitate the salt. The purification of the salt, however, is very difficult as it does not crystallize from its solutions. The compounds obtained by precipitation have been analysed by various investigators, and formulae for the salt and for lignin sulphonic acid, as well as for lignin, have been deduced from the results obtained. The most important investigations on this subject have been carried out by Klason, and the interesting results of these investigations will be found in the literature, especially his book " Beitrage Zur Kenntniss der Chemischen Zusammensetzung der Fichtenholzes" ("Contribution to the Knowledge of the Chemical Composition of Spruce Wood' 7 .) Klason succeeded in separating in a high state of purity the barium salt of the lignin sulphonic acid in the following manner : The liquor was concentrated in vacuo till nearly dry and the residue dissolved, by which means part of the gypsum and sulphite were separated out. The liquor was then neutralized with calcium carbonate and crystallized calcium chloride was added as long as it went into solution, in which manner a thick precipitate was formed. The liquor and precipitate were then boiled for 3 hours, after which the precipitate was separated out and washed with alcohol. In this way only about one-half of the calcium salts of the liquor was obtained. In order to transform this salt into a barium salt, sulphuric acid was added in a quantity corresponding to the amount of lime present. The liquor was then concentrated at ordinary temperature to a thick consistency, whereupon alcohol was added. The gypsum was separated out and the alcohol evaporated off at ordinary temperature. The liquid was then diluted with water and neutralized with barium hydrate, the amount required having been previ- ously determined by titration. As it is usually difficult to filter the liquid, alcohol was carefully added until a precipitate was just formed. Before the addition of alcohol the liquor was allowed to stand till all barium sulphate formed had settled. The barium ligno-sulphonate was precipitated from the clear solution by the addition of alcohol. According to Klason the analysis of this salt points to the formula C4oH440i7S2Ba, and accordingly the lignin must have the composition C4oH42On or, as the molecular weight of the barium salt has been found to be at least 6,000, the formula may be (O4oH42Oii)6. It has been mentioned above that only about one-half of the lignin-calcium compound is precipitated from the waste liquor. From the high methoxy content of the precipitate and that of the wood, Klason con- cludes that there is a second lignin in admixture with the first, with no, or at least a very low methoxy content and a higher hydroxyl content, and has suggested the formula CasHssO^ (C4oH42On-2CH2-f-O) ; the lignin represents chiefly a conden- sation product of coniferyl alcohol and hydroxy coniferyl alcohol, the groups appar- ently having the same position as in gallic acid, namely, 1, 3, 4, and 5. In the formation of the sulphonic-acid salt in the cooking process it is stated that two molecules of SO2 are added to the lignin, forming a sulphonic acid. Besides this the lignin can combine with two more SO 2 molecules one of which is very loosely 16 FORESTRY BRANCH BULLETIN No. 66 attached so that it may be partially titrated with iodine at ordinary temperature, whereas the second molecule is more closely combined but can be separated quanti- tatively by evaporation and the addition of barium chloride to the liquor. Klason there- fore assumes that the lignin complex has three ethylene bounds,two of which bring about the intimate addition of two SO2 molecules forming lignin sulphonic acid, the third group binding SO 2 more loosely. The fourth SO2 molecule is attached to an active carbonyl (aldehyde or ketone group) so loosely that the sulphurous acid can be sep- arated from it at ordinary temperature. The formula for lignin which Klason has proposed is meant to represent a summary of facts concerning the reactions of the lignin compound, and must be confirmed by future exact analytical investigations. It has, however, as Schwalbe remarks, "an advantage which should not be under- valued, namely that Klason's speculations give a splendid working hypothesis for the sulphite cooking process, for which it is really intended." Wichelhaus has given the following table of the quantitative composition of a waste sulphite liquor: Dry residue. . . . a) organic . . b) inorganic. SO2 combined . . . SO2 free ...... Cl .......... SiO 2 ......... Fe 2 O 3 and A1->O 3 . CaO ......... MgO ........ Alkalies ...... Specific gravity . . Reaction ...... 82*8350 grammes in one litre 68-3440 14-4910 3-43<40 5-8420 2'5600 0*0240 0-0024 0-0102 7*1760 0*0040 0-0192 1-0390 Acid Concerning the nature of the organic substances Klason has given the following summary of the waste products calculated on one metric ton of pulp : Liquor I. Liquor II. Liquor I. Liquor II. Lignin Kilo- grammes. 644 311 15 5 73 235 102 Kilo- grammes. 600 325 15 30 200 00 Pounds per Short Ton. 1,287 622 31 146 470 . 204 Pounds per Short Ton. 1,200 650 30 60 400 280 Carbohydrates Proteins Rosin and fat Sulphurous acid combined with the lignin Lime . ... . . 1,380 l,2f,0 2,760 2,520 Frank, A. THE CHEMICAL PROCESS IN 'SULPHITE COOKING. The sugar value of the waste liquor, the difficulties in fermentation, and the unpleasant odour of the sulphite spirit are discussed. Papier-Ztg. vol. 14 (1889) p. 1556. Earth, K SULPHITE LIQUOR. The author found that the separation of CaSOs takes place at the moment when the liquor has the composition CaH (SO 3 )2. The oxidation of H 2 SOs to H 2 S04 or CaSOs to CaSO 4 does not take place without the presence of wood or increased pressure. Papier-Zig. vol. 15 (1890) p. 667. COMPOSITION OF WASTE SULPHITE LIQUOR 17 Suddens, W. ORGANIC ACIDS OF SULPHITE LIQUOR. Gives proof of existence of succinic and protocatechuic acid in sulphite liquor. The digallic acid (tannin) originally present is probably changed by the SO? into diprotocatechuic acid, which has tanning properties. Papier-Ztg. vol. 16 (1891) p. 1*813. Harpf, A. CHEMISTRY OF SULPHITE PROCESS. During the cooking process the H2SOs is oxidized to H2SO4 but forms a water- soluble calcium salt of a sulphur containing organic acid. Dingler's polytech J. (1892). Hofmann. Handbuch der Papierfabrikation 2nd edition (1897), pp. 1546, 1623. Papier-Ztg. vol. 16 (1891) pp. 1726, 1844, 1908, 1964, 2155, and vol. 17 (1892) pp. 1069, 1121. Weld, F. W., Lindsey, J. B., Schnelle, W., and Tollens, B. ON THE SO-CALLED "SULPHITE-LYE" AND ON THE ROTATION OF GLUCONIC, GALACTONIC, AND RHAMNONIC ACIDS. Mannose and galactose are found in the liquor, which yields furfural on dis- tillation with HC1, proving that pentaglucoses or pentoses are also present. The presence of saccharic acid could not be proved, but vanillin was found by means of the phloroglucinol reaction. A table shows that the acids obtained by oxidation from glucoses possess a remarkable kind of bi-rotation. Ber. vol. 23 (1890) p. 2990. J. Soc. Chem. Ind. vol. 10 (1891) p. 156. ' , . Lindsey, J. B. and Tollens, B. SULPHITE LIQUOR AND LIGNIN. The soluble by-products of the bisulphite process of pulping wood are derivatives of its lignin or lignone constituents, and the authors have investigated these waste liquors with the view of elucidating the constituents of the latter. The results of a general examination for carbohydrate constituents showed (1) the absence of dextrose or bodies yielding dextrose, (2) the presence of galactose, mannose, pentaglucose or derivatives of these. A series of observations of yeast fermentations of the liquor, after expelling sulphurous acid by evaporation with sulphuric acid, showed the formation of 5-6 c.c. alcohol from 1 litre of the wood liquor, (containing 95 grammes total solids). After hydrolysis b,y boiling with acid, the quantity of alcohol formed amounted to 6.75 c.c. It is obvious that these by-products are for the most part insusceptible of alcoholic fermentation. The greater proportion of the constituents of these sulphite liquors are pre- cipitated by lead acetate. This precipitate decomposed by sulphuric acid gave a solu- tion from which alcohol threw down a flocculent substance having the empirical com- position C26HsoSOi2; the filtrate from this on evaporation yielded a gummy body, analysis of which also gave numbers expressed by the formula C2cH3oSOi2. The addition of hydrochloric acid to the original liquor precipitated a body C2cH3oSOio; and bromine threw down a brominated derivative C^6H2sBr4SOn. These products boiled with hydriodic acid for the determination of OCHa gave numbers proving the presence of 2 CHa groups in the above empirical formulae. The S is present as SOsH. For the original constituents of the pine wood, of which these bodies are sudphonated derivatives, the authors arrive, after discussion, at the formula C24H24(CHa)2Oio and point out its substantial identity with that assigned by Dietrich and Konig (Landw. Vers. Stat. vol. 13, p. 222) to the lignin of woody tissue, as with that taken by Cross and Bevan for the lignone constituent of jute (Chem. Soc. J. vol. 55, p. 213). Ann. vol. 267 (1892) p. 341. . Ber. (1893) p. 322. J. Soc. Chem. Ind. vol. 11 (1892) p. 835. 491202 18 FORESTRY BRANCH BULLETIN No. 66 lindsey, J. B. and Tollens, B. SULPHITE LIQUOR AND LIGNIN. " The liquor experimented with was prepared by the Ritter-Kellner process. It was yellow and almost clear, and when fresh smelt slightly of sulphurous acid, the quantity of which was increased by heating with dilute sulphuric acid. It had a specific gravity of 1.055, decolorized iodine solution, and strongly reduced Fehling's solution on warming a result not to be ascribed to the sulphurous acid present as this has no such action in alkaline solution. Phenyl-hydrazine acetate gave a fairly copious yellow turbidity which became darker on standing and finally separated as a dark, tarry mass. A precipitate of barium sulphate was produced on adding barium chloride to the wood-pulp solution after the addition of hydrochloric acid ; lead acetate gave a dense yellow precipitate, leaving the filtrate clear and colourless. A solution of gelatin gave a grey precipitate which cohered in clots on stirring. "Seeing that, according to Wehmer and Tollens, the formation of levulinic acid on heating organic substances with hydrochloric acid is a certain indication of the presence of hexacarbohydrates, the fact that only a small quantity of the silver salt could be obtained from sulphite liquor goes to show that lignin does not fall into this class of bodies. A trace, at most, of dextrose was found by the saccharic acid reaction of Gans and Tollens. The presence of a small quantity of galactose or galactan was recognized by the formation of mucic acid. Mannose was detected by the formation of its hydrazone which melted at 187 C. and was further identified by its ultimate analysis and behaviour on polarisation. The quantity obtained was 3-4 grammes of the hydrazone from 500 c.c. of the liquor, which was increased to 5 grammes when inversion had been previously performed. Pentoses were recognized by means of the furfural reaction, furfuramid melting at 114 0. being ultimately obtained. On evaporating liquor to a syrup, adding alcohol, and boiling, a considerable amount of gummy matter separated out. After this had been freed from residual gummy matter the final alcoholic extract had an odour of vanillin and gave the phloroglucin reaction for vanillin ; the presence of xylose was negatived by the spectroscopic examination of the alcoholic solution of the phloroglucin precipitate. It therefore appears certain that vanilla, or some closely analogous body, must be present in sulphite liquor, although it has not been isolated in the crystalline state. " An experiment was made to ascertain the capability of the liquor of fermenting. The sulphite was decomposed by a slight excess of sulphuric acid and fermentation effected by fresh yeast with the addition of a small amount of a nutritive material derived from the same yeast. From 1 litre of the liquid thus treated 0-0456 per cent of alcohol by volume was obtained. Therefore, out of a total amount of solid matter of 9-46 per cent not more than about 1-2 per cent consists of fermentable carbohydrates. "The cause of the yellow precipitate with lead acetate was investigated. A portion of the fluid from which sulphuric acid had been eliminated by means of baryta water was precipitated with lead acetate, and the precipitate analysed. It had a com- position of which the organic portion was expressed by the formula 26 Hso Oi2 or C26 Hs2 Ol2. " The crude lead precipitate was decomposed with sulphuric acid, and the excess of acid removed by digestion with a second portion of the precipitate, and the resulting solution, which gave no reaction with phloroglucin, was concentrated and diluted with alcohol. A grey flocculent precipitate, which, after purification by means of alcohol and ether and drying over sulphuric acid, gave results corresponding to the formula C26H 3 oSOi2 or C24H 24 (aH[3)2SOi2. The filtrate from this grey body yielded on evaporation to dryness a substance of the formula, C 24 H24 (CH 3 ) 2 SOi2 + li H 2 O which reduced Fehling's solution. A substance was also precipitated from the original sulphite liquor by hydrochloric acid, to which was assigned the formula C26H 30 SOio, and a brominated derivative was also obtained C 2 GH28Br 4 SOio. The authors deduce from these observations that the gummy material from which the above sulphur- COMPOSITION OF WASTE SULPHITE LIQUOR 19 containing bodies are formed has the composition C24H24(CH3)2Oi2, or C24H26 (CHs)2 Oi2,assuming that the sulphur is not in direct union with the oxygen. Should the contrary be true, and the sulphur be present as a sulphonic group, the above formula would be reduced by two or three atoms of oxygen. According to Mitscherlich, sul- phite liquor contains tannin, a supposition upheld by its behaviour with gelatin, hide powder, and lead acetate, but opposed to this is the absence of reaction with iron salts and the divergence in composition noted above. Nevertheless, if it be assumed that the sulphur is present as a sulphonic group, in the substance capable of precipitating gelatin a resemblance to the bodies prepared from sundry phenols by Schiff, which he termed, ' sulphurized tannins,' becomes apparent, as they also fail to give the iron reaction." Thesis. 'Gottingen (1891). Z. angew. Chem. vol. 5 (1892) p. 164. J. Soc. Chem. Ind. vol. 12 (1893) p. 287. Ahrens, F. B. SULPHITE LIQUOR OF CELLULOSE PULP MILLS. The author, in conjunction with E. Klingenstein, had occasion to examine waste liquor at the Agricultural Technological Institute of the University of Breslau, the following being the results: Sulphite waste liquor is a reddish-brown, cloudy liquor, with strong acid reaction, a peculiar smell, a specific gravity of 1-0465 (6-5 Be.) at 15-8 C. When evaporated a tough, sticky, gummy substance remains ("solid matter") amounting to 9-4 per cent, of which 1-11 per cent is ash and 8-29 per cent organic matter. A slight error occurs in all the results herein recorded, which the authors point out. It is due to the fact that the " ash " consists of sulphate and sulphite of lime, which in calcining is partly reduced to calcium sulphide and thence to sul- phuretted hydrogen, which burns off as SO2. This slight loss was thus credited as " organic matter." PURIFYING THE LIQUOR WITH LIME The liquor as it leaves the boilers is strongly acid, containing a considerable quan- tity of recoverable sulphurous acid which may be obtained as sulphite of lime by the addition of sufficient lime to nearly neutralize the solution. To complete the neutraliz- ation the liquor may be run over limestone. A precipitate obtained by the addition of lime contains a certain quantity of organic matter, varying according to the temper- ature and the amount of lime added. I. RESULTS OF EXPERIMENTS The hot liquor was treated with a measured quantity of fresh milk of lime, boiled and filtered, the filtrate being then neutralized by carbonic acid. Number. CaO. Solid Matter. Ash. Organic Sub. 1 . % 2 , % 8'75 % rso % 6 '95 2 3 7'48 1-59 5'89 3 4 7 '36 1 71 5 65 5 6 8'86 1*52 5'34 7 8 6'65 1'54 5'11 9. 10 6'79 T51 5'28 x 11 12 6-52 1'49 5 03 x 12... 15 6'31 1'49 4 82 13 20 7 '00 1"60 5-40 14 30 4 99 roi 3'98 By a further addition of lime the organic matter precipitated increases, and by longer boiling with lime the organic compounds are again brought into solution, which fact explains the results marked X in the above table. 4912O 2 20 FORESTRY BRANCH BULLETIN No. II. RESULTS OF EXPERIMENTS Measured quantities of fresh milk of lime were added to the liquor when cold, the precipitate filtered off, and the filtrate neutralized with CO 2 and examined, the results being : Number. CaO Solid Matter. Ash. Organic Sub. 1 ... % 2 % 6-21 % I'll % 5-10 2 3 6-19 1-33 4 96 3 4 5'26 i-oo 4-26 4 6 5'08 1-04 4-04 5 8 4 96 1-10 3'86 6 10 5 67 ' 1-22 4 45 7 12 5'76 1-23 4-53 8 14 6-26 1-29 4-97 It is seen that the minimum of organic substance is left in the liquor (3-86 per cent) by treating with 8 per cent of lime, a regular increase taking place with an increase in the lime used. Upon adding the lime the liquor turns from yellow to red and brown. Treatment of the liquor with alumina. A number of tests were made to ascertain the quantity of organic matter that could be mechanically carried down, by means of gelatinous alumina prepared by decomposing aluminate of soda with CO 2 . The liquor was treated with known quantities of aluminate of soda and then saturated with CO 2 at the ordinary temperature. Results: Number. A1 2 3 . Solid Matter. Ash. Organic *-ub. 1 % 1 % 9'58 % 2 06 % 7'53 2 2 9 22 2'18 7-04 3 4 9'38 8 '53 2-11 2 13 7-27 6 40 4 5 82 3 10 5'10 5 6 10*84 3 96 6' 88 DRY DISTILLATION OF THE RESIDUE As already pointed out the residue obtained by simply evaporating the liquor to dryness is a dark, gummy, tough substance, whereas the residue obtained after treat- ment with lime is a firm, friable material. The ash and total sulphur contained in this were estimated. Ten litres of liquor were boiled with 138 grammes of CaO and filtered; the residue amounted to 835 grammes and gave by analysis the following: 22.37 per cent of- ash and 6.45 per cent of total sulphur; of the ash, 14.4 per cent consisted of sulphur of which 13-4 per cent existed as SO 3 and 58-5 per cent as CaO. By the dry distillation of this residue a considerable quantity of gas was evolved, mostly H 2 S, the formation of which is probably due to the reduction of the sulphites and sulphates by the organic matter. The distillate is a liquid of penetrating odour from which sulphur separated on standing, and the residue consists of a black pitch. The distillate was acid and contained acetic acid, acetone, mercaptan, and an oil containing sulphur with an unpleasant smell. The two latter are produced by the secondary reaction between the H 2 S and the methyl alcohol, and a smaller number of nitroge- COMPOSITION OF WASTE SULPHITE LIQUOR 21 neous bases. The pitch contained 33-6 per cent of ash and 4-37 per cent of total sul- phur; the ash contained 71-6 per cent of CaO and 13-7 per cent S, of which 12-5 per cent existed as SO 3 . Similar results were obtained by the dry distillation of the lime precipitate. BY OSMOSIS The following diffusion tests were conducted in the ordinary way. In the cell there were 10 litres of liquor and 10 litres of water. At first a test was taken every hour, but this was found to be unnecessary. The surrounding water increased in colour and became somewhat acid, and had no action on polarised light. P. Schubert obtained the following results:: Days. Solid Matter. Ash. Organic Matter. 1 % 1'95 % 33 % 1-62 2 2'46 0'49 1-97 3 . .. . 2-98 0'52 2'46 5 3'95 0'63 3 32 7 . . .. 4-10 0-67 3-43 10 4'44 0'71 3'7l The diffused liquor after 10 days had a specific gravity of 1.020. ELECTROLYTIC EXPERIMENTS In one of these experiments a liquor was employed that had been treated with lime and neutralized with CO 2 , lead plates being the electrodes. After about two hours action of a current from three large Bunsen elements, a slimy precipitate separated, the liquor turning a light yellow colour, and the lead was dissolved to considerable quantities. A quantitative test gave the later mentioned results. By electrolysis a liquor was obtained which was treated cold with 3 per cent of lime and by neutralizing with CO, became somewhat heated. It was of a dark red or brown colour and con- tained 6.9 per cent of dry substances, 1.33 per cent of ash, and 4.86 per cent of organic matter. The lead plates had 159 cm. of acting surface and were separated 0.3 cm. from each other. The current was 5 amperes. The length of time during which the current passed was 110 minutes. After separating the lead by sulphuretted hydrogen, and calculating upon the original volume, there were found 4.42 per cent dry subs- tance, 1.07 per cent ash, and 3.35 per cent organic matter. The experiment showed without a doubt a great diminution of organic substance. Another trial was made with a platinum electrode, the size of the plates, the strength of current, etc., being as be- fore. The liquor employed, which had been treated with 5 per cent of lime whilst hot, was neutralized with CO 2 and contained 7.13 per cent of dry substance, of which 1.56 per cent was ash and 5 . 57 organic compounds. The experiment lasted two hours. Only a small precipitate was produced but the liquor became nearly black. By analysis 6.3 per cent of dry substance was obtained, of which 1.5 per cent consisted of ash and x 4.85 per cent of organic matter. The above experiments clearly indicate that with lead electrodes the purifying effect is partly due to the lead; the electric current also has the effect of reducing the organic matter. It appeared desirable to ascertain the effect of a stronger and a higher tension current. By means of a dynamo a current /was employed of 70 volts and 10 amperes, and of 106 volts and 19 amperes. As elec- trodes, lead and zinc plates were used. The liquor employed was treated with 3 per cent of lime whilst cold, was filtered and neutralized with CO 2 , and showed by analysis 4-96 per cent organic substance. The precipitate formed was very small and the liquor became strongly heated. The analysis in the one case showed 6-5 per cent of dry substance, 0-23 lead, 1-27 ash, and 5-0 organic compound, and in the other 6:-51 22 FORESTRY BRANCH BULLETIN No. 66 of dry substance, 0-15 zinc, 1-48 ash, and 4-98 organic compound. No further effects were produced by the use of currents of higher tension. It is a well known fact that in the manufacturing of sulphite wood-pulp a boiling operation occasionally requires a much longer time than usual, and the reason being unknown a number of experiments were conducted as follows: the liquor was treated with 3 per cent of lime, and the precipitate was pressed and stirred in water. Into the solution S0 2 was then passed until it smelt strongly of the latter. For several hours it was heated from 125 to 130. In every case considerable quantities of sulphuric acid compounds were obtained, the quantities varying according to the degree of saturation with SO 2 and the heating. From 100 grammes of dry precipitate the minimum increase of H2SO4 was 2.6 gram- mes and the maximum 5 . 9 grammes. Z. angew. Chem. vol. 8 (1895) p. 41. J. iSoc. Chem. Ind. vol. 14 (1895) p. 603. Ulzer, F. and Seidel, H. SULPHITE CELLULOSE WASTE LIQUOK. Of the dry residue 5.97 per cent and of the liquor 0.807 per cent are sulphur. The part in the form of organic compounds amounts to 0.60 per cent. The high content of carbohydrate-like substances which can be salted out is very striking. The different proposals for use of liquor are considered. Graf Andrassay's proposal for evaporation of liquor in open pans, by furnace gases on counter current principle. Coal briquetting. Mitt. Techn. Gew. Mus. vol 6 (1896) p. 186. Knoesel, Th. WASTE SULPHITE LIQUORS. Papier-Ztg. vol. 23 (1898) part I p. 1503. Hofmann, C PRATCT. HANDBUCH DER PAPIERFABRIKATIOK Berlin 1875, 2nd Edition vol 1 (1891) vol. 2 (1897) p. 1575-1628. Harpf, A. UTILIZATION OF WASTE SULPHITE LIQUOR. Report on papers read before the Third International Congress for Applied Chemistry in Vienna, 1898. Z. angew. Chem. vol. 11 (1898) pp. 876, 925, 1169. Seidel, H WASTE LIQUORS FROM "SULPHITE" WOOD PROCESS. The liquor investigated 'by the author was obtained from a Silesian mill working the Ritter-Kellner process. The following analytical results may be noted: specific -gravity 1-050; total solid residue (dry at 100) 12.013 grammes per 100 c.c., i.e.' 11.44 per cent, containing 9.54 per cent total sulphur. The data concerning sulphur are as follows, calculated in this case as per. cent of the liquor : Sulphur in dry residue, per cent of liquor 1*0910 Sulphur as free SO 2 0'0320 Sulphur as SO 3 0'0074 of the total sulphur of the liquor, 93 per cent exists in the form of "organic" com- pounds. In reference to the claim of the value of these liquors as fertilizers, by reason of their potassium salt contents, a determination of potash was made and found to amount to 1 gramme of K2O per 52 litres. A study of the precipitates obtained by various processes of "salting-out" e.g. Ekman's series of so-called "Dextron" products (German Patent 81,553), confirms the author's previous conclusion that this method of fractionation of the organic con- stituents of the liquor fails to bring out any constitutional differences. A similar conclusion results from a study of the fractions obtained by precipitation with alcohol. The analysis of a carefully purified fraction gave the following numbers : C, 56.27 per COMPOSITION OF WASTE SULPHITE LIQUOR 23 cent; H, 5.87 per cent; S, 5.52 per cent in closest agreement with numbers obtained by Lindsey and Tollens, and corresponding with the empirical formula C26H3oSOi2. It is noted also that the results of these chemists were obtained with a liquor from a mill working under the different conditions of the Mitscherlich process. Respecting the theory of the reactions taking place in the digesters, the author advances no new hypotheses, but generally confirms those summarized in "Cellulose" (Cross and Bevan), pp. 177 to 201. Mitt. Techn. Gew. Mus. vol. 7 (1897) p. 119. J. Soc. Chem. Ind. vol. 17 (1898) p. 178. Seidel, H. and Hanak, L. WASTE SULPHITE LIQUOR. In previous articles the authors have shown that an organic substance containing sulphur can be obtained from waste sulphite liquor in different ways, and the products were proved to be similar by the corresponding amount of sulphur contained therein. Since then, different boilings from the same Silesian cellulose-mills have been analysed and the former statements corroborated. The products obtained reduce Fehling's solution, are soluble in water, are inso- luble in absolute alcohol, and in the concentrated solution of common salt give a pro- cipitate with phenyl-hydrazine, give the reaction with a-naphthol and H2SO4, give t]o.e same shades of colour with FeCls and almost the same percentage of mineral ash, and sulphur. They also give precipitates with barium chloride and lead acetate, soluble with difficulty, but cannot be completely precipitated by the latter reagents. The percentage of sulphur was slightly lower than in the products first analysed, being about 8 per cent, but it always corresponded within narrow limits in the pro- ducts of the same liquor, again showing the identity of the organic products and also proving that the amount of organically-combined sulphur depends upon the manner of conducting the boiling process. To obtain the principal constituents of the organic matter as pure as possible a dilute solution of waste liquor was acidified with HC1 and boiled, and to this barium chloride was added in the quantity calculated to completely precipitate the sulphuric acid present. The filtrate showed no turbidity with either barium chloride or sulphuric acid, and as the barium salt of the organic substance is soluble in water this filtrate therefore contained it in solution. After evaporating part of the latter, alcohol was added and a precipitate obtained which the authors termed " Gum free from sulphuric acid." This precipitate yields 13-32 per cent of ash, which calculated as calcium sul- phates, gives the percentage of CaO as 5-64. With oxalic acid the CaO was calculated as 5-66 per cent. The amount of sulphur contained was 8-44 per cent. The isub- stances show all the before-mentioned reactions. The authors then endeavoured to substitute for the calcium in the organic salt other metals, but whilst they succeeded in this substitution in the case of barium they only obtained partial success with zinc, the experiments being carried out as follows : Fifteen grammes of gum free from sulphuric acid were dissolved in 150 c.c. of water and digested with 9 grammes of crystallized barium chloride. Alcohol was then added, giving a brown precipitate which was decanted with alcohol and carefully dried. This was then incinerated and the ash treated with sulphuric acid. The barium was then estimated by precipitation and also according to Carius's method to eliminate the error caused by small quantities of soluble sulphates, the average of the analyses show- ing 14-49 per cent of BaO. The sulphur contained was 7-77 per cent. The substance contained no chlorine. Zinc salt was obtained by dissolving 5 grammes of the gum in 100 c.c. of water and adding 2 grammes of zinc chloride. The ash from the precipitate with alcohol gave 6-95 per cent of ZnO and 7-86 per cent of S. On comparing the three results the metals were found to be combined in almost molecular proportion. This leads to the conclusion that the precipitate obtained is the salt of a definite organic acid which is the principal constituent of the organic matter in the waste liquor, and which is produced by the action of the bisulphites upon the 24 FORESTRY BRANCH BULLETIN No. 66 non-cellulose constituents of the wood. This supposition is further supported by the percentage of sulphur in the different precipitates, which when calculated in proportion to the molecular weight of the salt gives for the Ba salts 9-04 per cent; for the Ca salt 8-94 per cent; and for the Zn salt 8-44 per cent of sulphur, the average being 8-80 per cent. Ten grammes of the organic barium salt were mixed with the calculated amount of sulphuric acid and the mixture was dissolved in excess of water. A small amount of BaSO4 which was formed was filtered off. The mixture was allowed to stand for some days at a temperature of about 40 C., a white precipitate of BaSO4 being gradually formed which was filtered off. This treatment was continued for about three weeks until no further precipitate was produced. No trace of either barium or sulphuric acid could then be detected in the liquid by the ordinary analytical methods. The solution was evaporated to a syrup, and alcohol added. No precipitate was obtained, showing that the pure organic acid was soluble in alcohol. A brown, flaky precipitate was obtained from this aqueous alcoholic solution by ether, and this was carefully dried. The amount obtained was about 3 grammes. The substance thus purified is a brown, glossy, hydroscopic powder. It has an acid reaction, reduces Fehling's solution, yields with phenyl-hydrazine a yellowish- white precipitate, and gives precipitates with barium chloride and lead acetate which are soluble with difficulty. The ash, estimated as BaO, amounts to 1-26 per cent. The percentage of sulphur was 8-80 which corresponds with the amount obtained from the Ca, Ba, and Zn salts. The average elementary composition, therefore, of the ash-free organic substance containing sulphur is (1) From Silesian waste liquors (2) From Austrian waste liquors C 53'29 per cent C 56*27 per cent H 5'23 " H 5-87 S 8*8'0 " S 5-52 O 32'29 " O 32-24 consequently much more sulphur and less hydrogen and carbon are contained in the Silesian than in the Austrian waste liquor. When allowed to stand for some months in the open air the sulphite liquor deposits CaSO4 and turns lighter in colour. The dried substance obtained contains only 6-72 per cent of sulphur and the liquor itself contains 0-067 per cent of sulphur as sulphate. Oxidation of the organic matter has therefore taken place. In the reduced solution left exposed in the open air a light yellow gum-like precipitate was thrown down with alcohol, containing 7-01 per cent of sulphur. On distilling with steam a milky liquid was obtained showing the same properties as the gas ; it contains furfural. The quantities, however, show no definite proportion to the amount of waste liquor ued. Nitric acid ;acts energetically on the organic substance obtained from waste sulphite liquor. A considerable number of acids could be obtained, one of which was identified as oxalic acid. The halogens have also an energetic action on waste liquor. With chlorine the liquor becomes blood-red, and yellow precipitate is produced which decomposes on heating, giving off HOI. It can be dried in a vacuum, is insoluble in water and alcohol, reduces Fehling's solution, and gives a brown precipitate with phenyl- hydrazine. On oxidizing with fuming nitric acid, chlorine and sulphur can be recog- nized. A remarkable occurrence in the sulphite-cellulose manufacture is a deposit of sulphur in the wooden pipes through which the waste liquor is discharged from the digesters. In these pipes a greyish-white crystalline substance is deposited which has the following composition: water, 6.28 per cent; CaSO4, 87.41; FeO and AkOs-O.lS; silica 0.28 ; sulphur 5.75 ; total 99.85 per cent. The appearance of this su'lphur shows that the SO2 in the digester is not only oxidized but that some of it is reduced as well. , Mitt. Tech. Gew. Mus. (Vienna), vol. 7 (1807) p. 283. J. Soc. Chem. Ind. vol. 17 (1896) p. 596. COMPOSITION OF WASTE SULPHITE (LiquoR 25 Seidel, H. and Hanak, L.-WASTE SULPHITE LIQUOK. In continuation of their previous work (see previous abstract) the authors now find that free furfural is a not inconsiderable constituent of the sulphite liquor, its presence being identified by extracting with ether, adding aniline, and, after evaporat- ing the ether, adding hydrochloric acid, when the furfural reaction is distinctly obtained. Hence the previous statements require modification, since the whole of the furfural present does not originate from pentoses or pentosans. The presence of these substances is, however, proved by the phloroglucin reaction and by the fact that after distillation with hydrochloric acid the following substances gave furfural: thick liquor (sulphite liquor evaporated to 28 Be), the solid precipitated by salt or by alcohol, the dry residue from the thick liquor, and finally the dry residue of the filtrate after precipitating with alcohoL In order to remove sulphur from the organic substance contained in the liquor, the latter was treated with bleaching powder on the water-bath, filtered from gypsum, barium chloride added to the filtrate, the barium sulphate filtered off, and the solution evaporated. The product obtained is exceedingly hygroscopic, is free from sulphur, and reduced Fehling's solution strongly. The quantity of oxidizing agent necessary for this operation is too large to allow the method to be employed for rendering the sulphite liquor innocuous. Experimental evidence showed that chemical recovery of the sulphur is a simple matter, but the advantage could only be taken of this tech- nically when it is possible to utilize the organic substance of the sulphite liquor for heating purposes. With regard to the reducing action of the sulphite liquor, this is not due to the sulphurous acid but to the organic substance containing sulphur. Sulphite liquor reduces completely Methylene Blue, Indophenol, and Indigo, and gives with 1.1 dinitnonapthalene a lilac, and with 1.4 derivative a brown dyestuff. A further use for sulphite liquor consists in employing the organic sulphur compound as a substitute for cream of tartar on alumina and chrome mordants of wool. Mitt. Tech. >Gew. Mus. (Vienna) vol. 8 (1898) (11 and 12) p. 337-347. J. 'Soc. Chem. Ind. vol. 17 (1898) p. 863. Seidel, H. WASTE SULPHITE LIQUOE. * l In my last communication it was shown that the lignin substance of wood con- sisted of 64 per cent carbon, 6 per cent hydrogen, and 30 per cent oxygen. " The data obtained by calculation from the different analyses of lignosulphonic acids showed differing values of the sulphur content, so that the composition of lignin was obtained by subtracting the amount of SO2. The fact is emphasized that the above mentioned composition of lignin is that of the lignin which can be regenerated from the liquor. This lignin must differ from the original lignin of the wood by a greater content of hydroxyl groups. I assume that in the action of sulphurous acid on wood the following reaction takes place: X. CH: CH.-Y + SOs H 2 = X. CH.2 . CKSOs H: Y. By heating at higher pressure the following decompositions occur : X, CH 2 . CH.SOaH. Y=X. CH 2 . CHOH. Y + SO 2 . This decomposition is the reason why the waste liquor cannot be heated at higher pressures. The half of the organically-bound sulphur can be readily obtained as SO 2 ; alkaline heating at higher pressure is out of the question on account of the separation of CaSOs. Calcium bisulphite waste liquor can be evaporated under reduced pressure or at atmospheric pressure at 100-115 without decomposition of the lignin sulphonates. "The regeneration of lignin from very dilute solutions of lignin sulphonic acid takes place very slowly and in small quantities at ordinary temperatures. If sulphite liquor is made weakly alkaline and allowed to stand several days a reversion of the reaction is observed." 26 FORESTRY BRAXCH BULLETIN No. 66 The author's views on composition of lignin have received support from Klason (Kirchner, "Das Papier"). According to Klason, the chief substance of sulphite liquor, calcium ligniii-sulphonate, has the composition CisH^OsSCa^. This corresponds to the percentage composition C. 54.5; H. 5.55; O. 32.32, for lignin sulphonic acid. These numbers also correspond with the numbers obtained by Lindsey and Tollens and by Seidel and Hanak. They give on subtracting for S02 the following as the composition of lignin: C. 65.06; H. 6.00; O. 28.91. These differ considerably from Street's figures, viz: C. 64.54; H. 6.41; O. 29.06. Z. angew. Chem. vol. 13 (1900) p. 1307. Papier-Ztg. vol. 25 (1900) part II pp. 3295, 3371. J. Soc. Chem. Ind. vol. 19 (1900) p. 1033. Ahrens, F. B. DISTILLATION EXPERIMENT WITH SULPHITE LIQUOR. The liquor after the addition of infusorial earth was evaporated to dryness and then the residue, dried completely in air, was subjected to dry distillation. From 100 grammes there were produced 16-17 litres of gas (CO2 heavy carbons, O, H, CHi), and 50 grammes coke which contained 36 grammes infusorial earth. The heating value of the gas varied greatly, between 2,450 and 3,550 cals. The liquid distillate contained, besides a great deal of water, very small quantities of methyl alcohol and acetone, very small quantities of liquid hydrocarbons, and larger quantities of mercaptans. Chem. Zeitschrift vol. 2 (1903) p. 743. Chem. Zentr. (1903) part II p. 812. SULPHITE PULP IN AMERICA: Methods of manufacturing sulphite pulp at Ausable Forks, N.Y., on Lake Cham- plain. Samples of waste liquor taken from digesters at end of the digestion process were found to contain 10-5 per cent solid material. About 90 per cent of this residue con- sists of organic and volatile matters, while about 5-7 per cent consists of calcium sulphate. When discharged into rivers the liquor is acid and contains 0-42 per cent calcium sulphate, the remainder being largely lignin and other organic extractions. It also contains finely divided wood-pulp. Pulp Paper Mag. Can. vol. 4 (1006) p. 294. Krause, H. CHEMISTRY OF WASTE SULPHITE LIQUOR. Sugar content. Chem. Ind. vol. 29 (1906) p. 217. Papier-Ztg. vol. 32 part I (1907) p. 1100. J. Soc. Chem. Ind. vol. 25 (1906) p. 493. Schwalbe. Lecture on Alcohol from Waste Liquor (Schwalbe 1910). Krause, H. CHEMISTRY OF SULPHITE LIQUOR. The principal organic constituent of the waste lyes is the calcium salt of lignin- sulphonic acid, but corresponding to higher temperature of digestion the Ritter- Kellner liquor has a darker colour and contains more furfural and generally more sugars than the Mitscherlich liquor. Fehling's solution is not suitable for the detec- tion of sugars in the liquors, since the lignin derivatives exert a reducing reaction even in the cold. Nylander's bismuth solution, however, is not reduced by the lignin bodies and can be employed for the detection of the sugars. The separation of the sugars is best effected by evaporating the liquor in the presence of barium carbonate to a pasty consistency, mixing the product with sand, and extracting the sugar by exhaustion three to six times with hot 90 per cent alcohol. The author's observation COMPOSITION OF WASTE SULPHITE LIQUOR 27 showed that in both processes of digestion the liquors from wood boiled in the autumn contained about twice as much sugar as those obtained in the spring. The waste liquors contain free furfural, pentosans, and pentoses; the lignin constituents of the liquors yield no furfural on distillation with hydrochloric acid. In addition to the pentosans and pentoses the liquors contain hexosans and hexoses. Amongst the sugars present the author has identified xylose, mannose, galactose, levulose, and traces of dextrose. The following table shows the results of analyses made of the two liquors obtained in the autumn by the two processes : Mitscherlich. Ritter-Kellner. .Furfural % 01 % 02 Pentosans 0'40 0-09 Hexosaus . ... 0'21 0'49 Total .sugars 1'48 1 47 Pentoses 0'47 0'41 Mannosp . 0'48 0'48 Levulose 0'28 25 Galactose O'Oi O'OI Lfextrose trace The author has also investigated to a certain extent the lignin derivatives of the liquor. On the addition of bleaching powder to the liquor, acidified with hydrochloric acid, a chloro-derivative was obtained which, after purification by alcohol and ether, showed a composition corresponding with the formula, C26H2oCl SOs2. This and other derivatives of lignin-sulphonic acid have the peculiarity of being soluble in alcohol only when acidified, whereas the presence of acid decreases their solubility in water. The author found that on boiling the liquors with dilute caustic potash the greater portion of the combined sulphur was split off without apparently any profound decom- position. Chem. Ind. vol. 29 (1906) p. 217. J. Soc. Chem. Ind. vol. 5 (1906) p. 493. Frank, A. COMPOSITION AND QUALITIES OF WASTE LIQUORS. Kirchner, Das Papier vol. 2 (1907) p. 134. DETERMINATION OF FREE AND COMBINED SULPHUROUS ACID IN WASTE LIQUORS. Wochbl. Papierfabr. vol. 38 (1907) p. 3199. Carlson, T. THE POLLUTION OF THE MONDAL RIVER (SWEDEN) BY WASTE SULPHITE LIQUOR. Amount and composition of the waste liquor. Based on 4-5 metric tons (4-96 short tons) cellulose, 1,050 kg. (2,310 Ib.) inorganic and 4,405 kg. (9,700 Ib.) organic substances. Papier-Fabr. vol. 7 (1909) p. 587. Papier-Ztg. vol. 35 (1910) part II p. 2117. Kerp, W. and Wohler, P. SULPHITE LIQUOR AND FURFURAL .SULPHUR- OUS ACID. The sulphur present in sulphite-cellulose waste lyes in the form of sulphurous acid (free and combined) amounts to one-fifth to one-third of the total sulphur. The proportion of sulphurous acid in the lyes which can be directly titrated with iodine increases with the dilution of the lye, and on continued titration with iodine the reac- 28 FORESTRY BRANCH BULLETIN No. 66 tion proceeds in stages ; these features are characteristic of the behaviour of sulphurous acid compounds of aldehyde. The combined sulphurous acid may therefore be con- sidered to be present in the form of sulphurous acid compounds of the aldehyde con- situents of the lye, viz. furfural, vanillin, xylose, mannose, galactose, and levulose. The lyes also contain a substance which, when the lyes are diluted, acts as an oxygen- carrier and exerts an oxidizing action on the sulphurous acid. The so-called calcium lignin-sulphonate must be regarded as a mixture of different substances. The reaction constant of the decomposition of sodium-furfural sulphite in aqueous solution is 0-72 x 10. In neutral solutions equilibrium is attained almost instantaneously, but less rapidly in acid solutions although the amount of decomposition is considerably greater in the latter case. Combination of sulphurous acid and furfural takes place only at the aldehyde grouping, not at the double linkage, furfural behaving in this, respect as a saturated aldehyde. Arbeit. Kais. iGesundh. vol. 32 (1909) p. 120. Chem. Zentr. (1909) part II p. 710. Papier-OFabr. vol. 7 (1909) pp. 46, 1135. Papier-Ztg. vol. 34 (1909) p. 3286 vol. 35 (1910) p. 1932. J. Soc. Chem. Ind. vol. 28 <1909) p. 1001. Chem. Abs. vol. 4 (1910) p. 443. Stutzer, A DETERMINATION OF SULPHUROUS ACID IN SULPHITE LYES. The standard method for the determination of sulphurous acid in foodstuffs is to distil with a current of carbon dioxide together with steam in presence of phosphoric acid, collecting the vapours in iodine and weighing the sulphuric acid produced as barium sulphate. In this way are determined not only the inorganic sulphites but also the sulphurous acid held in combination with aldehydes and sugars. The waste lyes of sulphite wood-pulp mills contain, in addition to these forms of sulphurous acid, combined sulphurous acid in the form of calcium lignosulphonate, and when such lyes are treated with phosphoric acid, in the manner described the results are variable according to the degree of decomposition undergone by the various organic derivatives of sulphurous acid present. The values obtained increase with the time of distillation and the concentration which the phosphoric acid thereby undergoes But in the analysis of waste sulphite pulp lyes it is for most purposes only of interest to determine the quantity of sulphurous acid which is readily split off under certain con- ceivable circumstances, whilst the more firmly fixed sulphurous acid may generally be considered as harmless. The author, therefore, proposes distillation with acetic acid instead of with phosphoric acid, the weaker acid readily decomposing the inorganic sulphites but only attacking the sulphurous in combination with aldehydes and lignin to a slight extent in a distillation of short duration. Two hundred and fifty c.c. of water are placed in an Erlenmeyer flask of 750 c.c capacity, the air expelled by carbon dioxide, and 25 c.c. of the waste sulphite lye are added with 25 c.c. of 25 per cent acetic acid. The liquid is kept in full ebullition for 15 minutes whilst the vapours are collected in iodine solution. This 'period of distillation is ample for the decomposition of sodium and calcium sulphites. Aldehyde sodium bisulphite is decomposed only to the extent of 4-8 per cent as against 22-8 per cent with phosphoric acid under 'similar conditions; calcium lignosulphonate is decomposed (using 50 c.c. of acetic acid) to the extent of 3-3 per cent. Chem.-Ztg. vol. 34 (1910) p. 1167. J. 'Soc. Chem. Ind. vol. 29 (1910) p. 1370. Wochbl. Papierfabr. vol. 41 (1910) p. 4148. Chem. Abs. vol. 5 (1911) p. 1335. COMPOSITION OF WASTE LIQUOR AND WASH- WATER FROM SULPHITE MILLS. Papier -Fabr. vol. 7 (1909) pp. 12, 136. 189. COMPOSITION OF WASTE SULPHITE LIQUOR 29 Klason, P. DISCUSSION ON KLASON'S PAPER ON "IRREGULAR PRO- GRESS OF SULPHITE COOKS". Papier-Ztg. vol. 35 (1910) pp. 375, 451, 731. Klason, P. CONTRIBUTION TO THE KNOWLEDGE OF THE CHEMICAL COMPOSITION OF SPRUCE. Investigations of the ligiiosulphonic acid contained in the waste liquor. Gebr. Borntrager Berlin IW. 35. Pamphlet 2 of the German Association of Pulp and Paper Chemists. Stutzer, A EXPERIMENTS ON WASTE SULPHITE LIQUOR. Concentrated waste liquor (wood extract), cell-pitch, molasses, and waste liquor gave, when 100 grammes and 500 grammes of solid substance respectively were present in 1000 c.c. the following viscosity numbers (water = 100) : 100 grammes 500 grammes in litre in litre Wood extract 120 402 Cell-pitch 120 516 Molasses 113 147 The unchanged liquor had the viscosity of 120. Molasses of 44-8 Be is less vis- cous than wood extract of 32-5 Be. The chemical analysis gave: Wood Cell-pitch Original Molasses extract Liquor 82*79 12*18 79*30 14*70 1-44 11-81 8*50 0*87 5*87 0-85 0-85 0*24 - l \; :V?.'- l! dry substance 10*26 7-14 ...*. 7*09 7*00 1-02 2*02 17*99 11-82 The lignin had a specific gravity of 1-056. One hundred c.c. contained dry sub- stance 12-87 grammes, ash 1-53 grammes, lime 0-92 grammes, sulphur 0-90 grammes, sulphurous acid 0-26 grammes. Papier-Ztg. vol. 35 '(1911) p. 5. Jahrb. Chem. Techn. -(1913) part II p. 501. Schwalbe, C, G. CHEMIE DER CELLULOSE. This work contains information with regard to the composition of the liquor. Berlin 1911 'Gebr. Borntrager. Honig, M. ACETIC AND FORMIC ACIDS IN SULPHITE LIQUOR. The waste liquors from the digestion of wood by the sulphite process contain acetic acid and formic acids, both in the free state and in combination with calcium; the proportion of free acid is always greater than that of the combined. In the waste liquors examined by the author the total quantity of acetic and formic acids found ranged from 2-151 to 9-078 grammes per litre. On the assumption that 1 cubic metre (35-3 cubic feet) of waste liquor corresponds to 100 kilogrammes (220 Ib.) of cellu- lose, the daily production of volatile organic acids in a wood-pulp mill may be calcu- lated. If 100 kilogrammes (220 Ib.) of cellulose are assumed to be derived from 300 kilogrammes (660 Ib.) of raw wood, the yield of volatile acids works out at from 0-72 to 3-03 per cent of the weight of the wood. The proportion of formic to acetic acid varies according to the circumstances; in two liquors it was 1:5-78 and 1:5-60, whilst in a third it was 1 :13-6. In the analysis of the liquors for the separation of the volatile Crude ash. . . . . . ..- 2*64 Lime 0*50 Total sulphur. . 4*80 Sulphurous acid. 0*15 Calculated on 100 grammes Lime 0*78 Total sulphur. . 7-51 Sulphurous acid. 0*23 Crude ash. . . . 4-13 30 FORESTRY BRANCH BULLETIN No. 66 acids, the vapours produced in the distillation, before they enter the condenser are passed through a flask containing a milk of calcium or barium carbonate maintained in gentle ebullition. In this way a complete separation of the organic acids from the volatile aldehydes is effected whilst most of the sulphurous acid is precipitated. The solution containing the salts of the organic acids is filtered, concentrated to 100 c.c., treated in the cold for 4 hours with a little hydrogen peroxide to oxidize the residue of sulphurous acid, and the excess of peroxide destroyed by manganese or lead per- oxide. The solution is divided into two parts, in one of which the total volatile acid is determined, and in the other the formic acid is determined, gravimetrically by mer- curic chloride and sodium acetate. If a solution of the neutral lead salts be evaporated and the residue extracted with alcohol the lead formate remains insoluble, whilst the soluble portion contains the acetate; no other volatile organic acids are present. J. Soc. Chem. Ind. vol. 31 (1912) p. 768. Chem.-Ztg. vol. 36 (1912) p. 889. Chem. Abs. vol. 6 (1912) p. 3517. Paper vol. 9 (1912) iNo. 1 p. 29. Zweiberg, G. von TESTING OF SULPHITE CELLULOSE LYES WITH IODINE. The titration of the sulphur dioxide in sulphite digestion liquors, by means of iodine, may lead to erroneous results unless certain precautions be taken. The prin- cipal sources of error are loss of sulphur dioxide by volatilization and the reversibility of the reaction; SO2+H 2 O-f 21=2HI-(-SO3. The latter- error is diminished by working at high dilutions. If iodine be added to a strong solution of sulphurous acid the reaction may also be complicated by the liberation of sulphur. Excessive stirring and exposure to air is to be avoided. The best method is to dilute the sulphite liquor to a concentration approximately equivalent to that of the iodine, and to run the sul- phite solution into the iodine so that an excess of the latter is present until the end. Eor the separate titration of the free and combined sulphurous acid, the acid produced by the reaction with iodine must be titrated subsequently with sodium hydroxide. For the combined titration, 2 c.c. of the sulphite liquor are diluted with 20 c.c. of water and run in a fine stream into 10 c.c. of N/8 iodine solution ; starch should be added only towards the end of the titration; when decoloration is complete 2 drops of phenolphthalein are added and the liquid is titrated with N/8 sodium hydroxide. For the titration of the sulphur dioxide at the end of the boiling process, 100 c.c. of lye are made alkaline with a solution of lime and sugar, then boiled and filtered; the preci- pitate is dissolved in hydrochloric acid, diluted to 250 c.c., and 25 c.c. are taken for titration with iodine. Alternatively 25 c.c. of lye may be distilled in an atmosphere of carbon dioxide with 25 c.c. of 25 per cent acetic acid and 250 c.c. of water, and the distillate collected in N/10 iodine. Svensk Pap. Tid. (1913) May 31. Papier-Fabr. vol. 11 i(1913) p. 1007. Paper vol. 12 (1913) No. 13 p. 16. J. Soc. Chem. Ind. vol. 32 (1913) p. 863. Chem. Abs. vol. 7 (1913) p. 3837. Pulp Paper Mag. Can. vol. 11 (1913) p. 52. Walker, W. 0. THE PROBLEM OF THE WASTE LIQUOR FROM SULPHITE MILLS. Composition of the digester liquor. As it comes from the digester it is a dark reddish-brown liquid of variable specific gravity, about 1.05. It has a peculiar, not unpleasant odour, due to bodies of a terpent nature. By evaporation of the liquor a syrup is obtained which, on further evaporation, changes to a glue-like mass. The dried residue is about 10 to 12 per cent of the weight of the original liquor. This residue on ignition gives about 12 per cent of ash, chiefly sulphates of calcium and magnesium. The other 88 per cent is organic material. The following substances have been shown to be present in the liquor: Chief constituent an organic sulphur compound, probably a calcium and magnesium sul- COMPOSITION OF WASTE SULPHITE LIQUOR 31 phonate; small quantities of sulphurous acid, pentoses and pentosans, a terpeiie-like substance and free sulphur ; very small quantities of sulphuric acid, mannose, dextrose, and galactose; free furfural and traces of vanillin or vanillin-like body. The chief constituent of this liquor may be precipitated by alcohol and is obtained thereby as a dark, gummy mass which becomes brittle by drying. It is also obtained by concentration and salting out by means of sodium chloride or magnesium sulphate. Purification is difficult as it is apparently only soluble in water and dilute alcohol from which it does not crystallize. It yields chlorine and bromine derivatives, contains active carbonyl and methyl groups, and is a strong reducing agent. Sulphur in the compound is shown by McRae to be present in the form of a sulphonic group. It is probably the soluble reaction product from the calcium and magnesium bisulphites on the complex groups in combination with the cellulose in the lignocelluloses. These groups are commonly called lignin or lignone and have the characteristics of di-ketones, particularly quinones. The lignone com- plex contains more carbon than cellulose. The lignone-bisulphite compounds have been separated in various derivative forms and analysed. The product precipitated by hydrochloric acid from the waste liquor has been given the empirical formula C24H24(CH3)oSOi2 and the formula C24H24(CH3)20io to the parent lignone complex, Our structural knowledge of the lignone group is very limited and has been gathered from complex decomposition reactions. These reactions show the presence of hydrocarbon nuclei of very small dimensions together with a high proportion of CO groups alternating in periods of short dimensions with the hydrocarbon groups. Furfural derivatives appear to be present, also CHs groups and a low proportion of OH groups. J. Soc. Chem. iEng. vol. 32 (1913) p. 389. Chem. Eng. vol. 17 (1913) p. 246. Schwalbe, C. G. and Grimm, H. ROSIN IN WASTE SULPHITE LIQUOR Less than 0-03 per cent rosin could be extracted by shaking with ether. Wochbl. Papierfabr. vol. 44 (1913) p. 3251. Chem. Abs. vol. 7 (1913) p. 3837. Honig, M. FORMIC ACID AND ACETIC IN WASTE SULPHITE LIQUORS. Author states that no organic acids other than formic and acetic acid are contained in the waste liquors. In 1 litre liquor 2-151 grammes up to 9-078 grammes of volatile organic acids were found. Chem.-Ztg. vol. 36 (1912) p. 889. Chem. Abs. vol. 6 (1912) p. 3517. Paper-Maker Brit. Trade J. (1915) p. 497. Kerp, W. and Wohler, P. TO THE KNOWLEDGE OF COMBINED SULPHUR- OUS ACID. Sulphite pulp and furfural sulphurous acid. A chemical and pharmacological investigation. Papier-Ztg. vol. 38 <1913) p. 3063. Arbeit. Kais. Gesundh. vol. 32 p. 120. 32 FORESTRY BRA*-CH BULLETIN No. 66 Banthier, G DECOMPOSITION OF CELLULOSE, STARCH, SUGAR, AND SULPHITE BY HEAT. The behaviour on dry distillation of cellulose, starch, and sugar substances, having the same percentage composition, was compared by heating under the same conditions in an iron retort 44 cm. long and 6.5 cm. in diameter, arranged in an electrically heated oven. A length of 21 cm. of the retort was charged with the material and the temperature was raised gradually so as to reach 100 C. in 1^ hours and 500 C. in 7 or 8 hours. The products of distillation in percentage by weight of the dry substances were as follows : : ' ' Cellulose. Starch. Sugar. Coke % 32 9 % 28'6 % 12 2 Water.. . 31 '7 29 '7 6'29 Tar 3'25 2'69 55'04 Acetic acid 3'28 5'29 8 '78 Aldehydes. . 5 '82 5 '66 6'15 Ketones. . ... 11 1 11 34 Total gases 17-33 22'70 5 96 Carbon dioxide 1T26 13'08 4-37 Ethylene 24 0'39 05 Hydrogen 02 03 O'Ol Carbon monoxide 4 >7 8 7 64 r9 Ethane 0'35 74 O'll Methane. . . 0'68 82 0'13 TJOSS or undeterniines.. 5 23 4 -20 5'38 Composition of tar- Carbon 52'20 45 02 38'91 Hydrogen . . . 6'86 6 31 6'19 Oxygen . 40 94 48 '67 54-90 The time-temperature curves showed that with cellulose an exothermic decom- position takes place between 250 and 300 C, and that this reaction is complete at 320 C. This phenomenon is not shown by starch and sugar. The stability towards heat increases in the order: cellulose, starch, sugar; but the first two are more nearly alike in this respect than either is to sugar. Since cellulose does not yield methyl alcohol on dry distillation, it has been supposed that waste sulphite-cellulose lyes contain the constituents of wood which yield valuable distillation products. The lye was therefore partially separated from sulphur compounds by passing through it a current of air and steam, evaporated to dryness and distilled. A very small yield of liquid products was obtained and no methyl alcohol, whilst large quantities of hydrogen sulphide and mercaptan were evolved. J. Gasbel. vol 57 (1914) 32 and 55. J. Soc. Chem. Ind. vol 33 (1914) p. 129. Chem. Aba. vol. 8 (1914) p. 1344. Klason, P. and Segerfeld. BORNEOL IN SULPHITE LIQUOR. During rectification of alcohol obtained from waste liquor a reddish-brown oil separated out. From this oil optically inactive borneol, similar to that resulting from treatment of turpentine with concentrated sulphuric acid, was recovered. The borneol was probably formed in the digestion process from bornyl acetate (or similar ester) originally present in the volatile oils of the wood. Svensk Kem. Tid. Paper vol. 13 (1914) No. 18 p. 18. Chem. Abs. vol. 8 (1914) p. 1345. COMPOSITION OF WASTE SULPHITE LIQUOR 33 Bergstrom, H, 0. V. INACTIVE BORNEOL FORMED IN THE SULPHITE PROCESS- Papier-Fabr. vol. 13 (1915) p. 229. Chem. Abs. vol. 9 (1916) p. 2709. J. Ind. Eng. Chem. vol. 7 (1915) p. Paper vol. 16 (1915) No. 7 p. 18. 999. Hagglund, E . DIE SULFITABLAUGE UND IHRE VERARBEITUNG AUR ALKOHOL. (WASTE SULPHITE LIQUOR AND ITS CONVERSION INTO ALCOHOL.) Gives a discussion of the composition of the waste liquor. Fr. Vieweg. Sohn. Braunschweig (Germany) (1915) p. 56. Hagglund, E. CARBOHYDRATES OF PINE WOOD. Sulphite liquors contain 2-3 per cent sugar consisting of 0-71 per cent xylose; 1-04 per cent mannose; 0-06 per cent galactose; 0-06 per cent fructose; 0-43 per cent undetermined. Of the total sugar 30 per cent is xylose; 41-7 per cent mannose; 2-6 per cent, galactose; and 3-0 per cent, fructose. If the wood is hydrolyzed with 0-5 per cent H2S04 at 155 or 170 for 30-45 minutes, part of the cellulose is hydrolyzed so that glucose is present in the sugar mix- ture. The amount of sugar is 9 per cent or 14-5 per cent of the dry weight, depending on the temperature. The various sugars were: At 155. At 170. Xylose per cent. 32*7 per cent. 30' 1 Mannose 35'6 43'7 Fructose 4*3 4'7 Galactose 3'3 q . o Glucose 0'5 14'0 Undetermined .. 23'6 4'2 Chem.-Ztg. vol. 70 (1915) p. 416. Chem. Abs. vol. 9 (1915) p. 2925: Oman, E. THE AMMONIA TEST FOR SULPHITE LYES. Papier-Fabr. vol. 14 (1916) p. 509. Tekn. Tid. vol. 46 (1916) p. 4. J. iSoc. Chem. Ind. vol. 35 (1916) p. 832. Chem. Abs. vol. 10 (1916) p. 2636. Hagglund, E. ANALYSIS OF CALCIUM HYDROGEN SULPHITE SOLUTION Chem.-Ztg. vol. 40 (1916) p. 433. J. Soc. Chem. Ind. vol. 35 (1916) p. 686. Chem. Abs. vol. 10 (1916) p. 2636. Oman, E. SUGAR FORMATION IN THE SULPHITE PROCESS. At the beginning of the cook the lye contains a large proportion of non-hydrolyzed sugar. The non-hydrolyzed sugar is split up by the acid liquor during the progress of the cook, but it is by no means always completely hydrolyzed. Tekn. Tid. vol. 46 (1916) p. 6. Papier-Fabr. vol. 14 (1916) pp. 256, 273, 291, 306, 485, 584. J. Soc. Chem. Ind. vol. 36 (1916) p. 832. Chem. Abs. vol. 10 (1916) p. 2637 491203 34 FORESTRY BRANCH BULLETIN No. 66 Hagglund, E. SUGAR FORMATION IN THE SULPHITE PROCESS. (Reply to Oman.) Papier-Fabr. vol. 14 (1916) pp. 363, 57<0. Klason, P. REPLY TO OMAN'S ARTICLES ON SUGAR FORMATION AND ' "BLACK .COOKS." Papier-Fabr. vol. 14 (1916) p. 657. Klason, P. ANALYSIS OF SULPHITE LIQUOR. Discusses Oman's investigations on this subject especially the ammonia test. Svensk Pap. Tid. vol. 19 (1916) p. 115. Papier-Fabr. vol. 14 .(1916) p. 7(39. Oman, E. ANALYSIS OF SULPHITE LIQUOR (REPLY TO KLASON). Svensk. Pap. Tid. vol. 19 (1916) p. 143. Dieckmann, K. and Hagglund, E. THE ANALYSIS OF SULPHITE LIQUOR. Chem.-Ztg. vol. 40 (1916) p. 581. Chem. Abs. vol. 11 (1917) p. 1544. Kertesq, Z. VOLATILE ORGANIC COMPOUNDS FORMED IN THE SUL- PHITE PROCESS. The relief gases carry off acetaldehyde, acetone, methyl alcohol, acetic and formic acids, and furfural. One thousand litres (1220 gallons) waste liquor yield about 0-6 litre (0-13 gallons) acetaldehyde, 0-2 kg. (0-44 Ib.) acetone, 0-53 kg. (1-17 Ib.') methyl alcohol and 6.32 kg. (13.9 Ib.) ethyl alcohol. The essential oils which collected on the) surface of thes liquor were separated into 80 per cent cymene, 10-12 per cent sesquiterpene, about 4-5 per cent diterpene, and traces of polyterpene. Chem.-Ztg. vol. 40 (1916) p. 945. Chem. Abs. vol. 12 (1917) p. 1040. Paper-Maker Brit. Trade J. (1917) vol. 52 p. 36. Pulp Paper Mag. Can. vol. 15 (1917) pp. 236, 306. Dickerson, W. H. THE DISPOSAL OF WASTE SULPHITE LIQUOR. Discussion at the meeting of the American Technical Association of the Pulp and Paper Industry. Great variations in inorganic matters 5-10 grammes CaO and MgO per litre; specific gravity about 5 -8 Be. The ratio of inorganic material to the organic is on an average 15 per cent. By draining the blow-pits, approximately 1,500 pounds of solids should be obtained per ton of pulp (up to 2,100 pounds by special apparatus). Paper vol. 19 (1917) No. 20 p. 19. Klason, P. THE .SUGARS IN WASTE SULPHITE LIQUOR. Referring to Hagglund's work, Klason states that the fermentable sugar originates from the carbohydrates which are present in the wood to an amount of 16 per cent. Two liquors of specific gravity 1.052 and 1.0504 and dry substance 13.5 per cent "and 11.5 per cent were examined. Sulphurous acid titrated with iodine 0.26 and 0.13 per cent, lime content 0.75 per cent and 0.82 .per cent. The total sugar in the liquor is between 3.3 and 3.6 per cent as follows: mannose, 0.526 per cent; galactose, 0.279 per cent; glucose, 1.65 per cent; arabinose, 0.90 per cent. Glucose and mannose are more easily fermentable than galactose. The usual yield of alcohol from the liquor is 1 per cent by volume, maximum yield 1.4 per cent. Svensk Pap. Tid. vol. 20 (1917) p. 176. (See " Alcohol " p. 105. EFFLUENTS The sulphite mills situated on large rivers or seas usually have the great advantage of being allowed to discharge the waste liquor without any previous purification. In Canada with her large rivers and sparse population the problem of the disposal of waste liquor waters has not, therefore, been so 'widely discussed. However, in densely populated countries where legislation prohibits the direct emptying of the waste liquors into the streams the sulphite-pulp industry meets with great difficulties. In some districts mills are even forced to close down if they are unable to dispose of the liquor in a satisfactory manner. In fact the great development of processes for utilization of the waste sulphite liquor is due more to these circum- stances than to efforts on the part of the manufacturers to turn the enormous quanti- ties of valuable material wasted in this process into useful products. The available literature on the question of the pollution of rivers by sulphite liquor and the purifica- tion of the liquor shows that there is some difference of opinion regarding the injur- iousness of the liquor, caused by fibres, sulphurous acid, and dissolved organic sub- stances. It has been pointed out that the fibres collect in the river and precipitate impuri- ties from the effluents of other factories and from sewage, forming a mud at the bottom of the river, poisoning the fish, and causing other damage. The fibre losses from the mills are often very large, but the fact that these vary between 1 and 10 per cent of the dry pulp produced shows that it is possible, - by the use of effective save-alls, to decrease the losses considerably in some mills. This is especially desirable as it would mean a recovery of very valuable material. The fibres lost do not, as it is generally believed, consist chiefly of the less valuable parenchyma cells but contain a large proportion of good tracheids. The fibres are largely absorbed by the layer of algae and also form a nutriment for organisms. The growth of algae is considerably increased by the organic substances of the waste liquor, particularly the fermentable sugars. The algae usually present in the rivers are of a brownish colour and are attached loosely to the river-bed but are changed into a stronger structure of a greyish colour by the action of the sulphite liquor. In small rivers, and especially where the water flows slowly, the growth of algae caused by the organic matters of the liquor may be so considerable that the whole river-bed is practically covered with a layer of algae, preventing the fish from reaching the nutriment of the soil. Large proportions of the algae die and give rise to the bad odours often noticed. It has been considered of importance to remove as far as possible the free or loosely-combined SO2 from the liquor before discharge, and a neutralization of the liquor has been recommended. On the other hand it has been stated that a neutral or slightly alkaline liquor is more harmful as regards growth of algae than is 'the acid liquor. No doubt the organic substances directly favour the growth of algae and in small rivers or rivers with a slow current this has an injurious effect upon fish life, but it is also stated that a certain fish nutriment is developed through the influence of the organic substances. The former was the case in Konigsberg (Germany) where the liquor had to be taken in tank steamers and discharged in the open sea. The free sulphurous acid present in the liquor requires for its oxidation a certain amount of oxygen, which in rivers that are not sufficiently aerated has to be supplied by the water itself. In small rivers the fish may in this way be deprived of the oxygen required for respiration. Indirectly the sulphur content of the liquor may have an injurious effect upon fish life through the decomposition of sulphates and the subsequent formation of hydrogen sulphide. For the purification of waste liquor several methods have been proposed. A high dilution with water as obtained in large rivers is no doubt very effective as far as the oxidation of the reducing substances of the liquor is concerned, but the increased 49120 3-J 35 36 FORESTRY BRANCH BULLETIN No. 66 growth of algae caused by the organic substances is noticed even in high dilution if the liquor is added continually to the stream. But this alga (Sphaerotilus) is very sensitive towards any interruption in the food supply and, recognizing this fact, it has been proposed to discharge the liquor intermittently, e.g. twice in 24 hours. In some cases this has proved to be of benefit. Biological treatment has apparently not been successful because of the antiseptic action of the sulphurous acid. Irrigation does not effect the necessary purification except in cases where the liquor has previously been mixed with sewer effluents from a city. Oxidation of the liquor before discharge into the river has proved inefficient. The purification of the rivers by copper sulphate has also been considered, but it has been pointed out that this treatment will also destroy such algae as are necessary in the river for the production of oxygen and the absorp- tion of organic substances from waste effluents. Copper sulphate is also changed chemically by the action of the carbon dioxide present in the water. The copper car- bonate, however, does not act upon the fungus but precipitates in the sludge, and may in this way be injurious to the natural fauna of the river. Although it appears that no effective purification can be obtained in a simple manner and therefore the expensive evaporation of the liquor in some cases may prove to be the only possible method for its disposal, the modern processes for utilization of waste sulphite liquor, e.g. the production of alcohol, tannin extract, binding material, and fuel may satisfactorily solve the problem of river pollution by waste sulphite liquor. Mitscherlich, A. IMPROVEMENTS IN THE PROCESS OF, AND APPARATUS FOR BOILING WOOD WITH SULPHITES. Description of the most important points of the process and method of preventing the spent liquors from l>eing obnoxious, by discharging the same through iron pipes into collecting tanks containing cold liquid and then causing the same to mix with about one thousand times their volume of water. English Patent 1655 (1884). J. Soc. Chem. Ind. vol. 4 (1885) p. 549. Leisenberg, C. PROCESS FOR PURIFICATION OF EFFLUENTS BY ALKALI FERRITES OR ALEALI FERRITE ALUMINATES. . The sodium ferrite is made by heating an iron ore or a mineral containing iron, e.g. bauxite with sodium carbonate in a muffle. The waste water is first made slightly alkaline with lime and then the ferrite is added, iron hydroxide separates preventing formation of H2S and carries down much of the inorganic and organic substances present. German Patent 37882 (1886). Ber. (1887) p. 30. Papier-Ztg. vol. 12 (1887) p. 398. Korndorff, Th. PROCESS FOR PURIFICATION OF EFFLUENTS WITH CHARCOAL SATURATED WITH CHLORINE. German (Patent 32696 K.L. 12 (1886). Papier-Ztg. vol. 11 (1886) p. 1419. Konig, J. POLLUTION OF WATER AND DANGEROUS CONSEQUENCES. Methods of Purification of Effluents. Jul. Springer, Berlin (1887). Chem.-Ztg. vol. 11 (1887) p. 1111. PURIFICATION OF EFFLUENTS. Statement regarding dilution of waste water when discharged into the rivers. English Bill of August 18, 1886. Papier-Ztg. vol. 12 (1887) p. 770. WASTE SULPHITE LIQUOR EFFLUENTS 37 Schreib, H PURIFICATION OF EFFLUENTS. Action of calcium hydroxide upon the organic substances in the waste water. Papier-Ztg. vol. 12 (1888) p. 1489. Frank, A. PUKIFICATION OF EFFLUENTS. Frank is opposed to the use of processes in which the liquor trickles over lime- stone. Injurious substances can only be removed completely through the use of caustic lime. Papier-Ztg. vol. 14 (1889) p. 1488. Frank, A. PROCESS FOR PURIFICATION OF EFFLUENTS FROM SUL- PHITE MILLS BY FILTRATION OF IRRIGATION FIELDS. Only the removal of directly injurious substances from the liquor is necessary, whereas substances as sugar, amyloids, etc., are removed by self-purification in the river. Papier-Ztg. vol. 14 (1889) p. 363. Hofmiann C. : Handbuch der Papierfabrikation, 2nd edition (1897) p. 1597. Schubert, Zellstoffabrikation (1906) pp. 256, 266. Gottstein, L. PURIFICATION OF EFFLUENTS. Some success has been obtained by allowing the liquor to trickle over limestone. The formation of certain algae has been prevented. Papier-Ztg. vol. 14 (1889) p. 1556. OPPERMIANN'S PROCESS FOR PURIFICATION. To prevent the development of lower organisms in waste waters, ozonized dolomite or magnesia lime is used. Sugar and gum substances remain in solution. Papier-Ztg. vol. 14 (1889) pp. 1512, 1735. Schreib, H! FORMATION AND NATURE OF FUNGI TROUBLES. The lime that remains dissolved in the settled liquors is not injurious. Papier-Ztg. vol. 14 (1899) pp. 1576, 1875. Webster, M. PURIFICATION OF EFFLUENTS WITH ELECTRIC CURRENT. Papier-Ztg. vol. 14 (1889) p. 1312. Haussner, A. NEW FEATURES IN PAPER MANUFACTURE. The author refers to Frank's process for purification of waste liquor. The liquor is mixed in tanks with the gases from the digester and then with milk of lime; CaSOs is precipitated and is used again. The clear liquid is then treated with air for the separation of the lime. Webster has proposed a purification by means of electric cur- rent. Dingler's polytechn. J. vol. 275 p. 577, vol. 276 p. 49, vol. 277, pp. 118, 174, 211. Jahrb. Chem. Techn. (1890) p. 2876. Schreib, H. EFFLUENTS. Z. angew Chem. Vol. 3 (1890) p. 675. Durr & Co PROCESS FOR REMOVAL OF ACID FROM WASTE LIQUOR AT THE END OF THE "COOK". The liquor is subjected to evaporation at a very much diminished pressure. German Patent 71942 (1893). Ber. vol. 27 (1894) p. 220. SULPHITE WOOD LIQUORS AND POLLUTIONS. Several paper-mills in the Breslau and Liegnitz districts have made serious attempts to minimize the pollution occasioned by the discharge of sulphite liquors. 38 FORESTRY BRANCH BULLETIN No. 66 Neutralization with lime followed by settling, addition of lime in excess, and filtering off the precipitated sulphite, and variation of such treatments, have given only partial results. Two mills have adopted the drastic process of evaporation to dryness and calcining the residue, which appears for the moment to be the only effectual solution of the problem. Papier-Ztg. vol. 17 (1892) p. 2148. J. Soc. Chem. Ind. vol. 12 (1893) p. 58. Brack, E. TREATMENT OF WASTE LIQUORS FROM THE BISULPHITE PROCESS. The author proposes to treat these liquors with gelatin and alum for the removal of the soluble lignone derivatives and subsequently with chalk to neutralize. This treatment is found to remove one-fourth of the dissolved organic matter and a large proportion of the uncombined sulphite, and to give an effluent which remains un- changed for months. Chem.-Ztg. vol. 95 (1892) p. 1782. J. Soc. Chem. Ind. vol. 12 (1893) p. 460. Carpenter and Schulze. PROCESS FOR REMOVAL OF ACID FROM WASTE LIQUOR AT THE END OF THE "COOK". Warm compressed air is forced through the pulp, whereby oxidation products are formed which would only have been formed in the waste liquor by atmospheric oxidation. German Patent 78306 (1894). (Addition to German Patent 71942.) Ber. vol 28 (18%) p. 260. Wichelhaus, H. EXAMINATION OF WASTE SULPHITE LIQUORS AND EFFLUENTS FROM SULPHITE MILLS. Methods for purification. Removal of sulphurous acid by neutralizatioh with lime and oxidation of the organic substances by air. Chem. Ind. vol. 18 (1895) p. 51. Papier-Ztg. vol. 20 (1895) p. 1180. Hofrnann, C., Handbuch der Papierfabrikation, 2nd edition (1897) p. 1622. Chem.-Ztg. vol. 19 (1895) p. 46. Ekman, C. D. WASTE SULPHITE LIQUOR. Review of methods of utilization. Irrigation has proved unsatisfactory. The decomposed or oxidized liquor finds its way to the water-courses of the neighbourhood in the form of a dark liquor of disagreeable odour. The best method is to dilute the liquor at once with as much water as possible before it goes into the river. If no large river or sea is close at hand the best method is to evaporate the liquor and condense the steam so as to prevent pollution of the air. Papier-Ztg. vol. 21 (1896) part I pp. 2218, 2609, 3247. J. Soc. Chem. Ind. vol. 15 (1896) p. 735. Hofmann, C. HANDBUCH DER PAPIERFABRIKATION. Second edition (1897) p. 1622. Schnarmann, H. The erection of a plant at Unterkochen for preparation of Ekman's "dextrone" was forbidden because of the nature of the residual liquor. Papier-Ztg. vol. 22 .(1807) part II p. 3679. Spindler, H. PURIFICATION OF SULPHITE LIQUORS. The destruction of the organic substances is not complete even with energetic oxidation. Chem.-Ztg. vol. 21 (1897) p. 302. WASTE SULPHITE LIQUOR EFFLUENTS 39 Pollacsek, E. PROCESS FOR PURIFICATION AND UTILIZATION OF EFFLUENTS FROM SULPHITE MILLS. Oxidation with air and iron chloride. Austrian Privilegium 967 (1898). (See " Miscellaneous " p. 168.) Goldschmidt, E. ACTION OF FORMALDEHYDE ON SULPHITE LIQUOR. Spent sulphite lyes heated in hydrochloric acid solution with excess of formalde- hyde give a brown precipitate of methylene compounds of sugars; it may be prepared pure through the benzoyl compound. Formaldehyde is worthy of attention as a means of purifiying these waste lyes; it fixes the sulphurous acid and prevents excessive growth of moulds and algae. Chem.-Ztg. vol. 22 .(1898) p. 374. J. Soc. Chem. Ind. vol. 17 (1898) p. 790. DISPOSAL OF SULPHITE CELLULOSE WASTE LIQUORS. The offer of a sum of money for a process of rendering harmless the waste liquors of the paper and cellulose factories of Unterkochen and Wolfash resulted in 83 applic- ations of which 75 were German, the remainder being from America, England, Sweden, Norway, and Austria-Hungary. Besides the prize given for the process selected a further sum was given to the inventors of the next best process, and three other processes were considered worthy of attention. In very many cases suggestions were made which had already been tried and found to be impracticable. Many of the proposed processes failed to take into account the local conditions of the factories; others were obviously useless or else introduced other inconveniences. L. J. Dorenfeldt received the first prize, Drs. Appel and Max Buchner the second prize, and Dr. Oesterlen and Assistant Inspector Honold of Stuttgart with Drs. Kuehn and Gilg received honourable mention. Papier-Ztg. vol. 23 (1898) p. 3527. J. iSoc. Chem. Ind. vol. 17 (1898) p. 1171. Schikora. FISH EAT WATER FUNGI. Z. Fischerei (1899) part I p. 5. Banning and Setz. SETTLING ARRANGEMENT FOR WASTE WATER. D.R.G.M. 132826 (1900). Weigelt, C. EXAMINATION OF EFFLUENTS AND FISH WATERS. Edited by Deutsch Fischereiverein, 'Berlin 1900. Ferenczi, S. PURIFICATION OF WATER. Papier-Ztg. vol. 26 (1901) p. 271. Fischer, F DAS WASSER. Jul. (Springer, -Berlin (1902). Stutzer, A. ACTION OF SULPHUROUS ACID AND OTHER SUBSTANCES OF SULPHITE LIQUORS ON PLANTS. The author's experiments have shown that sulphurous acid is extremely injurious to plants that grow in water. Hence, when sulphite lyes are discharged into small rivers the plants on the banks turn yellow or pe'rish completely. In further experi- ments it was found that under the conditions chosen the influence of sodium bisul- phite upon the germination process was only slightly weakened by the presence of potassium carbonate. The latter salt, however, was able to strengthen germinated plants, so that taking an approximately equal number of plants the production of green leaves, etc., rose from 211 to 2Y5 grammes. The author concludes that the sodium 40 FORESTRY BRANCH BULLETIN No. 66 bisulphite gradually reacts with the constituents of the soil to form less injurious compounds, and that this change is accelerated by the presence of calcium carbonate. Neutral compounds of sulphurous acid that are only sparingly soluble in water are 3nuch less dangerous to plants than the readily soluble salts. Neutral potassium sul- phite is soluble in 800 parts of water. On mixing sulphite lyes, concentrated by evaporation, with an equal weight of powdered Thomas slag and evaporating the mixture the amount of sulphurous acid fell to 1 or 2 parts per 1,000 and the lime in the Thomas slag converted this residue of sulphurous acid into neutral calcium sulphate. Similar results were obtained in the actual experiments of plants. D. Landw. Presse vol. 29 (1903) p. 725. J. Soc. Chem. Ind. vol. 22 (1903) p. 42. Vogel, J. H. PAPER-MILL AND PULP-MILL EFFLUENTS. The effluents from sulphite wood-pulp mills are very objectionable, and no satis- factory process exists for their purification. These liquors contain, in addition to the sulphur derivatives, considerable quantities of sugar which afford nutriment for the growth of a fungus, Sphaerotilus natans, in the streams. Hofer has shown that it is the fermentable hexose sugars, principally, which give rise to its growth. Numerous attempts have been made to treat the liquors by the same process as is employed for the bacterial purification of sewage, but the sulphur compounds have such an inhibi- tive action on the bacteria that no purification is effected in the beds. The author thinks, however, that if the liquors were first treated for the precipitation of sulphites and were then subjected to putrefaction in a septic tank, with the addition of seepage, something might be effected by this process. Some mills dilute their liquors and run the effluents day and night into the stream; but Hofer considers that less harm is done by discharging the whole of the liquors at once, intermittently, provided the stream is a large one, since the fungus growths are thereby nourished for a shorter time. The so-called continuous settling arrangements do not remove the suspended matters so efficiently as sedimentation in tanks; in these, after 12-15 hours, the liquor only contains 10-12 milligrammes of suspended matter per litre. In soda-pulp mills, only the more dilute washings, containing 10 per cent of the total wastes, have to be discharged. In small streams these liquors give rise to the accumulation of algae. They should, however, be quite amenable to treatment on the bacterial system after a preliminary putrefaction in a septic tank, which would also serve for the removal of the fibrous matters by sedimentation. Wochbl. Papierfabr. vol. 37 (1906) p. 1612. Papier-Ztg. vol. 31 '(1906) pp. 1278, 1314 and 1355. J. Soc. Chem. Ind. vol. 25 (1906) p. 555. Gottstein, L. ON SULPHITE LIQUOR. According to experiments of the Bavarian Fishery Experimental Station it is preferable to run the liquor into the streams intermittently rather than continuously. i Remarks to Klemm. Papier-Ztg. vol. 51 (1906) p. 952. Z. angew. Chem. vol. 19 (1906) p. 1270. Klemm, P. WATER AND EFFLUENTS. Lecture to the Pulp and Paper Chemists. Papier-Ztg. vol. 31 (1906) p. 694. Z. angew. Chem. vol. 19 (1906) p. 293. Ramsay, W PURIFICATION OF EFFLUENTS. Z. angew. Chem. vol. 19 (1906) p. 833. Chem.-Ztg. vol. 30 part I (1906) p. 431. WASTE SULPHITE LIQUOR EFFLUENTS 41 Schreib, H ON THE QUESTION OF RIVER WATER PURIFICATION. Comments on Vogel's paper claims priority over Hofer. Papier-Ztg. vol. 30 (1906) p. 1111. Z. angew. Chem. vol. 10 (1906) p. 1302. Hofer, H. The author found by experiments with waste sulphite liquor that even at the dilution of 1 part to 100,000 parts of water, formation of algae takes place. This is due to the fermentable sugar, whereas the arabinose, rhammose, and xylose are not injurious. . Allgein. Fischerei Ztg. vol. 31 (1908) p. 71. Vogel, J. H. COMMUNICATION ON EFFLUENTS TO THE VEREIN DER ZELLSTOFF-UND PAPIER-CHEMIKER. This paper deals with (a) effluents from paper-mills (&) effluents from sulphite- pulp mills (c) effluents from sulphate-pulp mills. (6) Effluents from Sulphite-Pulp Mills. Of all the processes proposed for utilizing the waste liquor none have met with technical or financial success. It is therefore desirable that the proposals of Frank and Lehmann for using the liquor as a cattle food should be investigated and the merits of the proposals decided on. Purification by precipitating the organic substances with chemicals has not been and probably never will be successful, because precipitation will always be incomplete. Frank's process, which seemed the most useful, has been tried and it has been found that it does not render the liquor totally harmless. The sugar content must first be removed or changed in such a way as to render it harmless, as the presence of sugar increases the growth of algae. Hofer carried out experiments by letting sulphite liquor run into a stream continuously and observed the growth of algae. He found that the fermentable hexoses cause the rapid growth of sphaerotilus algae. He neu- tralized the sulphite liquor and fermented it with yeast and after driving off the alcohol the liquor was run into streams. No increased growth of algae was observed although the liquor was run in in concentrations of from 1 :100 to 1 :1000. The algae showed a noticeable tendency to die off; in any case it was impossible by this means to cause the rapid growth of algae. Experiments with glucose solutions showed the very rapid growth of algae, so in a few days the stream was filled with algae. Solutions of ypentoses such as arabinose were without influence on the growth of sphaeroltilus. When biological treatment of sewage was introduced it was thought that a similar treatment might purify sulphite liquor. When first introduced this biological treatment of sewage was not a success, but with subsequent modifications the treat- ment was able to render harmless most forms of organic matter, though not that con- tained in sulphite liquor. Spindler put forward a reason for this in that the organic substances of sulphite liquor are not easily oxidized. Hofer investigate.d the subject, working on it one year. It had the same chemical composition at the end as at the beginning. The cause of this was that the liquor contains compounds of sulphurous acid, e. g. of lime, dextrose, and ligno-sulphonic acid, which are strongly antiseptic, so that bacteria which can act readily on many organic substances have no effect on sulphite liquor. Hofer remarks that experiments are being carried on with a view to precipitating the sulphurous-acid compounds by means of lime before the biological treatment, but Vogel considers that a very considerable purification must be carried out first, as well as a removal of the lime salts by a process such as Frank's. After this treatment a biological treatment might be successful. A number of sulphite factories have endeavoured to solve the problem by a high dilution of the liquor. This has been carried out by first adding the wash-waters from the pulp to the liquor and running the same into the stream very slowly. Hofer 42 FORESTRY BRANCH BULLETIN No. 66 investigated this subject and found that even at great dilutions if the liquor was run in continuously the algae continued to grow, but if it was discharged intermittently there was a noticeable decrease in the algae. This has been put in practice at several mills bu,t it is too 'early to have arrived at any definite results. By allowing the sulphite liquor to stand, the greater part of the content of pulp- fibre sank rapidly to bottom, but the last (portion amounting to 4 milligrammes per litre is so fixed that it will not deposit even on standing 8 days. By allowing the liquor to stand the pulp content drops to 10-12 milligrammes which is the limit to be aimed at practically. Z. angew Chem. vol. 19 (1906) p. 748. Vogel, J. H. WASTE SULPHITE LIQUOR. The sugar content of Mitscherlich liquor is lower than that of Ritter-Kellner liquor. The sugar content is higher in liquors from wood cooked in the fall. The formation of fungus is not always injurious to the fish and may in many cases be considered as favourable; but the liquor should not contain sulphurous acid. In small rivers the formation of fungus may be so considerable that the entire river- bed is covered, thus (preventing the fish from reaching the nutriment of the soil, whereby the spawning places are destroyed. In quiet places in the river the sulphate may be decomposed, forming EkS which kills the fish. Purification with copper sulphate is not considered feasible as it will also kill such algae; as are necessary for the formation of oxygen and for the absorption of organic matters in the waste water. Wochbl. Papierfabr. vol. 38 (1907) pp. 881, 958. Papier-Ztg. vol. 31 (1906) pp. 1278, 1314, 1355. Z. angew. Chem. vol. 19 (1906) part I p. 750. Chem. Zentr. (1906) Part I p. 1853. Konig, J. POLLUTION OF RIVERS AND UTILIZATION OF WASTE SUL- PHITE LIQUOR. Z. angew. Chemie. vol. 19 (1906) part I p. 750. Verein, Deutscher Zellstoffabrikanten. DISCUSSION ON THE EFFECT ON FISH OF FUNGI CAUSED BY WASTE SULPHITE LIQUOR. Report on Meeting held on Feb. 17, 1906. Schreib, H. PROCESS FOR PURIFICATION OF EFFLUENTS. Chem.-Ztg. vol. 31 (1907) pp. 1133, 115,7. Z. angew. Chem. vol. 20 (1907) p. 1986, Vogel, J. H. COMMUNICATION ON EFFLUENTS TO THE YEREIN DER ZELLSTOFF UND PAPIER-CHEMIKER. (Z>) Sulphite Waste Liquor Summarizes the comments of Krause and Schreib on his previous paper. Prof. Marston lecturing on the effect of the algae on fish life stated that as a result of many observations there was grounds for considering algae as a useful fish food. It was suggested that copper sulphate might be added to the liquor as a bactericide, but this might be very expensive. Wochbl. Papierfabr. vol. 38 (1907) pp. 780, 881, 958. Papier-Ztg. vol. 32 .(1907) pp. 961, 1010, 1054, 1098. Z. angew. Chem. vol. 20 (1907) p. 786. Kirchner, E. Das Papier vol. 2 parts B. and C. Cellulose. Effluents from Pulp-Mills pp. 200-250, 400-474, 584-587. Kirchner, E. Das Papier vol. 2 pp. 122, 126. WASTE SULPHITE LIQUOR EFFLUENTS 43 Kolkwitz. BIOLOGICAL AUTO-PURIFICATION APPLIED TO THE DES- TRUCTION OF EFFLUENTS. Wochbl. Papierfabr. vol. 38 (1907) pp. 1998, 2289. Oesterreichischer Verein fur Cellulosefabrikation (Austrian Assoc. of Cellulose Manufacturers). PROCESS FOR MECHANICAL PURIFICATION OF TOTAL EFFLUENTS FROM PULP-MILLS AND PAPER-MILLS. German Patent 180768. Papier-Ztg. vol. 32 (1907) part I p. 948. Weigelt, C. CHEMICAL AUTO-PURIFICATION OF WATERS. Archiv fur Hydrobiofogie und Planktonkunde Reprint (1907) vol. 2. Luerssen, A. WATER POLLUTION BY SULPHITE-CELLULOSE FACTORIES. The effluent from the plant at Konigsberg was discharged into the River Pregel. It had been observed since 1872 that the river water during the hot months of the year became very offensive, the colour assuming also a deep brown or black tint. A searching inquiry, under the supervision of Prof. Pfleiffer, was 1 made in 1905. It was shown that the organic matters from the cellulose works, especially in warm weather, underwent rapid putrefactive changes which gave rise to the dark colour and the dis- gusting smell. The decision arrived at was that this effluent must be emptied into the town sewers, and this was allowed on the condition that the liquid underwent a pre- vious treatment with lime or other chemicals and was thoroughly neutralized so as to render the ligno-sulphites harmless. The acid present was not to exceed 0.06 per cent and the water was to be cooled down in large tanks at the factory before admission to the sewers. Z. Hyg. vol. 58 p. 121. J. Soc. Chem. Ind. vol. 27 (1908) p. 1220. POLLUTION OF THE WATERS OF LAKE CHAMPLAIN. Waters of Lake Cham-plain to be examined by the New York State Board of Health to ascertain the effect of the discharge into the lake of polluted water from streams on whose banks are located pulp-mills. Large numbers of dead fish are re- ported, and much slime on rocks that was never seen before the days of the pulp-mill. Pulp Paper Mag. Can. vol. 1 (1903) p. 126. Vogel, J. H. WASTE LIQUORS. Non-professional opinion frequently fails to distinguish between waste waters from pulp-mills and those from paper-mills. Tests on Mitscherlich and Ritter-Kellner waste lyes show that wood treated in the winter proved richer in saccharine contents than that dealt with in the spring. The percentage by weight of sugar in waste in summer was 0.5-0.875; while the percentage in winter was 1.0-2.0. Details of a plant to be erected 1 to purify waste lye from soda-pulp mills in such a way that it would be colourless and free from floating substances, are given. Claims that self- cleansing powers of small water-courses should be utilized in proportion to local require- ments. Pulp Paper Mag. Can. vol. 5 (1907) p. 142. Kolkwitz and Pritzkow, A. OPINION ON THE EFFLUENTS FROM PULP- MILL AT CZULOW. Chem. Zentr. (1908) part II p. 2048. Wochbl. Papierfabr. vol. 39 (1908) p. 332. Lassar-Cohn. CONTAMINATION OF RIVER PREGEL. This is caused by sulphite liquor, it is avoided by turning the sulphite liquor into the canal system. Papier-Ztg. vol. 33 (1908) part II p. 3379. Chem.-Ztg. vol. 32 (1908) p. 980. Chem. Zentr. (1908) part II p. 1545. 44 FORESTRY BRANCH BULLETIN No. 66 Vogel, J. H. EFFLUENTS FROM PULP-MILLS. The pollution of rivers by the effluents from sulphite wood-pulp mills may be direct (e.g. by fibres, dissolved organic matters, sulphurous acid) or indirect (e.g. by the growth and subsequent putrefaction of fungi and algae). Of the first class of polluting substances, the cellulose fibres are the most objectionable and the most easily removed. These fibres collect and precipitate impurities from sewage effluents and effluents of other factories and are deposited in the form of putrefying mud at the bottom of the river. On cases of damage due to pollution (e.g. fish poisoning or damage to crops after a flood) the ease with which the fibres are ' identified causes the responsibility to be thrown on the pulp-mill, even though the fibres are harmless them- selves and constitute only a small proportion of the mud. The cost of removing the fibres from the effluents is largely counter-balanced by the value of the recovered product, so that all mills should aim at discharging an effluent containing not more than 40 to 60 milligrammes of suspended fibres per litre, according to the size of the river. The waste liquors themselves if diluted 100 times are perfectly harmless to fish and vegetation, thus no direct damage is likely to ensue from their presence in the river; but the indirect nuisance caused by the growth and putrefaction of fungi may assume grave proportions in a slow-flowing river. The waste liquors at their original concentration are absolutely non-putrescible ; the growths are developed by the con- tinuous feeding of the lyes into the channel in a highly dilute form. A mill producing 40 metric tons (44-05 short tons) of cellulose per day will discharge 300 cub. m. (6,600 gallons) of original lye and 780 cub. m. (171,600 gallons) of wash-waters. The lye will very rarely contain 4 grammes of free sulphur dioxide per litre and this will be largely neutralized by the basic constituents of the wash- waters. The best method of preventing growths is to adopt the system of intermittent discharge of large quan- tities of lye instead of the continuous discharge of small quantities. The lyes in washing should be collected in a reservoir, freed from fibres, and discharged once or twice every 24 hours at such a rate that the total dilution of the original lye amounts to 100 times. The time of discharge might be about 40 minutes but every case requires particular consideration; much depends also on the degree of pollution by putrescible and the deoxidizing effluents from other sources. The author is opposed to the regula- tion requiring the neutralization of the effluents by lime. A neutral or alkaline con- dition of lye greatly favours the growth of fungi. It would seem apparently that the " free " sulphurous acid in these lyes is probably in loose combination with sugars and is far less poisonous to fish than pure sulphurous acid. All that is necessary is to insure that the free sulphurous acid does not amount to more than 1 gramme per litre of effluent ; the basic matters in the river water will do all that is necessary. In the case of very small water-courses, if the periodical discharge of the effluent be adopted it may be necessary to dilute the lyes in the reservoir before discharging. Papier-Ztg. vol. 33 (1906) part II pp. 3856. 3890, 3931. Wochbl. Papierfabr. vol. 40 ,(1909) pp. 857, 930. Z. angew. Chem. vol. 22 (1909) p. 49. J. Soc. Chem. Ind. vol. 28 (1909) p. 158. Chem. Abs. vol. 3 (1909) p. 1196. Pulp Paper Mag. Can. vol. 7 (1909) p. 289. WASTE WATER FROM PULP-MILLS. Daily amount of waste liquor and wash-water from a 40-ton mill, amount of free sulphurous acid. Recommends intermittent discharge. World's Paper Trade Rev. vol. 52 (1909) part III p. 36. Carlson, T. THE POLLUTION OF THE MONDAL RIVER (SWEDEN). (See " Composition " p. 12.) Kolkwitz and Pritzkow. REPORT ON WASTE LIQUOR FROM KATTOWITZ MILL. Mitt. Prufungsamt. Wasser u. Abwasser. Berlin vol. 10 (1909) pp. 1116, 173. Chem. Abs. vol. 3 (1909) pp. 1661, 1662. WASTE SULPHITE LIQUOR EFFLUENTS 45 Klason, P. PURIFICATION OF EFFLUENTS OF SULPHITE MILLS. For the disposal of the waste lyes from sulphite pulp-mills the correct principle consists in collecting them, with or without the wash-waters, in large reservoirs where they are cooled and aerated. They should then be discharged continuously and regularly into a river of sufficient volume. The main points to be considered are the proportion of the water to the organic matter and the quantity of oxygen dissolved in the water. If, on account of periods of drought, the volume of the river is restricted, large reservoirs should be provided for the storage of the lyes until the weather changes. According to the author's experience, no ill results whatever will result from the continuous discharge into a river which ensures a thousand-fold dilution of the lyes, corresponding to the introduction of 100 grammes of foreign matters per litre. A flow of 1 cub. metre (35-1 cubic feet) per second will deal with the by-pro- ducts from the manufacture of 7 metric tons (8-25 short tons) of air-dry cellulose per 24 hours. The average volume of a river may be calculated approximately as 40-60 per cent of the rainfall over the area drained by it. A reservoir capable of storing the lye and wash-waters for a week should be provided, and should be designed with a capa- city equal to 70 times the weight of the daily output of cellulose. The lye, diluted and infected with an equal volume of river water, will undergo a fermentation in the cpurse of 7 days storage, which will materially diminish the amount of organic matters ultim- ately discharged into the river. The self-purification of river-water polluted with sulphite-lyes may be divided into three states. The first is a rapid fermentation of some of the organic matters by organisms nourished by the phosphates and salts extracted from the wood. The oxygen of the water is rapidly consumed and the carbonic acid increases. When the supply of oxygen fails, the organisms respire at the expense of the organic solids in solution and powerful reducing actions supervene; this stage is the most noxious, and since the nitrogenous nutrition is limited it extends over a longer period than the first stage. The final state consists in a slow restoration of the natural condition of the water by the action of chlorophyll-bearing algae under the influence of light. Experiments made by the author showed that water at rest and at a constant temperature dissolves atmospheric oxygen at a slow rate only, but that variations of temperature act in the same way as mechanical agitation and cause a rapid aeration. The injuries to fish caused by sulphite lyes are principally indirect, brought about by the general deoxidation of the water; the resin, and, in soft waters, the free acid also bring about certain objectionable results; while the harm caused by fibres in suspension is practically negligible. Wood contains about 53 per cent of cellulose but yields only about 45 per cent of pulp ; the difference may be apportioned as follows : 4 per cent dissolved by chemical hydrolysis ; 3 per cent sorted out in cleaning and screening operations; and 1 per cent discharged with the wash- water. Thus the effluents may be estimated to contain, in suspension, about 2 per cent of the cellulose output of the mill; only about one-fourth of this suspended matter consists of thin-walled parenchyma cells which do not settle out on standing. Wochbl. Papierfabr. vol. 40 (1909) p. 2668. Papier-Fabr. vol. 7 {1909) pp. 26, 671, 701, 796. J. Soc. Chem. Ind. vol. 28 (1909) p. 1000. Papier-Ztg. vol. 35 (1910) p. 2116. Pulp Paper Mag. Can. vol. 8 (1910) p. 185. Paper vol. 3 .(1911) No. 2 p. 9. EFFECT OF PAPER-MILL EFFLUENTS ON FISH. The bad effect is due to fibres and sawdust. Papier-Fabr. vol. 8 (1910) p. 947. Z. angew. Chem. (1909) p. 2205. 46 FORESTRY BRANCH BULLETIN No. 66 Schneider, F. POLLUTION OF STEEAMS BY SULPHITE LIQUOR. The algae which are carried by the pulp-fibres choke up boilers, etc. River water into which sulphite liquor has been discharged will cause a rash on bathers, even though there is not enough liquor present to cause a taste in the water. Papier-Ztg. vol. 35 (1910) p. 1902. Z. Hyg. (1907) p. 121. Papier-Fabr. vol. 7 1909) p. 34. Z. angew. Chem. vol 22 (1909) p. 655. COPPER AS PURIFIER FOR WATER. Moore's invention by which it is claimed that any water is made free from germs in a few hours by addition of small amounts of copper. Zentr. Wasserbau. vol. 24 (1909) p. 377. EXPERIMENTS WITH COPPER SULPHATE AS A MEANS OF KILLING ORGANISMS IN PONDS AND RESERVOIRS. From 37th Annual Report of the Sanitary Board of Massachusetts, Boston, 1906. Gesund-. Ing. vol. 25 (1909) p. 422. Mackay and Miller. COST OF TREATMENT OF EFFLUENTS. J. Soc. Chem. Ind. vol. 28 (1909) p. 1183. Schall, C INNOVATION IN THE PURIFICATION OF EFFLUENTS. German Patents 194745, 204470, 206743, 206999, 207355, 194744, 197160, 202393, 196390, 194127, 2083-73, 201052, 197587. Z. ges. Wasserwirtsch vol. 9 '(1909) p. 147. Pritzkow, A THE PRESENT SITUATION OF THE EFFLUENT PROBLEM IN THE SULPHITE MILLS. Processes of purification and the effects on the waterways. Treatment of waste liquors by natural and artificial biological processes. Elimination by irrigation and evaporation. Utilization of substances 'contained in the liquor. Reprint from Vierteljahr. Ger. Med. 3 Folge XL Bol. No. 1 Berlin 1910. Eng. Record vol. 62 (1910) p. 468. Chem. Abs. vol. 5 (1911) p. 1144. Paper vol. 7 (1912) No. 1 p. 23. Vogel, J. H REPORT OF THE ASSOC. OF PULP AND PAPER CHEMISTS (1909) III WATER AND EFFLUENTS. Part C giving literature on effluents for year 1909. Papier-Ztg. vol. 35 (1910) p. 1931. Vogel, J. H. REPORT ON SULPHITE MILL AT RAGNIT, GERMANY. The author has reported on the possible pollution of the River Memel by the effluents from a sulphite-pulp mill which it is proposed to erect at Ragnit. The mill would produce 40 metric tons (44 short tons) of cellulose per 24 hours and the amount of effluents per second would consist of 3.47 litres (0.75 gallons) of waste lye; 9.26 litres (2-04 gallons) of cooling, rinsing, and washing waters, and 200 litres (44 gallons) of manufacturing waters. The flow of the river at low water is calculated at 200 cub. m. (7,000 cu. ft.) per second, and the river having numerous curves it is assumed that perfect admixture would be attained at a distance of 8 km. (5 miles) from the works, the dilution of the waste lyes being then 45,000 fold. Under these conditions any injury to the Tilsit waterworks, situated at a distance of 14 km. (8.7 miles), is amply provided against, and destruction of fish and the growth of fungus are considered to be quite out of the question. In addition to the manufacture of wood-pulp it is proposed to bleach 10 tons (11 short tons) of cellulose daily for the manufacture of paper, the bleaching effluents being mixed with the sulphite lyes and assisting their WASTE SULPHITE LIQUOR EFFLUENTS 47 oxidation. The author recommends. that the discharge be allowed under the follow- ing conditions: The strong waste lyes and the wash-waters used on the pulp for rinsing in the boiler itself, are to be collected in a reservoir of 1,000 cub. m. (35,300 cu. ft.) capacity, from which they are to be mixed after cooling with the constantly flow- ing clarified waste water from the manufacturing operations, and the diluted effluent discharged into the river. The manufacturing waste water and the used bleaching lyes are only to be admitted to the main effluent pipe after they have been so clarified from fibre that the maximum amount of suspended matter does not exceed 100 milli- grams per litre. The main discharge pipe must extend at least 5 metres (16.4 ft.) into the river, and must be provided with perforations for a length of 3 metres (.84 ft.) at the end in order to avoid discharge of a dense column of polluted liquid. Papier-Fabr. vol. 9 (1911) p. 438. J. Soc. Chem. Ind. vol. 30 (1911) p. 532. Chern. Abs. vol. 5 (1911) p. 2520. SULPHITE WASTE LIQUOR. Refers to Mitscherlich's original process for producing cellulose that demanded a dilution of 3,000 times the sewage from his process in order to render it inoffensive. Three types of waste: (1) digester liquor and wash-water; (2) screen and filter press water from the pulp presses; (3) condenser water and other water from machine operation. German conditions: 1-2 gallons of waste liquor from each pound of pulp. In 1908 Germany discharged daily 3,960,000 gallons of waste liquor of which 1,760 tons were solid matter containing 1,230 tons organic matter. Author reviews methods for treatment of waste in streams to destroy growths, etc. Evaporation claimed to be expensive, as a plant in Upper Silesia showed a cost of 82 cents per gallon when evaporating 50,000 gallons of liquor daily. Pulp Paper Mag. Can. vol. 10 (1912) p. 217. Kerschaw, G. B. THE PURIFICATION OF WASTE LIQUORS FROM PAPER- MILLS. Refers to waste from paper-mills in the manufacture of different papers. The following table was taken from vol. 3 of the 7th Report of the Sewage Disposal Com- . mission : PARTS FOR 100,000. Suspended Dissolved Oxygen i ibsorbed. In 3 min. In 4 hrs. AVhite papers crude liquors 204 54 20 139 68 4'84 Brown papers, crude liquors 290 477 39'6 59 106 3'98 126 178 25 'I ^^all papers, crude liquors 185 305 27 '8 Printing papers, crude liquors 6'2 264 3'92 89 157 2'30 Pulp Paper Mag. Can. vol. 13 (1015) p. 111. Reinitzer, B CONTAMINATION OF WATER SUPPLIES. It is stated that by mixing together the waste digestion liquors and the residues from the bleaching process both waste products are rendered innocuous to fish and 48 FORESTRY BRANCH BULLETIN No. 66 can be safely discharged into a water-course. The method is said to have worked satisfactorily in practice for a long time. Papier-Ztg. vol. 36 (1911) pp. 2882, 2913. Z. togew. Chem. vol. 24 (1911) p. 1851. J. ;Soc. Chem. Ind. vol. 30 (1911) p. 1206. Oesterr. Chem.-Ztg. vol. 15 p. 61. Chem. Abs. (1912) p. 1480. Pritzkow, A. INFLUENCE OF SULPHITE LIQUOR ON RIVER TILSIT. Mitt. Prufg-Amt. Wasse'rversorg. u. Abwasserbesseit. (1911) p. 119. Chem. Zentr. (1911) part II p. 1455. Rohland, P. ADSORPTION BY CLAYS, IV (DECOLORIZATION OF WASTE SULPHITE LIQUORS). The author has shown previously that clays rich in colloids have the power of adsorbing complex animal, vegetable, and artificial colouring matters, but attempts to remove the colouring matter from waste sulphite-cellulose lyes by adsorption with clay failed. The yellowish-brown colouring matter present in these* lyes is probably an iron compound, for on adding potassium ferrocyanide the deep greenish-blue colour of Prussian blue makes its appearance after some time. After this preliminary treatment the lyes can be decolorized by means of clay, for the latter adsorbs Prussian blue. Biochem. Z. vol. 46 (1912) p. 374. - J. Soc. Chem. Ind. vol. 31 (1912) p. 1119. Wellensick, F. CLARIFICATION OF EFFLUENTS. The effluent is treated with an alkaline solution of the humic substance separated from the waste lyes from the manufacture of cellulose from straw or wood, and then with basic or acid salts or other precipitants, e.g. milk of lime or aluminium sul- phate. German Patent 266998 (1913). J. Soc. Chem. Ind. vol. 33 (1914) p. 39. Scott, J DANGERS AND USES OF WASTE SULPHITE LIQUORS. The luxuriation of organisms in waters containing waste sulphite liquor seems also to depend on the soil of the river banks and the composition of the water itself. Paper-Maker Brit. Trade J. vol. 42 (1911) -No. 3 p. 401. Wasser Abwasser vol. 4 (1911) p. 540. Lassar-Cohn. PROCESS FOR RENDERING EFFLUENTS FROM SULPHITE MILLS HARMLESS. The pulp from the digester is pressed before washing and the liquor thereby pressed out is disposed of separately. German Patent Application 36157 (1913). Polz, H. The author has tried Rohland's Process of Purification with colloid clay and found it impracticable. Paper-Ztg. vol. 38 (1913) p. 3064. Wochbl. Papierfabr. vol. 44 (1913) p. 4611. Bohland, P. ADSORPTION POWER OF THE HYDROXIDES OF SILICON, ALUMINIUM AND IRO'N. The yellowish-brown, vegetable, colouring matter found in sulphite liquor is now adsorbed by the above mentioned hydroxides. Z. angew. Chem. vol. 80 (1913) p. 174. Chem. Zentr. {1913) part I p. 1858. WASTE SULPHITE LIQUOR EFFLUENTS 49 Vogel, J. H. WASTE WATEE FROM SULPHITE MILLS. The waste liquor should be treated as follows : 1. The cooking liquor evaporated, mixed with coal, and burned, 2. Remaining waste settled in basins, filtered, and used again, 3. Some of the wastes may be used for irrigation, 4. The white water waste purified by sedimentation in baffled settling basins. Papier-Ztg. vol. 35 (1911) p. 1547. Chem. Abs. vol. 6 (1912) p. 803. Stutzer, A. PARTIALLY REMOVING COLOURING MATTER FROM THE BACK WATER OF THE SULPHITE-CELLULOSE MILLS. The liquor is treated with phosphoric acid in the absence of a stronger acid. German Patent 246658 (1911). Chem. Abs. vol. 6 (1912) p. 2529. Rohland, P. PURIFICATION OF EFFLUENTS WITH COLLOID CLAY. Answer to Polz's criticism. Farber-Ztg. vol. 24 (1913) No. 21 p. 401. Papier-Ztg. vol. 38 (1913) p. 3522. Techn. Verein fur Zuckerfabrikation. HUMIN FOR PURIFICATION OF EF- FLUENTS. Humin alone or in mixture with lime has proved favourable in the purification of waste water from the sugar factories. Humin, a brown coal (lignite) extract, has a great adsorption power, encases small particles, and causes them to settle. Deut. Zuckerind. vol. 36 (1911) p. 243. Gottstein, I. THE PROBLEM OF EFFLUENTS. In a report the author claims that the composition of the liquor is less important than the dilution. Mixing with waste water from cities is often even of sanitary and hygienic effect. Wochbl. Papierfabr. vol. 43 (1912) p. 4329. Kolkwitz, R. THE SULPHURBOGITTUS "THIOPLOCA INGRICA WIS- LAUCH." Ber. Botan. Ges. vol. 30 (1912) p. 9 Borntrager, Berlin. Rohland, P. THE COLLOID PURIFICATION PROCESS FOR WASTE WATER. The colouring matter in the sulphite liquor is not absorbed by the colloid clay. Chem.-Ztg. vol. 37 (1913) p. 754. INTERMITTENT RELIEVING OF WASTE SULPHITE LIQUOR. An Austrian sulphite mill of 18 metric tons (19-8 short tons) capacity discharged the liquor diluted by 14 cub. m. (3,080 gallons) water into the river for two hours in every 24 hours. An increase in the formation of fungi in the river was experienced. Papier-Ztg. vol. 36 (1911) p. 864. Schlauf, J. THE SANITARY IMPORTANCE OF THE SULPHITE MANU- FACTURE INCLUDING THE BLEACHING WITH CHLORIDE OF LIME. Mixing of waste liquor with waste bleach liquor. Paper-Maker Brit. Trade J. vol. 42 (1911) Apr. 1 p. 55. Tillmann, J. WATER PURIFICATION AND REMOVAL OF WASTE WATER. Review of all Processes and Apparatus. (Ed. W. Knapp, -Halle, 1912.) 491204 50 FORESTRY BRANCH BULLETIN No. 66 Walker, W. 0. THE PROBLEM OF THE WASTE LIQUOR FROM SULPHITE 'PULP MILLS. A discussion of various methods of utilization. In some countries legislation has been enacted with regard to the disposal of this waste. That condition has not yet arrived in Canada, mainly on account of its large rivers and sparse population. The waste liquor is usually discharged into rivers and on account of its great volume and high content of organic material it then becomes a source of pollution, renders the water injurious to health, unfit for boiler purposes, and injurious to fish or other life. It causes in many cases the development of algae and in the smaller rivers the stream beds are sometimes completely choked with them. Under certain conditions the sulphite wastes develop large quantities of sulphuretted hydrogen, entailing *a rapid loss of dissolved oxygen and the death of all animal and plant life in the stream. J. Soc. Chem. Ind. vol. 32 (1913) p. 389. Chem. Eng. vol. 17 (1913) p. 246. Neresheimer, E. THE DISPOSAL OF SULPHITE-CELLULOSE WASTE. The liquor is detrimental less on account of S02 and fibres than on account of the large amounts of organic matter. Rivers receiving such wastes show a strong growth of Sphaerotilus, large amounts of which die off, resulting in a decided odour nuisance. The continual discharge of the liquor into the river, in high dilution, has proved inefficient. Good results have been obtained by discharging at intervals, as the fungus is very sensitive towards interruption in its food supply. Biologic treatment has not been successful. Evaporation is very expensive. Die Wasserwirtschaft vol. 6 p. 2. Wasser Abwasser vol. 7 (1914) p. 406. Chem. Abs. vol. 8 (1914) p. 1178. THE PROBLEM OF UTILIZATION OF WASTE WATERS FROM SULPHITE MILLS. The addition of waste liquor to the city sewer for irrigation fields has proved favourable in Konigsberg, Germany. The emptying of the waste liquor into the har- bour has increased the fish nutriment (plankton). Chem.-Ztg. vol. 38 (1914) pp. 639, 667. Wochbl. Papierfabr. vol. 46 (1915) p. 144. Chem. Abs. vol. 8 (1914) p. 3857. Gottstein, L. THE PROBLEM OF UTILIZATION OF WASTE WATER FROM THE SULPHITE MILLS. Correcting several points in the articles by Lassar-Cohn. Chem.-Ztg. vol. 38 (1914) p. 804. Splittgerber, A. DISPOSAL AND UTILIZATION OF CELLULOSE AND PAPER FACTORY WASTE. A general discussion of the waste liquor problem. Four methods of purification are mentioned; irrigation, artificial biologic treatment, infiltration, and evaporation. Chem. Abs. vol. 9 '(1916) p. 376. Wasser u. Gas. (1914) pp. 243-5, 268-70, 290-3, 313-6. Wasser Abwasser vol 7 (1914) p. 24. Hofer, H WASTE SULPHITE LIQUOR, GROUND-WOOD PULP, AND CEL- LULOSE AS NUTRIMENT IN FISH PONDS. Waste! liquor containing no free S02 wood-pulp and cellulose, which contains sugar or yields sugar on fermentation, have been found beneficial to fish life and growth and to the growth of plankton upon which the fish feed. Allgem. Fischerei. Ztg. (1915) Nos. 20,21. Papier-Ztg. vol. 41 (1916) p. 1. Chem. Abs. vol. 10 (1916) p. 1432. WASTE SULPHITE LIQUOR EFFLUENTS . 51 Schmidt-Nielsen, S. THE POLLUTION OF DRAMMENS RIVER (NORWAY) CAUSED BY PULP-MILLS AND PAPER-MILLS, 1911 AND 1912. Biological and chemical investigations. An investigation of the fibre losses from some 20 mills proved that these varied for the various mills between 1 and 10 per cent of the dry production, depending on the technical arrangements for recovery. The average length of the fibres were from 0-6 to 1-7 millimetres and several fibres, especially from the chemical pulp-mills and the paper-mills, reached a length of 3-4-5 millimetres. The losses do not consist chiefly of the less valuable parenchyma cells but to a great extent of good tracheids. At a certain point the river receives from the mills not less than 13,000 kg. (28,600 Ib.) dry fibres and 200,000 kg. (440,000 Ib.) dissolved organic substances in 24 hours, and in addition to this impurities from the logging. The reasons why the troubles caused by this pollution are not more pronounced are the facts that the mills are dis- tributed over a long distance and that the quantity of water in the river is large enough for an effective dilution. The water is also very effectively aerated in the many water- falls along the river. The river-bed is covered with a grey layer of algae which holds very strongly together, whereas the algae usually present in rivers is, as a rule, brown or greenish- brown and very loose. The algae grows rapidly in the presence of permanent nutriment in a low concentration from the waste liquors. Also, fibres are absorbed which streng- then the algae layers and contain nutriment for organisms. No investigations have been made to determine the effect of the normal algae layer upon the breeding of the salmon spawn, but if the algae layer forms the basis for fungus and bacteria growth the salmon spawn no doubt are damaged. Papir J. vol. 4 (1916) No. 2 pp. 17, 196. Graetz, B. PURIFYING SULPHITE BACK-WATER. The sulphite liquor is treated with fuel ash. Swiss Patent 73107 (1916). Danish Patent 21889 (1917). Chem. Abs. vol. 11 (1917) pp. 100, 2163. Pulp Paper Mag. Can. vol. 15 (1917) p. 741. Hoskins, W. SEPARATING SUSPENDED PULP FROM SULPHITE EFFLU- ENTS. The waste liquor is passed over a layer of limestone. The C02 generated by the action of the acid in the solution upon the CaCOs carries the pulp to the surface, and it is skimmed off and recovered. United States Patent 1226333 (1917). Chem. Abs. vol. 11 (1917) p. 2153. Pulp Paper Mag. Can. vol. 15 (1917) p. 741. 49120 4-| BINDING MATERIAL When waste sulphite liquor is concentrated to a thick liquid or to dryness a tar- like product is obtained which consists chiefly of compounds of lignin-sulphonic acid in admixture with sugars, and which is suitable as a binding material for powdered substances. The most important operation in the manufacture of a binder from the waste liquor is, therefore, the evaporation, but it is also often recommended in the numerous patents to purify the liquor before the evaporation by removing certain products which are not desired in the final binding material. The binding power may be increased or other qualities of the ultimate products may be obtained by the addition of certain substances to the liquor. In some cases when it is desired to remove- part of the calcium from the solution, sulphuric acid or a sulphate is added to 1he crude liquor, in other cases the liquor is neutralized with lime before evaporation. Instead of preparing the binder for briquetting separately it has also been proposed to mix the liquor with the briquetting material and other substances directly, as in the German Patents 246289 and 252439, according to which sulphuric acid or an acid compound is added to a mixture of sulphite liquor and bri- quetting material, with or without the addition of aldehydes. The mixture is heated to the point of gelatinization, which can be accelerated by adding such substances as tar, tar-products, asphalt, etc. Afterwards the briquettes are dried below 200 C. Among the many uses for which the binder from sulphite liquor has been recom- mended are binding material for briquetting powdered fuel (such as coal, peat, saw- dust, etc.), blast furnace dust, and fine pyrites. The binder is also used in foundries for making sand cores and for binding dust on roads. It has been pointed out as a drawback in the use of concentrated waste sulphite liquor as a binding material for briquetting powdered fuel that it is hygroscopic and soluble in water and, therefore, the briquettes are not weather resistant. Many methods for the elimination of this disadvantage have been patented. It has been recommended to heat the briquettes to a high temperature in order to carbonize the binder or to add to the liquor compounds of chromium and finally aluminum sulphate. Pollacsek has patented a process whereby the briquettes are immersed in a mixture obtained by heating crude petroleum oil, containing paraffin or ozokerite substances with bitumen and phenols, to the boiling point with strong aeration, until a mixture is obtained which solidifies on cooling. Favourable results have been reported by iron works regarding the use of waste sulphite liquor for briquetting coke dust and fine ore. According to Mathesius the reduction of iron ore is more favourable with briquettes, and a great saving in coke and an increased production has been experienced. In late years a product called "Zellpech" or "cell-pitch" has been manufactured and has occasioned considerable interesting discussion. The product is obtained by neutralizing the cooled liquor in wooden vats and filtering it through coke, whereupon the filtrate is concentrated by evaporation to a density of 35 Be. and used in this form, or is evaporated to dryness and made into blocks. This pitch contains 10 per cent moisture and represents 10 per cent of the original liquor. It has the appearance of a black, opaque rosin and is soluble in water. For the production of one ton of ''cell-pitch" one ton of coal is required, Its heat value is 3,166 calories (5,700 B.T.U.). The price of 10-12 dollars (in 1912) per ton is very close to that of tar. But for bind- ing fine coal only 5 per cent of this pitch is required, whereas Y-10'per cent of tar pitch is used. ^ Cell-pitch is also used for impregnating sail-cloth and ropes, and as a filling material. Blast furnace dust containing about 40 per cent iron may be mixed with ground cell-pitch, the proportion of pitch being 4-5 per cent. The mixture is heated with superheated steam at 350-420 C. and pressed into bricks. These bricks do not lose their shape in the furnace at a temperature of 1,600 C. 52 BINDING MATERIAL FROM WASTE SULPHITE LIQUOR 53 In Europe as well as in America waste sulphite liquor concentrated and neutralized has been used as a road-binder with apparent success. The United States Department of Agriculture made extensive experiments with waste sulphite liquor, with the result that concentrated liquor of a specific gravity of 1.13 may be classified as a temporary or semi-permanent dust preventive and road-binder. Half a gallon per square yard was effective for a period of 6 weeks. The cost including labour and material was estimated to be $0.0355 per square yard. The results of comparative tests at Queen's University, Kingston, Ontario, were in favour of using concentrated (4:1) waste sul- phite liquor instead of road oil. The road oil was washed away at the end of 4 months, whereas the roads treated with waste liquor directly or after previous treatment with oil still presented a hard surface at the end of that period. It has been suggeBted that the binding and water-resisting qualities be improved by emulsifying the liquor with mineral oil. Nettl, A. S. PROCESS FOR TRANSFORMING THE WASTE LIQUORS FROM THE MANUFACTURE OF SULPHITE CELLULOSE INTO SUB- STANCES MADE AVAILABLE FOR INDUSTRY. Austrian Privilegium 1576 (1888). (See " Gums, Adhesives and Sizing Material " p. 68.) inimann, H. PROCESS FOR UTILIZING SULPHITE LIQUOR AS A BIND- ING MATERIAL. The liquor, evaporated at least one-half, is treated with alkaline carbonates by which the dissolved organic substances are precipitated. It is proposed to use the precipitate as a binding material for briquetting wood, coke, and coal. Austrian Privilegium 3043 (1890). Mitscherlich ,A PROCESS FOR THE PRODUCTION OF TANNING MATE- RIALS, ADHESIVES, AND OTHER SUBSTANCES FROM WASTE SULPHITE LIQUORS BY OSMOSIS. German Patent 72161 (1891). English Patent 12927 (1893). (See " Tanning Materials " p. 78.) Mitscherlich, A. PROCESS FOR PREPARING ADHESIVES, BINDING AND CONCENTRATING MATERIALS' FROM WASTE SULPHITE LIQUORS. The liquor is directly neutralized with milk of lime without osmosis, then evapor- ated to a specific gravity of 1-2 and mixed while hot with one-fourth of its volume of a paste of lime of specific gravity 1-2 until the lime is absorbed and a thick, trans- parent substance is formed. This organic lime compound should be used for pre- paring coal briquettes, for binding powder substances, and for concentrating purposes. German Patent 72362 -(1891). Ber. vol. 27 (1894) p. 221. Papier-Ztg. vol. 19 (1894) p. 272. Jiirgensen, F., Niesz, Fr., Giimbel, G. ADHESIVES LIKE THAT PRODUCED BY PATENT 72386 ESPECIALLY FOR COATING CONTAINERS FOR PETROLEUM, ETC. German Patent 73718 (1892). (See " Gums, Adhesives, and Sizing Materials " p. 68.) Griffin, M. L. PROCESS FOR PRODUCING A PLASTER. Glue is dissolved in hot, waste sulphite liquor and the mixture when cooled is mixed with gypsum, fibrous material, sand or marble. The plaster has a low heat conductivity and is suitable for plastering purposes. German Patent 69874 (1892). Ber. vol. 26 (1893) p. 905. 54 FORESTRY BRANCH BULLETIN No. 66 ,* COAL BRIQUETTES MADE WITH WASTE SULPHITE LIQUOR. The remaining adhesive product from the evaporation of waste liquor has been used since 1893 in an iron works in Hungary as a binding material in the manufac- ture of briquettes from charcoal dust. Hofmann, C., Handbuch der Papierfabrikation 2nd edition (1897) p. 1620. Papier-Ztg. vol. 21 (1896) p. 1183, vol. 22 (1897) p. 3647. J. Soc. Chem. Ind. vol. 15 (1896) p. 579. Pollacsek, E. TREATMENT OF WASTE LIQUOR FROM THE SULPHITE PROCESS. The liquors, not previously purified, are mixed at ordinary temperature with fine coal, peat, or similar fuel with the addition of lime and kagnesite in the proportion of 1 part waste liquor, 5 parts coal or other material, 1 per cent of the mixture of lime, and i per cent of magnesia. Austrian Privilegium 985 (1898). Schild, H. SULPHITE WASTE LIQUOR AS A BRIQUETTING MATERIAL. According to German Patent 111757, coal for cooking purposes is preferably mixed with partially evaporated sulphite liquor. The amount to be added to each grade of coal must be found by experiment. Ten per cent of the weight of coal is usually used. The ash is thereby increased by about 0-5 per cent. Papier-Ztg. vol. 25 (1900) part I p. 1725 part II pp. 1125, 2456. Jahrb. Chem. Techn. '(1900) Part I, p. 15. Trainer, E. PROCESS FOR PREPARATION OF A BRIQUETTING MA- TERIAL. The liquor in a syrupy state has previously been used as a briquetting material. The hard brittle substance obtained from the evaporation of the liquor is now mixed with the coal dust, the mixture heated, and subjected to pressure. German Patent 136322 (1900). Chem. Zentr. (1902) p. 410. Papier-Ztg. vol. 27 (1902) part II p. 3478. Trainer, E. PREPARATION OF A BRIQUETTING MATERIAL FROM CAR- BOHYDRATES, (ALBUMINOIDS, RESINS, ETC-) The above named substances are boiled under pressure with acid sulphites, and the resulting liquid is evaporated to dryness. The dry mass can be used as a briquet- ting agent. German Patent 140542 (1900). Jahrb. Chem. Techn. (1903) p. 162. 'Trainer, E. PREPARATION OF A BRIQUETTING MATERIAL. Tar, resin or wax, etc., may be added to the liquor before evaporating. German Patent 140862 (1900) (addition to Ger. Patent 136322). Papier-Ztg. vol. 28 (1903) part II p. 1942. Jahrb. Chem. Techn. <(1903) part I p. 16. Wochbl. Papierfabr. vol. 34 (1903) p. 2658. Trainer, E. PROCESS FOR PREPARATION OF WATER-RESISTANT BRI- QUETTES WITH WASTE LIQUORS. The mixture of binding material and fuel is exposed to heat at not less than 120 0. , German Patent 144819 (1902). Papier-Ztg. vol. 28 (1903) pp. 86, 3086. PROCESS FOR UTILIZATION OF WASTE LIQUORS FROM THE SULPHITE PULP-MILLS. Discussion of the Trainer process, German Patent 140862 (1900). Papier-Fabr. vol 1 (1903) p. 419. BINDING MATERIAL FROM WASTE SULPHITE LIQUOR 55 Partington, E. UTILIZATION OF SULPHITE LIQUOR. The author has used sulphite liquor as a binder for street dust. Papier-Ztg. vol. 29 (1904) part II p. 2686. Trainer, E. PREPARATION OF A BRIQUETTING MATERIAL. The sulphite liquor is concentrated to a point such that, without mechanical means, a powdery substance is obtained. German Patent 161675 (1903). Jahrb. Chem. Techn. (1905) part I p. 19. Papier-Ztg. vol. 30 (1905) part II p. 2582. UTILIZATION OF WASTE-SULPHITE LIQUOR. Mechanical disintegration after cooling of the binding material obtained by Trainer's method. Papier-Fabr. vol. 3 (1905) p. 1557. Gewerkschaft Eduard. ZELLPECH (CELL-PITCH). Manufacture, use, and sale of binding materials for briquettes. Erecting and operating of briquetting plants. Solid and liquid binding materials. Wortschutzregister 13 93426 G. 6103 (1905). Elb, M. BRIQUETTING MATERIAL FROM SULPHITE LIQUOR. The adhesive substance prepared according to German Patent 166947 (1905) is now used for a briquetting material. By heating the briquettes they may be made insoluble in water. German Patent 173686 (1905). Papier-Ztg. vol. 31 (1906) part II p. 3180. Chem. Zentr. (1906) part II p. 924. (See " Gums, Adhesives, and Sizing Materials " p. 68.) Tavernier, A. E. and Oulman C. UTILIZATION OOF WASTE CELLULOSE LYES. Waste cellulose lyes from paper manufacture are treated with sulphuric acid and concentrated to a syrupy consistency, then well mixed with about 20 parts of the previously ground and sifted fuel. The mixture is heated for 10 minutes with direct steam, then formed into a paste and pressed in a briquette press under pressure of 220 kilogrammes per sq. cm. (3,130 Ib. per sq. in.) The briquettes are dried in a chamber built of bricks and covered with red lead. Vapours of hydrochloric acid are passed through the chamber. By the action of the acid the cellulose is transformed into carbon and thus made insoluble. The hydrochloric acid vapours are received in water and used again. French Patent 359239 (1905). German Patent 186775 (1906). Wochbl. Papierfabr. vol. 38 (1907) p. 3048. Chem. Zentr. (1907) part II p. 1276. J. Soc. Chem. Ind. vol. 35 (1906) p. 365. Sachs.-Bankges, Quellmalz and Co. PROCESS FOR MANUFACTURING WEA- THER-RESISTANT BRIQUETTES WITH WATER-SOLUBLE BIND- ING MATERIAL. The finished briquettes are heated to a temperature that will carbonize or coke the binding material without changing the briquetting material appreciably. German Patent 158497 (1906). 56 FORESTRY BRANCH BULLETIN No. 66 Sachs.-Bankges, Quellmalz & Co. PROCESS FOE MANUFACTURING BRI- QUETTES. In using gas coal it is heated separately before briquetting at a temperature a little above that required for the coking of the binding material, so that the volatile gases may be removed. German Patent 186652 (1907). Addition to German Patent 158497 (1906). Sachs -Bankges, Quellmalz & Co. PROCESS FOR INCREASING THE WEA- THER-RESISTING QUALITIES OF BRIQUETTES. Chromium compounds and, finally, aluminium sulphate are added to the waste sulphite liquor. UTILIZATION OF WASTE SULPHITE LIQUOR. The use of waste liquor for making cores according to patents by A. Bastian and M. Elb. One thousand kilogrammes (2,204 Ib.) of sand requires 5 kilogrammes (11 Ib.) of concentrated liquor. Papier-Fabr. vol. 4 (1906) p. 3128. Wagner, B. PREPARATION OF A BRIQUETTING MATERIAL. The best temperature of the liquor for briquetting is 60, with the substance to be briquetted at 140. The whole mixture is then compressed at a temperature of 100. German Patent 188428 (1906). Papier-Ztg. vol. 32 (1907) part II p. 3356. Wochbl. Papierfahr. vol. 38 (1907) ip. 3579. Jahrb. Chem. Techn. (1907) part I p. 10. Kumpfmiller, A. PROCESS FOR BRIQUETTING BY MEANS OF SULPHITE LIQUOR. Sawdust is mixed with unconcentrated sulphite liquor, dried and shaped under heavy pressure. German Patent 189177 (1904). ('See German Patient 195286, 199279, 176722, Presses for bulky substance.) Papier-Ztg. vol. 32 (1907) part II p. 3356. Chem. Zentr. (1908) p. 1118. Wochbl. Papierfabr. vol. 38 (1907) p. 3049. Jahrb. Chem. Techn. (1907) part I p. 8. Gewerkschaft, Eduard. PROCESS FOR ALLAYING BUST. 1. Streets are sprinkled with sulphite liquor after the liquor has been heated with acids. 2. Same as (1) except that the sulphite liquor is treated with aldehydes instead of acids. 3. As in (1) but the liquor after treatment as in (1) or (2) is mixed with tar. German Patent 200210 (1907). Chem.-Ztg. vol. 32 (1908) Rep. p. 478. Papier-Ztg. vol. 33 (1908) part II p. 2014. Kumpfmiller, A. PROCESS FOR PURIFICATION OF WASTE SULPHITE LIQUOR. Austrian Patent 40657 (1906). (See " Miscellaneous " p. 168.) Gewerkschaft, Eduard. BINDING MATERIAL IN FORM OF POWDER MANUFACTURED FROM WASTE LIQUOR. Swedish Patent 23464 (1906). Chem.-Ztg. vol. 32 (1908) Eep. p. 82. BINDING MATERIAL FROM WASTE SULPHITE LIQUOR 57 Robeson. J, S. PYRITES BRIQUETTES. Non-hygroscopic briquettes are made from fine pyrites and highly concentrated waste liquor. The briquettes give the same yield of SO 2 as the pyrites. United States Patent 1013614 (1912). German Patent 238119 (1907). Papier-Ztg. vol. 38 (1913) p. 1221. Chem. Abs. vol. 6 (1912) pp. 591, 1592. Sembritzki, W. CELL-PITCH FROM WASTE LIQUOR. At Walsum on the Rhine the hot sulphite liquors discharged from the digesters flow through cooled lead pipes into an acid-proof reservoir. Thence the liquor is pump- ed into wooden vats in which it is neutralized with lime; it is filtered through coke, heated to about 97 C., by passage through an economizer, and concentrated to a den- sity of 3*5 Be., in an evaporator. Much of this syrup is exported to England for use as a binder for moulds in foundries. The rest is evaporated to dryness by means of revolving steam-heated drums, from which the pitch, containing 90 per cent of dry substance, is moulded into blocks of about 1 cwt. (112 Ib.) each. The pitch has the appearance of black, opaque rosin, but is readily soluble in water. The yield of pitch is 10 per cent of the liquors, and a ton of coal is required to make a ton of pitch. This cell-pitch is used for briquetting blast-furnace dust, hitherto a waste product, although containing about 40 per cent of iron. The dry dust is mixed with ground cell-pitch and the mixture is treated in a mixer with superheated steam at a temperature of 350- 420 C. The mixture, which must not be so moist as to become sticky, is then pressed into bricks weighing about 3> kilogrammes (6'-6 Ib.) ; the proportion of pitch is 4-5 per cent. The bricks do not lose their shape in the blast-furnace at a temper- ature of 1600 C. since the pitch does not volatilize at a high temperature, but only cokes. The price of the pitch is 50 marks per metric ton ($10.88 per short ton). Cell- pitch may also be used for briquetting coal-dust; it is also employed as a filling mate- rial, for the preparation of a cheap, black dyestuff for cotton fabrics, and for impreg- nating sail-cloths and ropes. The crude waste liquors are valued at 5 pfennigs per metric ton ($0.01 per short ton) and the author states that a profitable means of dis- posing of these wastes has not been found. Wochbl. Papierfabr. vol. 39 (1908) pp. 658,2866. Chem.-Ztg. vol. 32 (1908) Eep. p. 221. J. .Soc. Chem. Ind. vol. 27 (1908) pp. 466, 916 Papier-Ztg. vol. 33 (1908) p. 872. Chem. Abs. vol. 2 (1908) pp. 484, 1885, 3463. Pulp Paper Mag. Can. vol. 6 (1908) p. 257. Kayser, H. EVAPORATION OF WASTE SULPHITE LIQUOR. The author doubts that the cell-pitch from all mills can be utilized, and announces a new method for separating water from the residue of waste liquors. Wochbl. Papierfabr. vol. 39 (1908) p. 2201. Knoesel, Th. PREPARATION OF CELL-PITCH. Discussion of Sembritzki's statements. Effect of the lime content of cell-pitch in the blast furnace. Wochbl. Papierfabr. vol. 39 (1908) p. 3276, vol. 40 (1909) p. 4049. Chem. Abs. vol. 3 (1909) pp. 484, 1083. Gewerkschaft, Eduard. PROCESS FOR BRIQUETTING WITH CONCENT- RATED WASTE SULPHITE LIQUOR. To the mixture of liquor and briquetting material and acid (10-15 per cent H 2 SO 4 ) or an acid compound is added, and this mixture heated to gelatinization. The briquettes are then dried below 200 C. Besides the acid, aldehydes may also be added. German Patent 246289 (1908). 58 FORESTRY BRANCH BULLETIN No. 66 Gtewerkschaft, Eduard.-PROCESS FOR BRIQUETTING The gelatinization is accelerated by adding to the liquor substances such as tar, tar-products or asphalt. German Patent 252439 (1908) (addition to German Patent 246289 (1908). Z angew Chem. vol. 25 (1912) p. 2359. Chem. Abs. vol. 7 .( 191) p. 416. WASTE SULPHITE LIQUOR AS KO AD-BINDER. Concentrated waste liquor is valued at 12 marks, per 1000 kilogrammes ($2.60 per short ton) in Silesia. Rogers Pulp-mills in Au Sable Forks, N.Y., produce road- binder and obtain 15 cents a gallon. Paper Trade J. vol. 49 (1909) p. 44. Papier-Ztg. vol. 35 (1910) p. 1589. TRANSPORTATION OF CONCENTRATED WASTE LIQUOR IN TANK CARS. Z. angew. Chem. vol. 23 (1910) p. 1216. Papier-Ztg. vol. 35 (1910) pp. 451, 2077. Papier-Fabr. vol. 8 (1910) p. 820. Opitz and Kay ser. CELL-PITCH FROM WASTE LIQUORS. Evaporation by use of superheated water under pressure. WochM. PapierfiabT. vol. 39 (1908) p. 1299. Mailer, M. EVAPORATION OF WASTE LIQUORS. Discussion of Opitz's and Kayser>s statements Wochbl. Papierfaibr. vol. 39 (1908) p. 1484. WASTE SULPHITE LIQUOR AS ROAD-BINDER. Experiments in Breslau and Czulow. Papier-Ztg. vol. 34 (1909) part II p. 4018. Papier-Fabr. vol. 7 (1909) pp. 143, 172. Badermann, G. GERMAN RAILWAY TRANSPORTATION OF SULPHITE LIQUOR. The German railway authorities have decided to recommend that concentrated waste lyes from the manufacture of sulphite wood-pulp be included among- the sub- stances suitable for transportation in tank ears. This concession has been made at the instance of the Pionier factory at Wals 28-3 31-6 59-9 0-1 40-0 io-6 6-7 Norego 27o 24-21 20-42 44-63 0-0 55-37 2-91 *) Hansa is mixed with gam bier. 2 ) The proportion between tanning and non-tanning substances show that the extract is. mixed to a large extent with other vegetable extract. The sugar content also indicated this. 3 ) Hocklingsen analysed by the shaking method, the others by the filter method. The analysis of Hansa is given by the firm. 4 ) The sugar tested in a sample by H. Landmark. 5 ) The high sugar content originates with some colouring substances which are not precipitated by ead acetate. 6 )The proportion between tannins and non-tannins proves that the extract is not pure sulphite extract but ts mixed with other extract. Mitscherlich, A. PROCESS FOR THE PREPARATION OF TANNIN FROM OAK. Claims. The process described for the extraction of tannin from oak depends on the use of calcium sulphite as the extracting agent. German Patent 4178 (1878). Saxon Patent 3912 (1875). TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 81 Mitscherlich, A. INNOVATIONS IN THE PROCESS OF PRODUCING TAN- NING MATERIALS WITH THE PRODUCTION OF THE BY-PRO- DUCTS, CELLULOSE, GUMS, ACETIC ACID, AND CALCIUM BI- SULPHITE. (a) Claims. 1. The preparation of tannin, adhesives, and a fermentable liquid through treatment of the wood with a solution of calcium sulphite at a temperature of over 108, as well as the simultaneous production of cellulose and acetic acid as by- products of this process. 2. The preparation of a solution of calcium bisulphite by further use of the sul- phur dioxide, which is driven off. 3. The direct application of the sulphurous acid liquid or the evaporated material or the decomposed calcium tannate as a tanning material. Importance is attached to the advantageous action of the sulphurous acid. (b) Claims. The preparation of tannin substance by treating wood with the solu- tion of the calcium salt at a temperature of over 108, as well as simultaneous produc- tion of acetic acid as a by-product in this process. German Patent 4179 (1878). (Addition to German Patent 4178). Addition to the process for producing tannin by using the by-products. Ber. vol. 12 (1879) p. 396. Kirchner, Zellulosefabrikation (1907) pp. 23, 25. Mitscherlich, A. COOKING OF WOOD WITH CALCIUM BISULPHITE, RE- COVERING CELLULOSE, TANNING MATERIALS, GUMS, ACETIC ACID. English Patent 1668 (1882). J. Soc. Chem. Ind. vol. 2 (1883) p. 700. Pictet, K. P. and Brelaz, G. H. IMPROVEMENTS IN SULPHITE WOOD-PULP. Cooking of wood with supersaturated solutions of sulphurous acid gas at a tem- perature below 100 C. in order to avoid the decomposition of the resinous and other encrusting matters in the wood. Recovering of SO 2 and preparation of gums, resin, tannin, alcohol, etc., from the waste liquor. English Patent 9509 (1884). J. Soc. Chem. Ind. vol. 4 (1885) p. 464. W. (Anonymous) WASTE SULPHITE LIQUOR. Description of the methods given by Hammer, Lowenthal, Councler, and Schrader, for determination of tanning acid. Analysis of liquors by these methods made the pre- sence of tannin seem probable. Papier-Ztg. vol. 16 (1916) pp. 1446, 1447. Mitscherlich, A. PROCESS FOR UTILIZING THE LYES OF SULPHITE-CEL- LULOSE PRODUCTS OBTAINED IN SUCH PROCESS AND APPAR- ATUS EMPLOYED FOR THAT PURPOSE. The inventor claims a separation of the constituents of the lye of sulphite cellu- lose by osmose, in a special apparatus, and utilizes such constituents for a tanning material and a cementation material. He also obtains alcohol by fermenting a certain portion of the liquor and, further, obtains food for animals. German Patent 72161 (1891). English Patent 12927 (1893). Ber. vol. 27 (1894) p. 149. Papier-Ztg. vol. 18 (1893) p. 3222. J. Soc. Chem. Ind. vol. 13 (1894) p. 834. Opl. C. PREPARATION OF SULPHITE-CELLULOSE LIQUORS FOR TAN- NING PURPOSES. The crude sulphite-cellulose liquors are treated with caustic lime for the removal of calcium bisulphite, normal calcium sulphite being precipitated; or the SO 2 is liber- 491206 82 FORESTRY BRANCH BULLETIN No. 66 ated by the addition of sulphuric or hydrochloric acid and then expelled from the liquors by steam. In the liquors thus purified, metallic tannates, soluble in water, are formed by the addition of metallic sulphates such as aluminium sulphate, alum or ferrous sulphate, whilst calcium sulphate is precipitated. The solutions of metallic tannates thus obtained possess, it is stated, tanning powers which it is proposed to apply in the tannery. German Patent 76351 (1893). J. Soc. Chem. Ind. vol. 14 (1895) p. 976. Mitscherlich, A. PROCESS AND APPARATUS FOR UTILIZATION OF WASTE SULPHITE LIQUOR. Austrian Privilegium 112 (1894). (See "Gums, Adhesives, and Sizing Materials" p. 68.) Blackinan, B. UTILIZATION OF LIQUOR. The liquor is blown into large chambers which are evacuated. The free S02 is drawn off with a vacuum pump and used again. The last amounts are obtained by heating the liquids. The liquor is then worked up for use as a tanning material. United 'States Patents 369836, 369530, 369634, 530635 (1895). Papier-Ztg. vol. 20 (1895) part I p. 1376, part II p. 2152. Ekman, C. D. WASTE SULPHITE LIQUOR. Review of methods for utilization. Mitscherlich method for using the waste liquor for tanning hides has had no success, due to the absence of tanning material in the liquor. Papier-Ztg. vol. 21 (1896) part I pp. 2218, 2609, 3247. J. Soc. Chem. Ind. vol. 15 (1896) p. 735. Mitscherlich, A REPLY TO EKMAN'S REMARKS ON SULPHITE LIQUOR. Preparation of tannin "Gerbleim" and "dextrine" are considered. Papier-Ztg. vol. 21 (1896) pp. 2349, 2850. Honig, M TANNIN EXTRACT FROM WASTE SULPHITE LIQUORS. The lyes are neutralized with calcium carbonate or lime and the clear solution concentrated to 15 -18 Be. They are then heated with sufficient sulphuric acid to combine with the lime present in the lye. After being concentrated up to 28-30Be. in a vacuum pan, and clarified, the solution may be used as a tannin extract. English Patent 18265 (1896). J. Soc. Chem. Ind. vol. 15 (1896) p. 819. Kempe, D PRODUCTION OF TANNINS. The liquor is boiled with lime under pressure, is filtered, and the filtrate worked up into tannins by heating under high pressure with sulphates of the heavy metals. Austrian Privilegium 3962 (1897). Swedish Patent 8422 (1897). Chem.-Ztg. vol. 22 (1898) p. 26. Ziegler, A. TANNING BY MEANS OF ALTERNATE TREATMENT WITH SULPHITE LIQUOR AND METALLIC SALTS. The hide is first treated with sulphite liquor and then treated with a solution of an alkali chromate or an aqueous solution of a salt of Al, Fe, Cu, or Cr. The leather obtained by this treatment is better than that by mineral tannage alone. German Patent 105669 (1897). Chem.-Ztg. vol. 25 (1900) part I p. 154. TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 83 Honig, M. TANNIN EXTEACT FROM WASTE SULPHITE LIQUOR. After precipitation of the lime, volatile gases are driven off with steam, and the liquor is then evaporated in vacuo. Russian Privilegium 953 (1898). Chem.-Ztg. vol. 23 (1898) p. 319. Honig, M. TANNING EXTRACT FROM SULPHITE LIQUOR. Zinc dust and sufficient H2 SO4 to liberate the combined sulphurous and acetic acids are added to the liquor, which have the effect of decolorizing the liquor. After partial evaporation the liquor so treated can be used as a tanning extract. German Patent 132224 (1901). United States Patent 727798 (1903). Austrian Patent 7325 (1901). Papier-Ztg. vol. 27 (1902) part II p. 2162. Chem. Zentr. (1902) part II p. 174. J. Soc. Chem. Ind. vol. 22 (1903) p. 763. Honig, M. PREPARATION OF A TANNING EXTRACT. The liquor is run into a battery of vessels provided with stirrers. These vessels are so arranged that each of them can be put into connection with the liquor reservoir and can also be emptied. The underlying idea is to prepare an extract such that the tannins and non-tannins are in such a relation as has been shown to be best in practice, i.e. 100 tannin to 85 non-tannin. In the liquor treated according to German Patent 132224 (1901) the ratio is 100-110. Accordingly extracts are added which are low in non-tannins, e.g. quebracho, mimosa, myrobalans. Quebracho is especially suitable on account of its cheapness and its ratio of 100 tannins to 8 non-tannins. For 100 kilo- grammes of quebracho wood 1-67 cubic metres of liquor 6 Be are used for extracting the tannin from the wood. German Patent 152236. Austrian Patent 12970 (1902). Papier-Ztg. vol. 29 (1903) part II p. 2226. Jahrb. Chem. Techn. (1904) part II p. 514. Karr, 0. TANNING MATERIAL AND PULP FROM CHESTNUT, OAK AND SIMILAR TANNIN-CONTAINING WOODS. United States Patent 762139. Papier-Ztg. vol. 29 (1904) part II p. 2726. Kumpfmiller, A. PURIFICATION OF SULPHITE LIQUOR. The hot liquor is evaporated in vacuo to 25 Be., with rapid stirring. The acids harmful to leather are volatilized, and CaSOs is precipitated. This is filtered off. The lime still remaining is precipitated with oxalic acid. An excess of oxalic acid does no harm. The liquor is again filtered. This filtrate is rich in tanning and filling organic substances. No organic substance is precipitated by this method. The extract while having a higher specific gravity than tanning extracts has a lower viscosity. It is easily soluble in water ; it is not decomposed in the pit ; the pores of the skin are not clogged up. It can be mixed readily with other extracts. German Patent 183415 (1905). Jahrb. Chem. Techn. (1907) part II p. 503. Chem. Zentr. (1907) part II p. 109. Wochbl. Papierfabr. vol. 38 (1907) p. 1402. Papier-Ztg. vol. 32 (1907) part I p. 2046. Chem.-Ztg. vol. 31 (1907) Rep. p. 243. Kumpfmiller, A. The liquor is first warmed and then sprayed continuously or intermittently into a chamber" in which a strong vacuum is maintained. It is stated that the sulphur dioxide escapes from the small particles of liquor almost instantaneously and that the 84 FORESTRY BRANCH BULLETIN No. 66 whole of the dissolved calcium sulphite separates, whilst the liquor itself is not dis- coloured. German Patent 203648 (1906). Chem. Zentr. (1908) part II p. 1834. Papier-Ztg. vol. 33 (1908) part II p. 3564. Chem.-Ztg. vol. 32 (1908) p. 1036. Wochbl. Papierfabr. vol. 40 (1909) p. 260. J. Soc. Chem. Ind. vol. 27 (1908) p. 1174. Chem. Abs. vol. 3 (1909) p. 714. Honig, M PROCESS FOR MANUFACTURE OF TANNIN EXTRACT. The waste liquor is treated with zinc dust and sulphuric acid or a stronger acid (Patent 7325), and before concentration in vacuo is filtered through a tannin-con- taining material or cooked with such a material. Austrian Patent 31862 (1906) '(Addition to Austrian Patent 7325). Kumpfmiller, A. PURIFICATION OF WASTE SULPHITE LIQUOR. Austrian Patent 40657 (1906). German Patent 183415 (1905). (See " Miscellaneous " p. 168.) Paeszler. METHOD FOR IDENTIFICATION OF VARIOUS KINDS OF TAN- NING MATERIAL AND TANNIN EXTRACTS. It is desirable to find a method for identification of tannin extract from waste liquor in tannin extracts. Sulphite liquor extract alone is not regarded as a tanning material but only as a substitute for other extracts, and can very well be used in mix- ture with other extracts. Chem.-Ztg. vol. 30 (1906) part II p. 1000. Philippi, W. H UTILIZATION OF SULPHITE LIQUOR FOR TANNING. The warm liquor from the digester is treated in the following proportions : 1 litre of the liquor is heated with sodium carbonate until the reaction is alkaline; usually 20-30 grammes are necessary. Twenty to thirty grammes of alum are now added and the liquor is filtered. The filtrate is used for tanning. It tans quickly and intensively. The hides are also preferably subjected to the action of dilute hydrochloric acid, either after or during the tanning process, in order to improve their colour. German Patent 195643 (1904) and 211348 (1905). French Patent 369608 (1906). Chem. Zentr. (1908) part II p. 1232 (1909) part II p. 400. Papier-Ztg. vol. 33 (1908) part I p. 1210, vol. 34 (1909) part II p. 2294. Jahrb. Chem. Techn. (1908) part II p. 557. J. Soc. Chem. Ind. vol. 26 (1907) p. 106. Chem. Abs. vol. 3 (1909) p. 2640. Kumpfrniller, A. PURIFICATION OF SULPHITE LIQUOR. According to the chief patent, after removal of most of the sulphurous acid by evaporation and separation of the calcium sulphite the remainder of the lime was precipitated by addition of oxalic acid. According to the present patent, their residual lime is converted by addition of a suitable acid. e.g. lactic acid, into a calcium salt which has no injurious action in the process in which the sulphite liquor is to be subsequently used. German Patent 194872 (1906) Addition to German Patent 183415. Chem. Zentr. (1908) part I p. 1118. Papier-Ztg. vol. 33 (1908) part I p 896. Chem.-Ztg. vol. 32 (1908) Rep. p. 256. Wochbl. Papierfabr. vol. 39 (1908) p. 1306. J. Soc. Chem. Ind. vol. 27 (1908) p. 562. TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 85 Kumpfmiller, A. PURIFICATION OF SULPHITE LYES FOE TANNING. The lye is first freed from the main portion of the sulphurous acid and calcium sulphite it contains by heating or by treatment in vacuo. It is then treated with ozone, whereby the remainder of the sulphurous acid and calcium sulphite are con- verted into sulphuric acid and calcium sulphate respectively, the greater portion of the latter separating out. On now adding barium carbonate the dissolved sulphuric acid and sulphate are precipitated. The liquor thus purified is suitable for use as a tanning and filling for hides. German Patent 207776 (1906). P/apier-Fabr. vol. 7 (1909) part I p. 293. Papier-Ztg. vol. 32 (1907) part I p. 986. J. Soc. Chem. Ind. vol. 28 (1909) p. 484. Chem. Abs. vol. 3 (1909) p. 2072. Kumpfmiller, A PURIFICATION OF WASTE SULPHITE LIQUOR. The waste liquors from the manufacture of sulphite cellulose are freed from sulphurous acid and calcium sulphite by evaporation in a vacuum apparatus, and are then treated with a solution of alum. The precipitate produced is separated. The solution thus obtained is suitable for use as a filling material in tanning and leather dyeing. German Patent 216284 (1907). J. Soc. Chem. Ind. vol. 28 (1909) p. 1324. Chem.-Ztg. vol. 33 (1909) Rep. p. 627. Papier-Ztg. vol. 34 (1909) part II p. 3716. Chem. Abs. vol. 4 (1910) p. 1114. Stewart, D PROCESS FOR MANUFACTURING TANNIN DYES AND EXTRACTS. Waste sulphite liquor with less than 6 per cent iron (as found in the ash) is used. The liquor is percolated with tannin-containing materials and after removal of precipi- tate evaporated in vacuo. Austrian Patent 40528 (1907). United States Patent 909343 (1900). Chem.-Ztg. vol. 33 (1909) Rep. p. 176. Little, A. D PROGRESS IN THE MANUFACTURE OF SULPHITE PULP IN 1906. [^ (-See " General " p. 185.) Tillberg, E. W PROCESS FOR OBTAINING TANNINS, ALCOHOL, AND CELLULOSE FROM WOOD. Swedish Patent 25283 (1907). Johnson, J. Y. (From J. S. Robeson). PREPARATION OF A TANNING MA- TERIAL FROM WASTE SULPHITE LIQUOR. The new product consists of a soluble compound of the sesquioxide of chromium and aluminium with the practically unchanged organic matters of sulphite cellulose liquor, and is prepared by treating the liquor with aluminium and chromium sesqui- oxide and an acid capable of precipitating mineral matter from such liquor and remov- ing the precipitate thus formed. After standing some time, the liquor deposits a second precipitate of sulphur, which is also removed. The solution is then concentrated or evaporated to dryness. The product is stated to be useful as a tanning material. English Patent 17956 (1908). United States Patent 851378-851381 (1909). Austrian Patent 42479 (1909). Chem.-Ztg. vol. 31 (1907) Rep. p. 312. Papier-Ztg. vol. 35 (1910) p, 300. J. Soc. Chem. Ind. vol. 28 (1909) p. 1050. 86 FORESTRY BRANCH BULLETIN No. 66 Eobeson, J. S. TREATMENT OF HIDES AND SKINS- The processes consist of: (1) the treatment of hides or skins with a tanning agent, followed by a bath containing sulphite liquor (see preceding abstracts), and finally bleaching with an acid or other bleaching agent; (2) the tannage of hides or skins by means of sulphite liquors and bleaching with an acid or other material ; and (3) tanning the hides or skins in sulphite liquors and .subsequently bleaching by the use of sulphuric acid and a salt which reacts with the acid to effect the bleaching. English Patent 17958 (1908). J. Soc. Chem. Ind. vol. 28 (1909) p. 1052. Johnson, J. Y. (From J. S. Kobeson) .TANNING HIDES AND SKINS. The method consists of treating the hides and skins, in successive baths of in- creased concentration, with a liquor containing a compound of the sesquioxide of aluminium or other base with the practically unchanged organic matters of waste sul- phite liquors (see preceding abstract). The tannage can be completed in this liquor or it can be finished by any of the ordinary tanning processes. The patent also covers the treatment of cotton, wool, and other fibrous materials with the same liquor. English Patent 17957 (1908). J. Soc. Chem. Ind. vol. 28 (1909) p. 1052. Teas, W. H. TREATMENT OF PARTIALLY-TANNED LEATHER}, ,WITH SULPHITE LIQUOR. The claims are for a process of filling leather consisting in treating the .partially tanned product with waste sulphite cellulose lyes which have been concentrated till they have the specific gravity 1-10-1 -35, the liquor being agitated during the treatment. United States Patent 916057 (1909). J. >Soc. Chem. Ind. vol. 28 -(1909) p. 432. PURIFICATION OF WASTE LIQUOR. Discussion of Kumpfmiller's process for preparation of tannin extract. Papier-Fabr. vol. 7 (1909) p. 293. Procter, H. E., and Hirst, S. DETECTION OF SULPHITE-CELLULOSE LIQUORS IN TANNING EXTRACTS. If attempts are made to tan with this .extract alone it is difficult, if not impossi- ble, to obtain a product which deserves the name of leather, the surface being apparent- ly tanned while the interior remains raw and unaltered, and the hide dries horny and usually has an unsatisfactory colour. If, however, the hide be in the first instance partially tanned with some ordinary tanning material or if some other tanning extract be used in conjunction with the "pinewood extract", leathers are produced similar in appearance to those of ordinary tannages, as the "pinewood extract", appears capable of absorption, giving firmness and weight, although it probably contains no bodies analogous to the ordinary tannins. It may, therefore, ultimately become a useful addition to the tanner's resources, but while experiments with it were at first apparently successful as a weighing and solidifying tan, some constituent appeared to accumulate in the liquors which led ultimately to the production of brittle or tender leather. Whether this was due to mismanagement the writers can- not at the moment say, but so far as they are aware but little of the extract has been sold to tanners under its own name. It is, however, obviously a tempting material for the extract manufacturer, as considerable quantities can be added to tanning extracts without altering their appearance, and it shows a good percentage of tanning strength by ordinary method of analysis. It is therefore important in the interests of the tanner that means should be discovered for the detection and, if possible, the estima- tion of "pinewood extract" in the mixture, and a good deal of time has been devoted by the writers to the attempts to discover a satisfactory qualitative colour reaction, TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 87 and it has been found that the following modification of the ordinary test for lignin with aniline and hydrochloric acid is very delicate and quite satisfactory. It was also found that the "tanning 1 substance" of the "pinewood", while it was estimated as tannin by the ordinary hide-powder process, was only to a very small extent capable of reducing, permanganate in the Lowenthal method, and therefore gave almost negative results in tanning, a "ipinewood extract" showing about 25 per cent of mat- ters absorbed by the hide being only equivalent by the Lowenthal method to about 4 per cent of gallotannic acid. This property of low oxidizability is not shared to nearly an equivalent extent by any ordinary tanning material, and, therefore, "pinewood extract" can be detected and even estimated approximately if present in considerable quantity, by comparison of the gravimetric and Lowenthal results. J. Soc. Chem. Ind. vol. 28 (1009) p. 293. Z. angew. Chem. vol. 32 (1909) p. 1566. Chem. Abs. vol. 3 (1909) p. 2395. Honig, M. TANNIN EXTRACT FROM WASTE SULPHITE LIQUOR. French Patent 413849 (1910). Austrian Patent Application 3325 (1909). Hungarian Patent Application 3806 (1910). Chem.-Ztg. vol. 34 (1910) Rep. p. 251. Z. angew. Chem. vol. 23 (1910)) p. 499. J. 'Soc. Chem. Ind. vol. 29 (1910) p. 1121. - ,XA 4T:r ;H ^^'Sfr* SULPHITE-CELLULOSE LIQUORS FOR TANNING. Procter and Hirst's statements on "pinewood extract" are criticized as being based upon a superficial study of the subject. The defects in the leather they examined were probably due to lime. A cellulose extract properly freed from lime when used in combination, especially with natural quebracho, gives good leather. Ledertechn. Rundschau, vol. 1 (1909) p. 361. Chem. Abs. vol. 4 (1910) p. 3150. Kumpfmiller, A. TANNING COMPOSITION FROM WASTE SULPHITE LIQUOR. The liquor is heated, poured into a vacuum chamber to free it from SO2, concent- rated and filtered to remove the precipitated OaSOs, treated with Na2COs to convert Ca (HSO3)2 into CaSOs and Oa salts of organic acids into Na salts, filtered, treated with HC1, and combined with a fresh, vegetable, tannin-containing extract, as que- bracho or mangrove extract, and a colouring material, as "leather-yellow". United States Patent 939394 (1909). Chem. Abs. vol. 4 (1910) p. 927. Kumpfmiller, A. PREPARATION OF TANNIN EXTRACT. The lime in the concentrated liquor is precipitated with soda. The filtrate is treated with hydrochloric acid, further concentrated, and mixed with quebracho extract. United States Patent 040394 (1909). Papier-Ztg. vol. 35 (1910) p. 300. Chem.-Ztg. vol. 33 (1909) iRep. p. 648. Philippi, W. H WASTE SULPHITE LIQUOR FOR TANNING. Austrian Patent Application 1821 (1909). Chem.-Ztg. vol. 33 '(1909) Rep. p. 447. Honig, M. TANNING EXTRACT FROM SULPHITE LYES. The lye as obtained from the treatment of cellulose with calcium bisulphite is analysed; from the analysis is calculated the quantity of sulphuric acid necessary to decompose the esters and salts of sulphurous acid which are present and to partly 88 FORESTRY BRANCH BULLETIN No. 66 liberate the sulphonic acids of lignin, present largely as calcium salts. After the addition of the sulphuric acid the solution is filtered through tanning material to remove iron, and then concentrated. French Patent 41384)9 (1910). J. Soc. Chem. Ind. vol. 29 (1910) p. 1121. Kumpfmiller, A. THE UTILIZATION OF WASTE SULPHITE LIQUOR IN THE TANNING INDUSTRY. Discussion on evaporation of waste liquor, purification and preparation of " sul- phite extract ". Difficulties in the manufacturing operation, and dangers in using lower grades of extracts. On the other hand there are advantages in using a mixture of good sulphite extract with quebracho extract. Report on Annual Meeting of German Pulp and Paper Chemists 1910 p. 57. Honig, M. EXTRACT FOR USE IN TANNING. The liquor is mixed with an acid (such as H2 SOi forming an insoluble lime salt together with salts of such an acid in such proportion as appears necessary for freeing a portion of the ligninsulphonic acid and for converting the remaining lime salts into other readily soluble salts. Thereupon the product is filtered, if necessary, through a tanning material which forms insoluble compounds with iron, for the purpose of imparting to the final product certain definite tanning properties through the addition of a given proportion of sulphonic acids in free and combined state. English Patent 7066 '(1910). Chem. Abs. vol. 5 (1911) p. 2989. . ^ Kumpfmiller, A. UTILIZATION OF SULPHITE LYES FOR TANNING. According to the process described by the author the lyes are violently agitated whilst boiling, in order to eliminate a portion of the sulphuric acid. Sodium carbonate is then added and the sodium sulphite formed is converted into chloride by hydro- chloric acid; lastly lactic acid is added, since the calcium lactate is not injurious in tanning. The purified lyes are evaporated in a vacuum circulation apparatus of the type used in the potash industry. It consists of an open boiler from which the lye circulates through a vacuum evaporating apparatus and back again to the boiler. The lyes contain 7-9 per cent of organic solids, including 2-3 per cent of tanning matter. In oak-bark extract the ratio of tanning matters to soluble non-tannins is 3 to 2, whilst in quebracho it is 20 to 1. By blending the wood extract with other tanning materials it is possible to prepare an extract very similar to oak-bark extract. The lyes must be thoroughly purified from lime and sulphurous acid, since these impurities would make the leather brittle and black. "Spruce wood" extract exerts a good mordanting action and yields a pale leather to which it imparts the necessary "handle", whilst the presence of the non-tannins gives body and weight. A combination of chrome and spruce extract tanning promises to become -of very considerable import- ance in the near future. Chem.-Ztg. vol. 34 (1910) p. 1362. J. Soc. Chem. Ind. vol. 30 (1911) p. 19. '"" Chem. Abs. vol. 5 (1911) p. 2944. DETECTION OF WOOD-PULP LIQUOR IN TANNING EXTRACTS. When used alone the "sulphite extract" produces a very inferior leather, but it may be used to adulterate other extracts without causing any decided difference in the appearance of the leather. Procter and Hirst propose the following method of identification of sulphite extract in tanning extracts. When 0.5 c.c. of aniline is added to 5 c.c. of tanning extract a turbid emulsion is produced. In case of unadulterated extracts, the turbidity disappears on addition of 2 c.c. of concentrated HC1. If wood- pulp liquor is present a decided precipitation remains. World's Paper Trade Rev. vol. 56 p. 390. Chem. Abs. vol. 5 (1911) p. 3908. TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 89 Dickerson, W. H. PROCESS FOR THE PRODUCTION OF TANNING AGENTS FROM WASTE SULPHITE LIQUORS. Weakly acid or neutral reagents are used to liberate sulphurous acid from waste sulphite liquors, and tannin from the tannin complexes contained therein, without producing secondary decomposition of the resulting or remaining organic constituents. iFor example, oxalic acid, in the proportion of about one-half of 1 per cent to 1 per cent by weight, is added to undecomposed waste liquor, preferably immediately after its discharge from the digester and either in its untreated state or after free sulphur 1 dioxide and calcium sulphite have been removed by evacuation, or by a stream of an indifferent gas, and preferably without any considerable concentration of the liquor. If complete removal of calcium is desired, sufficient oxalic acid must be added for this purpose. After settlement, the supernatant liquid is decanted off and immediately subjected to reduced pressure or to a stream of an indifferent gas to remove free sul- phur dioxide, and this process may or may not be accompanied by concentration in a vacuum evaporator or otherwise. The liquors thus obtained may be used for leaching tannin-containing materials. English Patent 7438 (1910) J. Soc. Chem. Ind. vol. ,30 (1911) p. 438. Eitner, W. TANNING EXTRACT FROM WASTE SULPHITE LIQUOR. The extracts from waste sulphite liquor placed on the market under the name of " Fichtenholz " (spruce wood), " Excelsior " extract, etc., are very similar with regard to composition. They contain about 23 to 26 per cent of substances which are absorbed by the hide, and about 28 per cent which are not absorbed. The extracts contain no tannin but serve as a filler. They are good solvents for quebracho extracts which are soluble with difficulty due to the presence of free sulphurous acid, but they do not dissolve impure quebracho extracts perfectly. The addition of sulphite extracts accelerates the tanning process ; the extracts serve as filler but they make the leather hard and brittle. Gerber vol. 37 (1911) pp. 227, 241, 256. J. Soc. Chem. Ind. vol. 30 (1911) p. 1269. Platsch, M. PROCESS FOR PURIFICATION OF WASTE SULPHITE LIQUOR BY PRECIPITATING THE INJURIOUS SUBSTANCES WITH CHEMICALS AT HIGH CONCENTRATION OF LIQUOR. The precipitation is carried out after the removal of the acetic acid. In order to remove the sulphur the precipitation is carried out with salts, the bases of which either form no compound or easily decomposed compounds. German Patent Application 26575 (1911). Platsch, M PROCESS FOR PURIFICATION OF WASTE SULPHITE LIQUOR. The lime is precipitated from the concentrated liquor with sulphuric acid, and the excess of acid removed with barium carbonate. German Patent Application 26960 (1911). Landmark, H. B UTILIZATION OF WASTE SULPHITE LIQUOR. The liquor is evaporated with an acid forming insoluble calcium salts until all the lime is precipitated. Starch products are thereby inverted into fermentable sugars. The excess of acid is precipitated in form of an insoluble salt and the filtrate concen- trated. The extracts can be used as an adhesive or tanning material. Norwegian Patent 21848 (1911). Swedish Patent 35500 (1911). Ledertechn. Rundschau vol. 4 (1912) p. 308. Papier-Ztg. vol. 36 (1911) p. 3706, vol. 38 (1913) p. 3063. Chem. Abs. vol. 8 (1914) p. 2278. Paper vol. 13 (1913) No. 11 p. 23. 90 FORESTRY BRANCH BULLETIN No. 66 Loveland, F. M. ANALYSIS OF SULPHITE EXTRACTS. J. Am. Leather Chem. Assoc. vol. 7 .(1912) p. 368. Sindall, R. W. WASTE SULPHITE LIQUOR FOR TANNING PURPOSES. The liquor is treated with aluminium or chromium salts, filtered, and afterwards evaporated to 31-32Be. (specific gravity 1-275-1-285). The extract contains 22 per cent tanning and 32 per cent soluble non-tanning substances, 2 per cent insoluble non- tanning substances, and 4-8 per cent ash. Used alone the extract gives only leather of inferior grade; in mixture with genuine tanning, extracts it is to a certain extent useful. Aniline and hydrochloric acid give with genuine extracts a clear solution, with sulphite extract a precipitate. Paper Makers' Monthly J. vol. 39 (1911) p. 401. Papier-Ztg. vol. 36 (1912) p. 300. Pulp Paper Mag. Can. vol. 10 (1912) p. 50. Claflin, A. A. THE TANNING PROPERTIES OF WASTE SULPHITE LIQUORS. The partly purified liquors were first suggested as a substitute for lactic acid in the tanning industry. This was a failure but it was discovered that the liquors con- tained considerable amounts of material absorbable by hide. The author claims that if the extracts are properly purified they have a distinct property of converting hide into saleable leather. He contradicts Eitner's assertion that the tanning properties are due to zinc sulphite since Amercan extracts do not contain this. J. Am. Leather Chem. Assoc. vol. 7 (1912) p. 164. Z. angew Chem. (1912) p. 1932. Chem. Abs. vol. 6 (1912) p. 1383. Sody, I TANNING EXTRACT FROM SULPHITE LYE. Cellulose extracts when examined by Procter's filter-bell method show from 20 to 30 per cent of tannin and; from 20 to 37 per cent of non-tannins, but with Lowenthal's permanganate method the figure for tannin is only about one-sixth as high. For the detection of cellulose extract in genuine tanning extracts, the author has found the most satisfactory the permanganate titration method and the aniline test recommended by Procter (J. Soc. Chem. Ind.). The loss of tannin, as indicated by the hide-powder method, when cellulose extract is mixed with a tanning extract, is confirmed (See Yocum and Faust). Comparative tanning tests were made with quebracho extract, cellulose extract ,and mixtures of the two, strips of hide being placed in the liquors and standing for some hours, being shaken for 30 hours, then washed and soaked in water for 15 minutes. At this stage all the samples appeared completely tanned, but after smoothing, lightly oiling on the grain and drying, it was found, on examining cut sections, that only the piece treated with quebracho extract had been properly tanned; all the other pieces showed a distinct line in the middle which was more pro- nounced the higher the proportion of cellulose extract employed. Moreover, in pro- portion as the relative amount of non-tannins in the extract was increased by addition of cellulose extract, the "rendement" or yield of leather decreased. The author con- siders that the addition of cellulose extract has a deleterious effect on drum tannage with other extracts. In vat tannage the cellulose extract may give rise to the acids necessary for the plumping of the hides, but through weakening of the liquors may diminish the yield of leather. Cellulose extracts may be used for the retanning of leather in place of extracts such as cutch and gambier, and may advantageously replace glucose and molasses. It is also useful for correcting the disagreeable brown colour imparted to leather by quebracho, mangrove, and divi-divi, but the retanned leather should not be exposed to light during drying, as this darkens the colour. Chem.-Ztg. vol. 37 (1913) p. 442. Collegium (1912) p. 529. J. Am. Leather Chem. Assoc. vol. 7 (1912) p. 373. J. Soc. Chem. Ind. vol. 31 {1912) P- 737. TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 91 Gross, F. F PROCESS FOR PREPARATION OF TANNING EXTRACT FROM WASTE SULPHITE LIQUOR. Hydrochloric acid and sulphuric acid is added to the hot liquor and the rest of the lime precipitated with chromate of potassium. The liquor is concentrated to 20 Be. and cooled under aeration. The precipitates are filtered off and the filtrate further evaporated. German Patent Application G. 38003 (1912). Honig, M PREPARATION OF A TANNING EXTRACT FROM WASTE SUL- PHITE LIQUOR. So much sulphuric or oxalic acid is added that the total ligno-sulphuric acids contained in the liquor are set free and the total lime precipitated. German Patent Application 'H. 56968 Cl. 28a (1912). Austrian Application A. 1611. ((Addition to Patent 43742). Paeszler. TANNING EXTRACTS ADULTERATED WITH CELLULOSE EXTRACT. In the author's experience no leather of any value can be made by the use of cellulose extract alone. In one case, in which the tanning was allowed to proceed for a year, a kind of leather was produced, but its character was unsatisfactory and the gain of weight very small. When cellulose extract is used mixed with other extracts, good leather is obtained but it is difficult to see whether the action is due to the other materials alone or whether the cellulose extract plays any part. It is quite possible that the latter may have certain tanning properties of its own when mixed with other extracts. Procter and Hirst's lignin test gives a negative result with an extract made by treating quebracho wood for 12 hours at 2 atmospheres pressure without bisulphite or for 5 hours at 2 atmospheres pressure with 4 per cent of bisulphite. When the latter treatment is carried out at 6 atmospheres pressure a positive result is obtained bu)t these conditions are never present in manufacturing. In the discussion it is stated that abnormal results were obtained in the examination of oak-wood extract when bad or spoiled wood had been used for its manufacture. Large quantities of cellulose extract are used in leather manufacture in England. A marketable leather can be produced by using a mixture of mangrove and cellulose extract in the proportion of 2 to 1. Chem.-Ztg. vol. 36 (1912) p. 812. J. iSoc. Chem. Ind. vol. 31 (1912) p. 736. Paeszler. THE SUGAR CONTENT OF VEGETABLE TANNING MATERIALS AND TANNING EXTRACTS. Ledertechn. Rundschau, vol. 4 (1912) No. 46-48. Deut. Gerber Ztg. (1912) No. 05. Collegium (1913,) p. 88. Bennett, H. G. WOOD-PULP AND TANNING EXTRACTS. The by-products from the pulp manufacture sold as vegetable tanning agents apparently contain a considerable amount of tannin when analysed by the official methods. However these so-called "pinewood" or "spruce" extracts answer only a part of the tests for tannin and do not contain true tannic acid. Tests proving this are mentioned. Also, tests for sulphite extract are given. The author has been discouraged by attempts, which he has seen, to make leather by using wood-pulp extracts. The product has a surface apparently tanned while the interior is unaltered and the hide is horny and not satisfactory in colour. Hides partially tanned with some ordinary tanning extract are similar in appearance to leathers of ordinary tannages. Evidently wood-pulp extracts are of use only in adding weight and as such have their risks. Shoe and Leather Rep. vol. 104 (1912) No. 3, p. 31. Chern. Abs. vol. 6. (1912) p. 3383 92 FORESTRY BRANCH BULLETIN No. 66 Chemische Industrie-und Handels-Ges. M. H.-TANNING PROCESS WITH WASTE SULPHITE LYES. In the use of waste sulphite lyes for tanning, claim is made for the addition of glycerin as well as of chromium compounds. The chromium compounds diminish the solubility of some of the organic constituents of the liquors, and hence prevent to some extent their removal from the hide by washing. By the addition of glycerin, the possibility of concentrating the liquors to the desired extent whilst still maintain- ing them in the liquid state is achieved. German Patent 248056 (1910). J. Soc. Chem. Ind. vol. 31 (1912) p. 999. Philippi, W. H TANNING EXTRACT FROM SULPHITE LYES. The claim is for the addition of chromium hydroxide to the extract for the purpose of neutralizing any acid liberated during the tanning process. German Patent 254866 (1910). French Patent 448064 (1912). Papier-Fabr. vol. 11 (1913) p. 102. J. Soc. Chem. Ind. vol. 32 (1913) pp. 438 and 439. Parker J. G WASTE SULPHITE LIQUOR AND ITS USE IN THE LEATHER INDUSTRY. Some investigators deny the tanning quality of the sulphite extract. Previous to and after tanning with pure extract treatment with sulphite extract in intervals is proposed. The extract could be used as a loading material in place of molasses, starch, sugar, etc. It is also proposed to study only the liquor from the first stage of the cooking process for tanning purposes. The aniline test is not decisive, as other sub- stances extracted from the wood give this reaction. Report 11. Ann. Meeting of I.V.L.J.C. Collegium (1912) p. 611. Chem.-Ztg. vol. 37 (1913) p. 6. Chem. Abs. vol. 8 (1914) 839. Yocum, J. H. and Faust, A. USE OF SULPHITE-CELLULOSE EXTRACTS FOR BLENDING. The use of sulphite-cellulose liquors for tanning has hitherto not met with much success, for if used in too great concentration the resulting leather often has a "tinny" feeling and a harsh grain. On blending the sulphite cellulose extract with other extracts, difficulties have also been met with because of the different behaviour with the different materials. The object of the present work was to determine the best conditions and the most suitable materials to blend with the cellulose liquors. A commercial sulphite-cellulose extract was used in the experiments. With every material which was tried, with the exception of the liquid quebracho extract, there was a loss of tannin produced by mixing. Mixtures of mangrove cutch with sulphite cellulose show no loss until more than 30 per cent of sulphite cellulose extract is used in the mixtures. In most cases the greater the amount of sulphite cellulose extract present, the greater the loss. With a mixture of equal parts of chestnut and cellulose extracts the loss was 6 per cent. With a similar mixture containing myrobalans the loss was 3-4 per cent. The losses with valonia are not quite so high as with myrobalans. With more than 30 per cent of the cellulose extract the resulting leather had a "tinny" feeling. J. Am. Leather Chem. Assoc. vol. 6 (1911) p. 537. J. Soc. Chem. Ind. vol 31 (1912) p. 36. Collegium (1912) p. 227. Chem.-Ztg. vol. 37 (1913) Rep. p. 115. TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 93 International Association of Leather Trade Chemists. DETERMINATION OF TANNING MATERIAL. Gravimetric determination of tannins and non-tanning substances by the method of the International Association of Leathern Trade Chemists; filter method and the jarfiller method by Procter. Chem. Techn. Neuzeit O. Damnier. Enke, Stuttgart, vol. 1 (1910) p. 689 vol. 3 (1911) p. 15 (Tanning materials from Sulphite liquor). Grosser, G. SULPHITE EXTRACT. The analysis of Honig's extract gave 23 per cent tanning substances, 30 per cent soluble non-tanning substances, and 4-3 per cent ash. In spite of 0-6 per cent of SOa the extract mixes with any other extract without precipitation. It is not suitable for after-tanning or loading, but for pre-tanning. In qualitative reactions for detection of adulterations the behaviour towards bromine water on one hand and formalin hydrochloric acid on the other hand are especially recommended; further the behaviour towards ferroatum and aniline hydro- chloric acid. The SO2 content and the ash content are particularly decisive. Technikum vol 20 (1912) p. 156. Chem.-Ztg. vol. 37 (1913) Rep. p. 442. Collegium (1912) pp. 510, 567. Grosser, G THE PHLOBAPHENE DISSOLVING PROPERTY OF NERADOL D. IN MIXTURE WITH QUEBRACHO-SULPHITE EXTRACT. Sulphite extract causes a precipitate with all tanning substances, and only with quebracho extract does it cause an increase in tanning substances, on account of its property of dissolving phlobaphen'e. If, however, the quebracho-sulphite-extract mixture is mixed with other tanning materials the unchanged sulphite extract preci- pitates the foreign tanning substances. If the precipitate is dissolved by the addition of 50 per cent Neradol D. the total amount of tanning substance is increased. Neradol makes any precipitation of tanning material impossible. Collegium (1913) p. 479. Franke, H VEGETABLE TANNING MATERIALS. Occurrence, qualities, preparation, and uses of the most important vegetable tan- ning materials. Magdeburg (1909.) Schneider, F. UTILIZATION OF THE LIQUORS FROM THE FIRST STAGE OF THE SULPHITE PROCESS. The observer is recommended to study the first extracts in the sulphite process (See also Ziegler). Collegium (1912) No. 512 p. 678. Gansser, A. DETECTION OF WASTE LIQUOR IN LEATHER, Pieces of ox hide are tanned with a dye (solution) containing 2-5 per cent waste liquor. The leather is afterwards extracted and the 'extracts compared tintometri- cally for intensity of colour with a 1.2 per cent tanning solution, as suggested by Procter and Hirst. In the case when 5 per cent waste liquor was used a certain quantity of the dilute solution gave the characteristic reaction (flakes at once) when 5 c.c. aniline and afterwards 20 c.c. concentrated hydrochloric acid were added. When 2 per cent was used the reaction took place in a few minutes. Collegium (1909) p. 360 (1912) p. 482. Z. angew. Chem. vol. 26 (1913) p. 528. Chem.-Ztg. vol. 37 (1913) Rep. p. 442 94 FORESTRY BRANCH BULLETIN No. 66 Winter, H, ACTION OF THE CELLULOSE TANNING EXTRACT UPON QUEBRACHO EXTRACT. Contrary to several leather chemists the author states that an increase of tan- ning, substance is secured when cellulose extract is added to solid Argentine quebracho extract, especially at 100 C. Perfect solubility in the cold is only obtained when pressure is used. Ledertechn. Rundschau, vol. 5 (1913) p. 161. Z. angew. Chem. vol. 26 (1913) p. 646. Dickerson, W. H. PROCESS OF TREATING WASTE SULPHITE LIQUOR FOR THE MANUFACTURE OF TANNING. EXTRACTS. In the manufacture of tanning extracts from waste sulphite liquor the latter is digested with an electrolyte such as sodium chloride, capable of gelatinizing the liquor or of converting it into a light-coloured mass of thin consistency when concentrated. To this mass may be added a thin tanning extract made by the addition to waste sul- phite liquor of a non-decomposing "precipitant" for lime. United States Patent 1043303 (1912). Paper Trade J. vol. 6(7 (1913) No. 2 p. 42. iSchwalbe Lit. (1913). Wochbl. Papierfabr. vol. 44 (1912) p. 4(796. J. Soc. Chem. Ind. vol. 31 (1912) p. 1140. Platsch, M PRECIPITATION OF OBJECTIONABLE CONSTITUENTS OF SULPHITE LYE. The precipitation of the calcium salts as sulphate can be completely effected only after elimination of the volatile organic acids (acetic acid) by evaporation of the lyes to a syrupy consistency. The reagents then used must be such that their bases form with sulphurous acid readily decomposable compounds only, or else do not com- bine at all. Aluminium sulphate, for instance, would be suitable, but precipitation may equally well be effected by sulphuric acid, provided the liquor be neutralized after the separation of the precipitate of calcium sulphate. French Patent 447578 (1912). United States Patent 1054141 (1913). J. .Soc. Chem. Ind. vol. 32 (1913) p. 284. Gianoli, G PROCESS OF PRODUCING TANNING EXTRACT. Crude, resinous, quebracho extracts are rendered soluble by treatment at 95 115 0., with a solution of sodium lignosulphonate, obtained, for example, from waste liquor from sulphite-pulp making by treatment with lime water to remove sulphurous acid, followed by sodium sulphate to remove excess of lime. United (States Patent 1063428 (1913). J. Soc. Chem. Ind. vol. 32 (1913) p. 760. Auerbach, J. IDENTIFICATION OF SULPHITE EXTRACT IN TANNIN EXTRACTS. The Procter-Hirst reaction can also be obtained when sulphite extract is not present. Only a negative reaction, therefore, is decisive. The Lowenthal-Procter method for determination of the tanning value is important. Chem.-Ztg. vol. 37 (1913) p. 906. Albersheim, M. PROCESS FOR PREPARATION OF TANNIN EXTRACTS FROM WASTE SULPHITE LIQUORS. An acetate, especially sodium and ammonium acetate, is added to the sulphite liquor and the mixture heated for a certain length of time, whereby the iron is precipi- tated. The filtrate may be treated with ammonia and carbon dioxide in order to remove the rest of the lime present. German Patent Application A. 22952 (1912). TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 95 Moeller, W. NERADOL TANNING SUBSTANCE. Discussion of the behaviour of the sulphite extract with Lowenthal's method of testing (permanganate) and the possibility of precipitation with hydrochloric acid and aniline. Collegium (1913) p. 489. Monnet C. SULPHITE EXTRACT IN TANNING EXTRACTS. The Procter-Hirst method for detecting sulphite extract is not reliable. Collegium (1913) p. 224. Z. angew. Chem. vol. 31 (1913) p. 646. Chem. Abs. vol. 7 (1913) p. 3856. Jedlica, F WASTE LIQUOR IN THE TANNIN EXTRACTS. In using more than 5 c.c. oak-extract solution sulphite extract could be detected with certainty with the Procter-Hirst reaction (0-5 c.c. water-white aniline, and 2 c.c. concentrated hydrochloric acid). If no distinct formation of flakes takes place after two hours in oak extract the extract is free from sulphite extract. Collegium (1913) p. 317. Sommerhof, E. 0. RENDERING TANNING EXTRACTS SOLUBLE JWITH SUGAR AND SODIUM BISULPHITE. The tanning effect of the sulphite extracts is based partly on the effect of the colloidal sulphur. Collegium (1913) p. 489. Stutzer, A. PROCESS FOR INCREASING THE AMOUNT OF TANNING SUBSTANCE IN THE SULPHITE EXTRACT. Lactic acid is added to the lime free liquor before, during or after the evapora- tion, in such a quantity that 10-50 parts lactic acid are used to 100 parts dry substance of the cooking liquor. The lactic acid or part of it may be produced in the waste liquor. German Patent Application St. 18199 (1913). Stutzer, A PREPARATION OF TANNING MATERIAL FROM WASTE SUL- PHITE LIQUOR. The lime is removed with ammonium sulphate. German Patent Application St. 17977 (1912). Luhrs, 0. PROCESS FOR PREPARING A DECOLORIZED, COMMERCIAL, LIME-FREE TANNIN EXTRACT FROM WASTE SULPHITE LIQUOR. Sodium bicarbonate or potassium bicarbonate, alone or in mixture with ammo- nia and phosphoric acid, is used for precipitating the lime. German Patent Application L. 34995 (1912). Stutzer, A. CONTENT OF TANNING SUBSTANCES IN WASTE SULPHITE LIQUOR. For removing calcium compounds from the lye, the addition of ammonium sul- phate before concentrating is recommended'. In this way, it is possible to obtain a liquor of 30 Be (specific gravity 1.262) containing only 0.08 per cent CaO and 0.84 per cent of mineral matter. The content of tanning substances (substances absorbed by hide powder) in the lye can be increased by the addition of different substances (sodium sulphate and bisulphate; salts of aluminium, zinc, iron, manganese, and chromium; phosphoric, acetic, and lactic acids). For example, an addition of 50 grammes' of 74 per cent lactic acid (per litre of original lye) to a lye to which 30 grammes of ammonium sulphate had been added before concentrating to 30 Be., the 96 FORESTRY BRAXCH BULLETIN No. 66 content of tanning substances rose from 49.65 to 62.9 per cent. The leather produced by the concentrated liquor was of a light colour. Z. angew. Chem. vol. 26 (1913) p. 463. Wochbl. Papierfabr. vol. 44 (1913) p. 3339. J. Soc. Chem. Ind. vol. 32 (1913) p. 8877. J. Am. Leather Chem. Assoc. vol. 8 (1913) No. 11, p. 481. Abraham, F. ACTION OF LACTIC ACID ON SULPHITE-CELLULOSE LYE. The author shows that the analysis of sulphite-cellulose liquors by the "filter-bell" method presents difficulties not experienced with the ordinary tanning extracts. Varia- tions in the strength of the liquor for analysis have a great effect on the results of analysis, and the author recommends that solutions of sulphite cellulose for analysis should be of a concentration corresponding to 3.5 grammes of tannin per litre. The use of lactic acid for swelling hide is known, and the increased tanning effect observed by Stutzer on adding lactic acid to sulphite-cellulose extract is considered to be due entirely to the hide powder becoming swollen by the acid and thus acquiring greater absorptive power for tannin. Gerberei-Technik (1913) Nos. 11, 12. Collegium (1913) 11,599. J. Soc. Chem. Ind. vol. 32 (1913) p. 1079. Eitner, W CELLULOSE EXTRACT. Practical tests of cellulose extract have established the fact that it is not an actual tanning material and has not the property of converting hide into a commercial leather. Hide treated with cellulose extract cannot be reconverted to raw skin by simple wash- ing; a colouration is produced completely through the skin and, when dried out, the skin is less transparent than is raw hide but is as hard and stiff as the latter. A rational analysis of cellulose extract should consist in estimating its total solid matter and mineral matter. From the former an estimate of its value as a filling material can be made and from the latter an idea of how far it has been purified from materials injurious to the leather. The cellulose extracts formerly on the market contained 50 per cent of solid matter and 5-8 per cent of mineral matter, resembling in this respect sulphited quebracho extracts. The use of cellulose extract as an adulterant of tanning extracts has reached large dimensions. Cellulose extract is added to other extracts not only to lessen the cost but also because it confers a better appearence on an inferior extract and improves its solubility. Beside the aniline hydrochloride reaction for cellu- lose extract (J. Soc. Chem. Ind. vol. 28 (1909) p. 293) its presence may be detected by the proportion between "matter absorbed by hide" and! "non-absorbed", which in the case of this material is about 1:0.82. For some other extracts the proportion is as follows : Quebracho extract 1 : 10 ; oak-wood extract 1 : 23 ; chestnut-wood extract 1 : 30 ; and myrobalans 1 : 215. The high ash content of cellulose extract (up to 9 per cent) is also found in some strongly sulphited tannin extracts, so a high percentage of ash need not necessarily imply its presence. Yo'cum has shown that by admixture of cellulose extract with tanning extracts a loss of tannin occurs which increases as the proportion of the former is increased; solid quebracho extract loses 4 per cent of tannin; catechu, 7 per cent; and chestnut extract 6 per cent. The author has shown that by treating the residue, obtained after allowing a solution of Argentine extract to settle, with sulphite liquor of 7 Be. (specific gravity 1-05) an increase of 3 per cent of matter absorbed by hide in the extract is obtained. Grosser has shown that by treatment of already tanned leather with sulphite cellulose a dark colouration is pro- duced in the liquor, caused by the removal of tannin or colouring matter, from the leather, while the colour of the leather is improved. By treatment with sulphite-cellu- lose liquor, only the "difficultly-soluble" and not the "insoluble" portions of quebracho extract are brought into solution. This solution cannot be ascribed to the sulphites in the cellulose liquor, as the purified extract has also the solvent action. The explan- ation probably lies in the fact that the "difficultly-soluble" tannins dissolve more read- ily in a tannin solution than in water. As a material for filling and adding weight the TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 97 cellulose liquor is applied either like glucose to the tanned and struck-out leather or the dried or well-pressed leather is hung in a strong solution. The liquor penetrates and fills the leather more quickly in the latter way than does a tannin solution which is usually employed for that purpose, but for that reason it does not add much weight to the leather. Cellulose extract may be incorporated with leather in much larger quantities than can a tanning extract, but a limit is reached at which the leather be- comes brittle. The high solubility of cellulose extract may cause stains to appear on the leather which has been treated with it and the surface of which has been washed with water to improve the colour, the extract dissolving from the centre of the leather and not merely from the surface. The brittleness of leather heavily loaded with cellu- lose extract may be lessened by incorporating the latter with a fatty material in a fine state of division, the acid oleates being the most suitable fats. The fat may cause a darkening of the colour of the leather and must be removed from the surface by treat- ment with soda and acids. The use of cellulose extract during the actual tanning pro- cess presents greater difficulties. The author has shown that the addition of the extract to the liquors, making the density greater, considerably hastens their tanning action. The rate of diffusion is increased by the increase in their density, and the penetration of tannin to the interior of the hide is hastened without any objectionable consequences such as drawn grain. Attempts have been made to 'produce the same effect by adding neutral salts such as sodium chloride and potassium sulphate to the liquors, but these have the disadvantage that tannin is precipitated by them from the liquors. The addi- tion of cellulose extract to other extracts, where it would improve them, should be made in the hot condition, and 20 per cent should be sufficient to produce the best results. By the addition of 20-30 per cent of cellulose extract 2-5 per cent of the time necessary "for the tanning process is saved. It will be found that cellulose extract must become much cheaper than at present if it is to find a use in this connection. Gerber vol. 39 (1913) pp. 43, 57. J. Soc. Chem. Ind. vol. 32 (1913) p. 229. Hurt, H. H. TANNING COMPOUNDS FROM SULPHITE LIQUOR. A tanning composition is made by treating the waste lyes with a salt of a sesqui oxide combined with an acid capable of forming insoluble calcium salts and removing the insoluble calcium salt formed. The resulting solution containing the organic matters of the wood-liquor substantially in their original relative ratios and composi- tion is substantially free from lime, and contains alumina or other sesquioxide base in amount equivalent to the lime in the original liquor. United States Patent 1075916 (1913). J. Soc. Chem. Ind. vol. 32 (1913) p. 1079. 'Jhem. Abs. vol. 7 (1913) p. 4095 Paper Trade J. vol. 58 (1913)' No. 44 p. 44. Walker, W. 0. THE PROBLEM OF THE WASTE LIQUORS FROM SULPHITE PULP-MILLS- a R. T. Mohan investigated the subject of tanning and found that the addition of lactic acid to the liquor improved the tanning properties. He tried the effect of the addition of sulphites and acids on ordinary hemlock-bark liquor, finding that they caused swelling, bleaching, and hardening of the leather. He also tried the effect of an addition of sulphites to waste sulphite liquor and found swelling, hardening, and bleaching to occur. He removed the lime and found very little difference in quality of the leather. Removal of the gummy matters destroyed all tanning property, fur- ther, the gums when redissolved would not tan. However, the addition of lactic acid improved the tanning markedly. During this work it was noticed that, according to the different percentages of acid in the liquor, the leathers varied from hard and bleached to black and flabby. Experiments were carried out to determine what rela- tion of tannin to acid was best to produce leather of a good colour and texture. It was found that each acid has a factor for each tanning extract. With bark liquors the 49120 T 98 FORESTRY BRANCH BULLETIN No. 66 best ratio was found to be 0-8 (tans 8 acid 10) for lactic acid. For sulphite liquors the ratio was 1. For equal parts of sulphite liquor (spruce) and quebracho the ratio was 0'4. From this it would seem, therefore, that for heavy leathers, when acidity of liquor is needed, more uniform and reliable results could be obtained by the proper control of the ratio of acid to tannin in the first half-dozen vat liquors at least." J. JSoc. Chem. Ind. vol. 32 (1913) p. 389. Chem. Eng. vol. 17 (1916) 246. Paper vol. 11 (1913) No. 9 p. 21. See " General " p. 185.) Monnet, C. SULPHITE-CELLULOSE LIQUOKS IN TANNING EXTRACTS. At the last conference in London of the International Association of Leather- Trades Chemists it was decided that the presence of a " pseudo-tannin " (e.g. sulphite- cellulose liquor) when detected in an extract should be mentioned in the report of the analysis. The author points out that Procter and Hirst's aniline-hydrochloride test has lately been found to give rise to erroneous deductions and to give varying results in the hands of different observers, and its indication should therefore be confirmed by other reactions. Collegium (1913) p. 224. J. 'Soc. Chem. Ind. vol. 32 (1913) p. 616. Loveland, F, M. DETECTION OF SULPHITE-CELLULOSE EXTRACT. Gansser has stated that leather tanned in extracts containing 2-5 per cent of sulphite cellulose will give an extract yielding the characteristic flocculent precipitate, on treatment with aniline and hydrochloric acid. The author was unable to obtain the test with leather tanned in sulphite-cellulose extract alone, in liquors as high as 50 Be. It appears that different sulphite-cellulose extracts give results at variance by the same tests, or else the extract changes during the process of leather manufac- ture. The heavy white precipitate which settles out of certain classes of sulphite- cellulose extract consists of sulphur. J. Am. Leather Chem. Assoc. vol. 8 (1913) p. 128. J. Soc. Chem. Ind. vol. 32 (1913) p. 373. Small, F. H, REPORT OF COMMITTEE ON ANALYSIS OF SULPHITE-CEL- LULOSE EXTRACTS. There is no really trustworthy method of estimating the amount of tannin in an extract due to the addition of sulphite extract. The substance in sulphite extract which exercises a tanning effect on hides has a lesser effect compared to true tanning liquors. J. Am. Leather Chem. Assoc. vol. 8 (1913) p. 62. Z. angew Chem. vol. 26 (1913) p. 670. Moeller, W. TANNING WITH SULPHITE-CELLULOSE EXTRACT. Sulphite-cellulose extracts contain lignosulphonic acids which are readily absorbed by hide substance and are very difficult to wash out. The sulphonic acids are the constituents which give the Procter-Hirst reaction (J. Soc. Chem. Ind. vol. 28 (1909) p. 293) and as they are so tenaciously retained, sulphite- cellulose extract cannot be detected in aqueous extracts of leather tanned with it (J. Soc. Chem. Ind. vol. 32 (1913) p. 373). Cold 2 per cent caustic-soda solution extracts these sulphonic acids from such leather, and on acidifying the solution gives the Procter -Hirst reaction. Sulphite-cellulose extract which has been used to "weight" fully-tanned leather is extracted by water alone. Hide tanned with a mixture of vegetable tanning material and sulphite-cellulose extract first absorbs the former, and if sufficient is present to tan the hide fully there is no absorption of the latter. (J. Soc. Chem. Ind. vol. 32 (1913 pp. 245,616.) J. Soc. Chem. Ind. vol. 33 (1914) p 365 Collegium (1914) p. 152. Ledertechn. Rundschau, vol. 2 (1910) p. 73. Chem. Abs. vol. 8 (1914) p. 2082. TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 99 Moeller, W. PSEUDO-TANNINS IN SULPHITE-CELLULOSE EXTRACTS. Lime and sulphurous acid must be removed from the sulphite extracts before use. (Extracts from soda mills are only neutralized with a weak acid.) All cellulose extracts give about 15 per cent ash and contain rosin and sugar, which are witthout value and when mixed with real tannin extracts are concentrated in the tannin lye and have a detrimental effect. Molasses, cane sugar, and glucose are cheaper loading materials for leather than cellulose-liquor extracts. Only 50 per cent of the soluble cellulose extracts are utilized as loading material. Collegium (1914) p. 319. J. Soc. Chem. Ind. vol. 33 (1914) p. 654. Pulp Paper Mag. Can. vol. 12 (1914) p. 468. Paper vol. 14 (1914) No. 19 p. 18. Moeller, W. CELLULOSE EXTRACTS IN TANNING EXTRACTS. The substances in cellulose extract which react witlh aniline and hydrochloric acid are all contained in the portion of it which is absorbed by hide. That the non-tannin filtrate sometimes gives the precipitate is due to the fact that many cellulose extracts are neutral or alkaline, and the material reacts very slowly with (hide powder. Cellulose extract was detected in the suspender pits of a tannery in which its use had been dis- continued for 6 months. By adding absolute alcohol to. a fairly, strong cellulose- extract solution 40-50 per cent is precipitated, which is quite a different action to that shown by most tanning materials. The precipitate contains all the substances which give the Procter-Hirst reaction (J. Soc. Chem. Ind. vol. 28 (1909) p. 293) and the portion left in solution is free from lignin. By precipitating the lignin substance there was obtained an oily liquid which was evaporated to a solid extract consisting mainly of substances absorbed by the hide. The alcoholic filtrate contained very little material capable of being absorbed by hide and did not react with aniline. Small quantities of cellulose extract mixed with other extracts can be detected by precipitat- ing with alcohol and applying the Procter-Hirst test to the dissolved precipitate. The author found it impossible to detect cellulose extract in leather in the manufacture of which it has been used mixed with other extracts in the ordinary course of manufac- ture. When, cellulose extract has been used as a filling and "weighting" material on tanned leather it can be washed out with water and the Procter-Hirst test applied. Collegium (1914) p. 488. J. Soc. Chem. Ind. vol. 33 (1914) p. 840. Moeller, W. WASTE SULPHITE LIQUOR AS TANNING MATERIAL AND ITS DETECTION IN LEATHER. The tannin content of the extracts is found to be 24 per cent. The lignosulpihonic acids contained in the extracts have a great affinity for the hide, but the tanning effect is low and the extracts are practically of no value for tanning purposes. Z. angew. Chem. vol. 27 (1914) p. 560. J. Am. Leather Chem. Assoc. vol 9 (1914) No. 5 p. 246. DISCUSSION UPON THE SULPHITE-CELLULOSE EXTRACT AND ITS USE AS A TANNING MATERIAL. Report on discussion in the Association of Leather Chemists. Z. angew. Chem. vol. 27 (1914) p. 604. Schnlte, F. H.-SULPHITE LIQUOR AS TANNING MATERIAL AND ITS DETECTION IN LEATHER. Polemic in answer to W. Moeller. Ledertechn Rundschau vol. 6 (1914) p. 129. Chem. Abs. vol. 8 (1914) p. 2637. J. Am. Leather Chem. Assoc. vol. 9 (1914) No. 7 p. 335. 49120 7il 100 FORESTRY BRANCH BULLETIN No. 66 SULPHITE EXTRACT AND HOW TO DEAL WITH IT. A discussion of its value and the opposition from the leather manufacturers. Deals particularly with W. Moeller's remarks of its uselessiiess. In. Germany only 1-5 per cent of the output from all the sulphite-mills could be used in that country. Papier-Fabr. vol. 12 (1914) Annual number p. 48. Dickerson, W. H. SULPHITE-CELLULOSE BLENDS. Results of analyses of the mixture of sulphite-cellulose and various tanning extracts are given. A slight loss of tannin is shown, which was lessened by the use of small quantities (0-1-0-5 per cent) of acetic acid. Tests are recorded of liquors to which sulphite-cellulose has been added. Here no loss of tannin resulted but a decided gain occurred. J. Am. Leather Chem. Assoc. vol. 9 (1914) p. 489. J. Soc. Chem. Ind, vol. 33 (1914) p. 1163. Gansser, A. DETECTION OF SULPHITE-CELLULOSE EXTRACT. Moeller and Loveland have been unable to confirm the author's results in the detection of cellulose extract in the extract from the leathers on which it has been used (Collegium -(1912) p. 482). It must be assumed that there are some cellulose extracts which do not give the Procter-Hirst reaction (J. Soc. Chem. Ind. vol. 28 (1909) p. 293) and Becker has shown that such extracts may be produced. Quebracho wood which is kept away from light and air and under the action of mould growths will give the Procter-Hirst reaction. Collegium (1914) p. 324. J. Soc. Chem. Ind. vol. 33 (1914) p. 654. Chem. Abs. vol. 9 (1915) p. 535. Grothe, 0. TREATING WASTE SULPHITE LIQUOR. The SO2 is removed by adding lime, the liquor is concentrated and heated with cyanide of potassium or sodium, under pressure for 4-5 hours, to a temperature of 150 C. The reaction mass is diluted with water and an organic cyanogen compound is precipitated by the addition of an acid. The precipitate is filtered off and dried at ordinary temperature and may be used for tanning. United States Patent 1087911 (1914) Chem. Abs. vol. 8 (1914) p. 1367. Paper Trade J. vol. 60 (1915) No. 6 p. 52. Honig, M. TANNING MATERIAL FROM WASTE SULPHITE LIQUOR. The liquor is mixed with an acid, e.g. H2SO4, to form insoluble calcium salts and free a portion of the lignosulphonic acids, adding a soluble salt of the acid used (e.g. ZnSO.*) to convert the remaining calcium salts into other soluble salts and an insoluble calcium salt, and finally filtering the product through a material (e.g. oak galls or myrobalans) which forms insoluble compounds with iron. United States Patent 1080970 (1913). Chem. Abs. vol. 8 (1914) p. 591. Appelius, W. and Schmidt, R. DETECTION OF SULPHITE CELLULOSE IN TANNING EXTRACTS AND IN LEATHER. The precipitate obtained with sulphite-cellulose extract and cinchonine sulphate forms, on heating, a characteristic, insoluble, brownish-black mass, which is quite distinctive even in solutions of vegetable tannins or in leather infusions containing only a little sulphite-cellulose extract. Neradol D. also gives with cinchonine sulphate a precipitate insoluble on warming, which, however, does not form a brownish-black mass but more resembles a silver-chloride precipitate. TANNING MATERIALS -FROM WASTE 101 The test depends upon the fact that the presence of tannin prevents the precipitate- given by sulphite cellulose and cinchoniiie from being dissolved on heating. In case of pure sulphite extracts, tannin must be added before making the test. Ledertechn. Rundschau vol. 6 (1914) p. 225. Z. angew. Chem. vol. 27 (1914) p. 691. Collegium (1914) p. 706. J. Am. Leather Chem. Assoc. vol. 9 (1914) p. 64. J. Soc. Chem. Ind. vol. 34 (1916) p. 189. Paeszler, J. ANALYSIS OF SULPHITE-CELLULOSE EXTRACTS. Sulphite-cellulose extracts analysed by the official method of the International Association of Leather Trade Chemists gave results varying within 10 per cent accord- ing to the strength of the solution used for analysis, although such strengths were within the official limits of 0-35-0-45 per cent of tanning matter. In control experi- ments with vegetable tanning materials variations in the strength of the solution taken for analysis within these limits had no influence on the results. The German section of the Association has decided that the strength of the solution of sulphite cellulose for analysis should be 20 grammes of extract per litre. Chem.-Ztg. vol. 38 (1914) p. 974. J. Soc. Chem. Ind. vol. 34 (1915) p. 189. Paper Trade J. vol. 61 (1915) No. 13 p. 50. Becker, H. and Gross F, F. SUSPECTED ADULTERATION OF QUEBRACHO EXTRACT WITH SULPHITE CELLULOSE. An extract described as pure quebracho showed 15 per cent sulphite cellulose according to the Procter-Hirst reaction; a higth alcohol figure, low gallic acid value, and high non-tannin content, also a large amount of sulphate in the ash. Becker is of the opinion that quebracho extracts made from partly rotten wood might give such results. An extract from partly rotten wood indicated 20 per cent sulphite cellulose. Gross points out that only 2 per cent of rotten wood is allowed in commercial quebractho wood and that attempts to make from quebracho wood alone an extract showing figures like those of Becker's extract did not succeed. From exper- ience he finds that quebracho extract cannot be regarded as pure if it contains more than 6 per cent of non-tannins. Ledertechn. Rundschau vol. 6 (1914) Oct. 22. Collegium (1915) p. 106. J. Soc. Chem. Ind. vol. 34 (1915) p. 501. Laufman, B. DISTINCTION AND DETECTION OF TANNING MATERIALS AND CELLULOSE EXTRACT IN LEATHER. In general it can be said that when leather is tanned partly with one extract and the tannage completed with another the aqueous infusion more nearly resembles the latter, but a part of the tannin in all cases may be so firmly combined with the hide fibre that it does not appear in the aqueous infusion. Leathers containing sulphite- cellulose extract, in which tihis material can be detected immediately after tannage, may show no reaction when tested after three months. Ledertechn. Rundschau vol 6 (1914) Dec. 24 and 31. J. Am. Leather Chem. Assoc. vol. 10 (1915) p. 160. J. iSoc. Chem. Ind. vol. 34 (1915) p. 437. Harrocks, W. E. and Tullis, J. K. PRODUCTION OF TANNING EXTRACTS FROM WASTE WOOD-PULP EXTRACTS. Wood-pulp extracts obtained as waste products in the manufacture of paper pulp, etc., are heated with neutral soluble salts, (e.g. aluminium sulphate and magnesium sulphate) and the mass which separates is pressed, dissolved in warm water, and used for tanning. English Patent 1&332 (1914). J. 'Soc. Chem. Ind. vol. 34 (1915) p. 1063. 3 . 3 1 ! jS ^! ft ,. C i. * 102 | ^OSBSTRY BRANCH BULLETIN No. 66 TANNIN EXTRACT FROM WASTE SULPHITE LIQUOR- Embretsfos mills are now producing 400,000 kilogrammes (880,000 Ib.) extract yearly by Landmark's method but the production can be increased to 5,000-6,000 metric tons a year '(5,500-6,600 short tons). Price at present is 20 ore per kilogramme ($0.0245 per Ib.). The Norwegian barium extract makes the leather firmer and more pliable and gives a lighter colour, and there is a great demand for the extract in Norway as well as in other countries. Papier-Fabr. vol. 3 (1915) No. 15 p. 188. Luke, J. PROCESS FOR OBTAINING A COLOURLESS, TECHNICAL, LIME- FREE TANNIN EXTRACT FROM WASTE SULPHITE LIQUOR. Sodium or potassium bicarbonate alone or in mixture with phosphoric acid or with ammonia and phosphoric acid is used for precipitation of the lime. Norwegian Patent 26138 (1915). Papier-Fabr. vol. 3 (1915) No. 17 p. 215. Grothe, 0. PROCESS OF MANUFACTURING A TANNING MATERIAL FROM WASTE SULPHITE LIQUOR. Norwegian Patent 25315 (1915). Papir. J. vol. 3 (1915) p. 37. Hurt, H. H. TANNING MATERIAL FROM WASTE SULPHITE LIQUOR AND PROCESS OF PREPARING THE SAME. A neutral highly concentrated waste sulphite liquor is treated successively or simultaneously with sulphuric acid and alkali sulphate to remove lime and to liberate ligninsulphonic acids. The precipitate is separated leaving a tanning liquor of 28 to 31Be. (Specific gravity 1-24-1 -27.) United States Patent 1147245 (1915). J. Soc. Chem. Ind. vol. 34 (1915) p. 915. Chem. Abs. vol. 9 (1915) p. 2465 landmark, H. B. PREPARATION OF A TANNING EXTRACT FROM WASTE SULPHITE LIQUOR. Waste liquors are evaporated to less than half their original bulk to remove free SO2, then treated with sodium carbonate in about twice the quantity necessary for neutralization to remove the iron and part of the calcium, and, after filtering or decant- ing the liquor, the remainder of the calcium is precipitated by oxalic acid. A further quantity of organic acid is added to the filtered product which is then concentrated. French Patent 474336 (1914). J. Soc. Chem. Ind. vol. 34 (1915) p. 1005. Landmark, H. B. TANNING EXTRACT FROM WASTE SULPHITE LIQUOR. Sulphuric acid may be used instead of oxalic acid. English Patent 7090 (1915). See French Patent 474336 (1914). J. Soc. Chem. Ind. vol. 35 (1916) p. 372. Chem. Abs. vol. 10 (1916) p. 2813 Appelius, W CINCHONTNE FOR THE DETECTION OF SULPHITE CELLU- LOSE IN LEATHER. The cinchonine test is uncertain with leather extracts unless carried out according to the following method: Five to ten grammes of leather, cut into small cubes (not finely ground), is extracted by heating to boiling with 100 c.c. of water. After filtra- tion, 5 c.c. of 25 per cent hydrochloric acid is added to the filtrate which is heated to boiling and again filtered. Twenty c.c. of cinchonine solution is then added to 50 c.c. of the filtrate, together with a very little tannin solution, and the mixture heated to TANNING MATERIALS FROM WASTE SULPHITE LIQUOR 103 boiling without moving the flask. A lumpy, brown-black precipitate appears in the presence of even small amounts of sulphite cellulose. J. Am. Leather Chem. Assoc. vol. 10 <1915) p. 202. Ledertechn.' Rundschau vol. 7 (1915) p. 17. J. Soc. Chem. Ind. vol. 34 (1916) p. 501. Gross, F. F. METHOD OF PRODUCING TANNING COMPOSITIONS FROM WASTE SULPHITE LIQUOR. The warm liquor after treatment with hydrochloric and sulphuric acids and potas- sium chromate, to remove lime, is concentrated to about 20 Be. (specific gravity 1.16), filtered, and further concentrated as desired. United 'States Patent 1154762 (1915). J. Soc. Chem. Ind. vol. 34 (1915.) pp. 1155, 1139 Chem. Abs. vol. 9 (1915) p. 3378. Byrom, F. G. PROCESS OF MANUFACTURING TANNING EXTRACTS FROM SULPHITE-CELLULOSE LIQUOR. Concentrated sulphite liquors are treated with phenols, amino compounds or nap- thalene-disulphonic acid, or with mixtures of these, or with the middle oil or the heavy oil from the distillation of coal-tar. A soluble, light-coloured tanning agent is ob- tained. English Patent 24196 (1914). J. Soc. Chem. Ind. vol. 34 (1915) p. 1063. Chem. Abs. vol. 10 (1916) p. 1610 Landmark, H, B. WASTE SULPHITE LIQUOR AS A TANNING MATERIAL. The author discusses the problem in general and states that the "sulphite extracts" when used in mixture with other extracts improve the colour of the leather, cause a greater absorption, and accordingly reduce the cost of tannage. The extracts are not good unless the iron is absolutely removed and the lime removed to such an extent that it cannot be detected in the extract (only in 'the ash). Tables showing the coin- position of various extracts. Tid. Kemi. Farm. Terapi. vol. 9 (1916) Nos. 1 and 2 Beveridge, J. THE UTILIZATION OF WASTE SULPHITE LIQUOR. When the liquor is neutralized with lime and the clear liquor evaporated down, it can be sold as a tanning agent known on the market as "spruce liquor". The table gives a comparison of this commodity with the extract from hemlock bark. Spruce Sulphite Process. Hemlock Wood Sulphite Process. Hemlock Bark Extracted with Water only. Moisture % 41.34 58.68 58.61 .07 39 36 19.25 1.290 % 47 93 52.07 51.93 .14 24.84 27.09 1.269 % 54.24 45.76 41.93 3.83 16.63 25.30 1.215 Total solids Soluble solids Insoluble Non-tannins Tannins Specific Gravity 104 FORESTRY BRANCH BULLETIN No. 66. . v. If calculated on 100 parts of total solids the amount of tannin is respectively 32-80 per cent, 52-02 per cent, and 55-29 per cent. The fact that this tannin is asso- ciated with other organic compounds in combination with lime and sulphurous acid and that these have the tendency to foul the tan liquor in the pits and 'perhaps enter into the composition of the leather itself, has operated against its extended use. Pro- cesses for a separation of these substances have been proposed by Mitscherlich, Opl, Kempe, Kumpf miller, and others. J. fioc. Chem. Ind. vol. 35 (1916) p. 563. Laufman, B. DETECTION AND DIFFERENTIATION OF VEGETABLE AND SYNTHETIC TANNINS. Reactions for detection of sulphite-cellulose extract and artificial tannins of the Neradol class. Finely-divided leather is allowed to stand overnight in ten times its weight of 2 per cent caustic soda solution. The solution is then filtered, slightly acidified with hydrochloric acid, filtered again, and diluted so as to contain 0-6 per cent of organic matter. It is then tested by the aniline test or by cinchonine sul- phate. A negative result shows absence of both sulphite cellulose and Neradol. A positive result indicates sulphite cellulose if Neradol is subsequently proved to be absent by special tests. Tests on Neradol are given. Chem.-Ztg. vol. 41 (1917) pp. 273 and 286. J. Soc. Chem. Ind. vol. 36 (1917) p. 513. Harvey, A. SULPHITE-CELLULOSE EXTRACTS. Review of method of manufacture, uses and tests. Leather World vol. 9 (1917) p. 73. ALCOHOL The amount of fermentable sugar in the waste sulphite liquor ordinarily varies according to the published data, between 1-5 and 2 per cent, but may in some cases be as high as 2-4 per cent. (Canadian sulphite liquor will vary from 0-5 to 1-75 per cent of fermentable sugars). As the lower carbohydrates of the wood must be consi- dered as the chief source of the fermentable sugar, the amount of sugar in the liquor may vary to some extent with the wood material, but no doubt the greatest factor in these variations is to be found in the method of cooking. Hagglund, who has published a very instructive work on the present stage of alcohol production from waste sulphite liquor, calls attention to this fact and shows how the formation of sugar depends upon the strength of the liquor as well as upon the temperature. He also shows how the fermentable sugars are partially destroyed at the high temperature prevailing in the digester at the end of the "cook". It is also interesting to note that only very little sugar is formed from the cellulose in the cooking process. The idea of manufacturing alcohol from the waste liquor dates back to the early years of the sulphite pulp industry but not until recent years had this resulted in commercial processes of any importance. Wallin's and Ekstrom's processes are now in. operation on a commercial scale in Sweden and the United States and, presumably, to a great extent in Germany; in Norway, Landmark's process has been in operation for some time, and a plant is also established in Sweden for the operation of the same process. Marchand's process has been tried out in an experimental plant in the United States with satisfactory results. The principle is the same in all these processes. The free sulphurous acid must bo removed as far as possible from the liquor and recovered, which in some cases is partly effected by concentration of the liquor. The liquor is then neutralized to a certain point of acidity. A suitable yeast is then added and the liquor fermented and distilled. The yield of alcohol depends of course, in the first place, upon the amount of fermentable sugar in the liquor, but the neutralization as well as the fermentation are both processes which require the closest control if the highest possible yield is to be obtained. Although a yield as high as 1-4 per cent by volume has in some cases been obtained Hagglund gives 1-0 per cent (100 per cent alcohol) as a good average. Landmark claims a higher yield, namely 1-2 per cent, with his process and an average of 1-1 per cent, and Marchand's process is said to yield 1 1-25 per cent, 180 proof alcohol. With regard to the neutralization of the liquor (which usually is previously or simultaneously effectively aerated in order to oxidize certain reducing organic sub- stances) it is not advisable to use lime alone, as in this case a large excess is required, causing an appreciable amount of sugar to be destroyed. Another objection is that it is difficult to obtain a clear solution which is necessary for the fermentation. Accord- ing to Hagglund, by using a smaller quantity of lime and employing calcium carbonate for the final neutralization these troubles are eliminated. In the Marchand process barium carbonate is employed for neutralization whereas Landmark uses calcium carbonate in his process. Nitrogen and phosphates are not present in the liquor in the quantity required for a normal fermentation, and must be added to tlie neutralized liquor. Certain available yeast extracts contain the necessary amount of these substances but if other extracts are used the nutriment must be added, in a suitable form. In Landmark's process milk or whey is heated with acid, the precipitate of "lignocasein" is filtered off, and the filtrate added to the sulphite liquor which can then be fermented directly with ordinary brewers' yeast. Ekstrom's process requires a "tempered" yeast which is prepared to meet the srpecial conditions of the sulphite liquor. With regard to the details of the processes of fermentation and distillation reference may be made to Hagglund's publication "Die Sulfitablauge und ihre Verarbeitung auf Alkohol". In 105 106 FORESTRY BRANCH BULLETIN No. 66 this same publication the manufacturing cost of a 100 per cent spirit is calculated, assuming a recovery of 3.7 cub. m. (816 gallons) of liquor per metric ton (220^ lb.) of air-dry pulp [4.1 cub. m. (904 gallons) per metric ton (2204 lb.) of bone-dry pulp] as follows : MANUFACTURING cost for 1 cubic metre (220 gallons) of distilled mash. Cost Items. SIZE OF MILL. 33,075 short tons. 22,050 short tons. 11,025 short tons. Steam Marks. 0-422 0-083 0-167 0-022 0-055 0-165 070 0-056 $ 1000 0-0197 0397 0-0052 0-0131 0-0393 0-0168 f 0133 Marks. 422 0-083 0-167 0-028 0-078 0-225 0-090 067 $ o-iooo 0-0197 0.0397 0066 0-0186 0-0535 0-0214 0159 Marks. 0-422 0-083 0-167 0-040 0-117 0-335 123 0-073 $ o-iooo 0-0197 0-0397 0095 0279 0-0796 0-0292 0174 Nutriment Materials Repairs . . Labour Miscellaneous . . .... 1-040 0-247 1 060 0-276 1-360 324 These figures are based upon prices in Scandinavia, and would have to be changed to suit American conditions. Assuming a 50 per cent increase in salaries, labour, and repair costs the manufacturing cost would be $0.282, $0.323, and $0.392. The yield of 100 per cent spirit being on an average 1 per cent by volume, and calculating the cost of an alcohol plant in America as being 50 per cent higher than in Scandinavia, and further allowing for 15 per cent depreciation and -interest the total cost and sel- ling price of one litre 100 per cent spirit is given in the following table. Size of . Pulp-mill Short Tons. Cost of alcohol Plant. 15 per cent Amortization and interest of plant. Spirit Produced . Amortization and interest per litre spirit. Manufac- turing cost. Selling price. $ $ Litres. $ $ $ 33,075 150,000 22,500 1,110,000 0-0202 0-0282 0-0484 22,050 112,500 16,900 740,000 0-0229 0-0323 0-0552 11,025 75,000 11,250 370,000 0-0315 0-0392 0-0707 The corresponding prices of an imperial gallon are $0.220, $0.251, and $0.320 and of a United States gallon $0.183, $0.209, and $0.268. Landmark claims a higher yield of alcohol, namely an average 1-1 per cent, and a lower cost of production, namely $0.0254 per litre, depreciation and interest and cost of handling included. This corresponds to a price of $0.115 per imperial gallon or $0.096 per United States gallon manufactured in Scandinavia. A direct comparison of the two processes on the basis of the published figures is not possible, as the operat- ing cost varies considerably with the size of the plant and with the yield of alcohol. Landmark has based his calculations on a recovery of 6-5 cub. m. (1,430 gallons) liquor per metric ton (2,204 lb.) of pulp and upon plant connected with a 15,000 metric tons (17,000 short tons) pulp-mill. This would mean a yearly production of 1,072,500 litres (236,000 gallons) of alcohol and would require an alcohol plant of the same size as the 30,000 metric ton (33,075 short tons) pulp-mill in the previous example. The chief difference of the two processes is in the neutralization and fer- mentation, but even if the cost of nutriment, neutralization, and material is sub- tracted the manufacturing price would still be as high as $0.186 for an imperial gallon or $0.158 for a United States gallon of 100 per cent spirit, which is appreciably ALCOHOL FROM WASTE SULPHITE LIQUOR 107 higher than the cost calculated by Landmark. The value of the " lignocaseiu " recovered in this process is said to cover very nearly the cost of the milk or whey employed. As the fermentable sugars represent only 15-20 per cent of the total organic sub- stances in the liquor, the residual liquor from the distillation process should be further utilized. Fuel may be recovered according to Strehlenert's process, but it has been pointed out that an unfavourable precipitate is obtained in cases where much lime has been used for neutralization. Valuable products may also be obtained by destructive distillation of the dry substance. In the cooking process 7 kilogrammes (14 Ib.) methyl alcohol are formed per ton (short) of pulp of which 4-4 Ib. can be recovered from the relief gases. One part of this alcohol is lost during the various operations, so that the crude ethyl alcohol contains about 3-2 per cent methyl alcohol. The two alcohols can be separated but of course this is not necessary when the spirit is to be ueed for industrial purposes. Mitscherlich, A. INNOVATIONS IN THE PKOCESS OF PRODUCING TAN- NING MATERIALS WITH THE PRODUCTION OF THE BY-PRO- DUCTS CELLULOSE, GUMS, ACETIC ACID, AND CALCIUM BI- SULPHITE. German Patent 4179 (1878). (See " Tanning Materials " p. 78.) Mitscherlich, A COOKING OF WOOD WITH CALCIUM BISULPHITE, RE- COVERING CELLULOSE TANNING MATERIALS, GUMS, AND ACETIC ACID. English Patent 1668 (1882). (See " Tanning Materials " p. 78.) Pictet and Brelaz IMPROVEMENTS IN SULPHITE WOOD-PULP. Recovery of gum, rosin, tannin, and alcohol. English Patent 9509 (1884). (See " Tanning Materials " p. 78.) Mitscherlich, A. PROCESS FOR PRODUCING TANNING MATERIALS, AD- HESIVES, AND OTHER SUBSTANCES FROM WASTE SULPHITE LIQUOR. German Patent 72161 (1891). English Patent 12927 (1893). (See "Tanning Materials" p. 78.). Mitscherlich, A. PROCESS FOR PREPARATION OF ADHESIVES FROM HORN SUBSTANCES BY MEANS OF WASTE SULPHITE LIQUOR. The waste liquor can be used for the production of alcohol after the tannins have been removed. German Patent 82498 (1893). (See " Gums, Adhesives, and Sizing Materials " p. 68.) Mitscherlich, A. PROCESS AND APPARATUS FOR UTILIZATION OF WASTE SULPHITE LIQUOR. Covers German patents for reclaiming adhesives, tanning material, alcohol, and fodderstuff. Austrian Privilegium 112 (1894). (See "Gums, Adhesives, and Sizing Materials" p. 68.) Classen, A. PROCESS FOR MAKING SUGAR SOLUTIONS FROM TANNIN- CONTAINING WOODS OR OTHER CELLULOSE 'MATERIALS EASILY FERMENTABLE. The product obtained by the usual method of inversion from the tannin-containing woods can be fermented to only a slight extent due to the gallic acid produced from 108 FORESTRY BRANCH BULLETIN No. 66 the tannins. To get rid of this gallic acid it is precipitated in the form of a metallic salt by first neutralizing with CaOOs and then adding a solution of a metallic salt (e.g. FeSO 4 ). It is then made weakly alkaline with lime, and the precipitated CaSO 4 filtered off. .German Patent 161644 (1903). Chem. Zentr. (1905) part II p. 560. Ekstrom, GK SPIRIT FROM WASTE SULPHITE LIQUOR Svensk Kem. Tid. (1909) No. 7. Papier-Ztg. vol. 35 (1910) part II p. 2519. Tillberg, E. W. PROCESS FOR OBTAINING TANNINS, ALCOHOL, AND CELLULOSE FROM WOOD. Swedish Patent 25283 (1907). * Bergstrom, H. 0. V. METHYL ALCOHOL IN THE MANUFACTURE OF ETHYL ALCOHOL FROM WASTE SULPHITE LIQUOR, Jernkontorets Annaler (1909) p. 691. Papier-Fabr. vol. 7 (1909) pp. 506, 607. Bergstrom, H. 0. V. METHYL ALCOHOL IN DIGESTION OF SULPHITE WOOD-PULP. Methyl alcohol has been obtained in considerable quantities from the condensed vapotirs blown off after the digestion of wood by the soda process. The author has examined the similar distillate from the sulphite-pulp digesters and has found that it contained about 1 per cent methyl alcohol. Only a portion of the total methyl alcohol formed passes off with the vapours, a certain amount remaining behind in the waste liquors. This latter observation has a bearing on the proposed utilization Of these waste liquors for the production of ethyl alcohol by fermentation. In connec- tion with the question of the chemical constitution of wood, the author mentions that when wood is boiled under atmospheric pressure with a dilute solution of an alkali hydroxide, ammonia, methyl alcohol, acetaldehyde, and acetone are formed. The same products are also formed from peat and "white moss" but in different propor- tions. Papier-Fabr. vol. 8 (1909) p. 970. J. Soc. Chem. Ind. vol. 28 (1909) p. 1162. Rosenblatt and Rosenband, M. THE RETARDING ACTION OF CERTAIN ACIDS UPON ALCOHOLIC FERMENTATION.- Chem.-Ztg. vol. 33 (1909) p. 921. MANUFACTURE OF ALCOHOL FROM WASTE SULPHITE LIQUOR AC- CORDING TO EKSTROM'S PATENT, IN SKUTSKAR (SWEDEN). Papier-Ztg. vol. 34 (1909) part I p. 1682. Wallin, J. H. ALCOHOL FROM WASTE SULPHITE LIQUOR. Neutralization with lime in excess and subsequent saturation with carbon dioxide. Addition of yeast and malt to the filtrate. In order to increase the sugar content the waste liquor may be cooked at high temperature with peat or sawdust. Norwegian Patent 18687 (1908). Swedish Patent 267808 (1907). M - German Patent 246708 (1908). Chem.-Ztg. vol. 33 (1909) Rep. p. 251. Papier-Ztg. vol. 35 (1910) No. 16. , Chem. Zentr. (1912) part I p. 1871. Pulp Paper Mag. Can. vol. 10 '(1912) p. 358. ALCOHOL FROM WASTE SULPHITE LIQUOR 109 Stora Kopparbergs Bergslags Aktiebolag. PROCESS FOR OBTAINING ALCO- HOL FROM THE WASTE LIQUORS OF THE MANUFACTURE OF WOOD-PULP BY SOLUBLE SULPHITE. The lime sludge from sulphate-pulp mills which, besides calcium carbonate, con- tains organic matter and salts of sodium and magnesium, obtained as a waste product in the treatment of the waste liquors with sodium sulphate or carbonate, is used to neutralize the waste liquor, which contains in addition to glucose and other organic substances a small quantity of calcium bisulphite and free sulphurous acid. Not only is neutralization thus effected but the liquor is also enriched with nutritive substance necessary for the subsequent fermentation. If necessary the liquor is renclereol neutral or slightly acid by addition of acid or alkali, and is then separated from the preci- pitate. The liquor is then cooled, preferably by being sprayed down from the top of a tower and encountering a current of air moving upwards; by this treatment, it is also concentrated and saturated with air. It is then treated with an enzyme preparation or with yeast, and with nutriment yeast extract, the alcohol formed being separated by distillation or otherwise. French Patent 402331 (1909). -J. iSoc. Chem. Ind. vol. 28 (1909) p. 1221. Wochbl. Papierfabr. vol. 40 (1909) p. 4265. Papier-Ztg. vol. 43 (1909) p. 1682. Ekstrom, G. ALCOHOL FROM SULPHITE-CELLULOSE LYES. An experimental plant for the production of alcohol from sulphite-cellulose waste lyes at Skutskar, Sweden, began operations on May 24, 1909, the waste lyes from a cellulose works of 5,000 metric tons (5,500 short tons) capacity being treated. In March 1910, 2,130 litres (469 gallons) of spirit of " normal strength " were produced per 24 hours, total for the month was 49,027 litres (10,800 gallons). In April the production was 2,120 litres (4:67 gallons) per 24: hours, total 50,980 litres, (11,200 gallons). In consequence of the favourable results the plant is now being extended to deal with the waste lyes from the whole production of the Skutskar cellulose works 20,000 metric tons (22,000 short tons) per annum. Papier-Fabr. vol. 8 (1910) p. 582. J. Soc. Chem. Ind. vol. 29 (1910) p. 810. Wallin, J. H. SULPHITE SPIRIT. Wallin produces up to 1 . 5 per cent alcohol by volume from waste liquor in the Boksholm sulphite mill. The experimental plant in Kopmanholmen obtained from waste liquor from one metric ton (2204 Ib.) of pulp 50 litres (11 gallons) of spirit. Papier-Ztg. vol. 35 (1910) pp. 1508, 2519. Wochbl. Papierfabr. vol. 40 (1909) p. 4253. Schwalbe, C. G. ALCOHOL FROM SULPHITE LYE. In 1891 Lindsey and Tollens made an investigation of a sulphite-cellulose waste lye, containing 9-10 per cent of dry solids, and found in it 1.2 per cent of fermentable sugars, the yield in alcohol being 58-67 litres .(12. 8-14. 7 gallons) per metric ton (2204 Ib.) of cellulose. Recently in Sweden, Wallin at Forss, and Ekstrom at Skutskar (see J. Soc. Chem. Ind. (1910) p. 810) have attempted to develop an industrial process on this basis. The two processes are identical in all essentials except for the neutralization of the crude-acid lyes; the former uses lime and the latter the waste causticization sludge from the sulphate cellulose mills. The lyes are first neutralized in large vats they are then cooled, (e.g. in towers), and are simultaneously aerated. It is claimed that the neutralization sludge obtained in the filter presses after this, process if used for the preparation of fresh lyes, contains sufficient calcium sulphite to effect a saving of 40-45 per cent of the sulphur required. In a mill producing 10 metric ton (11 short tons) of cellulose per 24 hours the volume of the lyes to be treated amounts to about 100 cub. m. (22,000 gallons) per day and the quantity of neutralization sludge 110 FORESTRY BRANCH BULLETIN No. 66 may be taken at about 1.5 metric tons (1.7 short tons) dry or 3 metric tons (3.3 short tons) moist. A yeast nutriment, malt extract or dead yeast is added to the neutralized, cooked, and aerated liquid, which is transferred to the fermentation tuns. These must be large enough to allow a storage of at least 3 days' duration. After fermentation and separation of the yeast, the lye is distilled in a continuous still. The column apparatus designed by Kubierschky is particularly suitable for the distillation of sulphite lyes. The alcohol in these is in an extremely dilute condition and the consumption of steam in their distillation is far larger than in a molasses distillery. The alcohol obtained is already denatured; it contains considerable proportions of methyl alcohol pre-exist- ing in the unfermented lyes, furfural, and probably acetone; it appears to be practi- cally free from terpenes. The process is being worked on a considerable scale at Skuts- kar; the average yield of alcohol may be taken as 60 litres (13.2 gallons) per metric ton (2,204 Ib.) of cellulose and the present output is 50,980 litres (11,200 gallons) monthly. It is stated that under Swedish conditions the treatment shows a profit, but the author points out that it offers no solution of the problem of the disposal of the waste lyes ; on the contrary it may even happen that owing to the presence of dead yeast, etc., in the spent wash the nuisance may be aggravated rather than abated. Wochbl. Papierfabr. vol. 41 (1910) p. 2354. Z. angew. Chem. vol. 23 (1910) pp. 1080, 1537. J. iSoc. Chem. Ind. vol. 29 (1910) p. 1052. Papier-Ztg. vol. 35 (1910) p. 2004. Chem. Abs. vol. 5 (1911) p. "ISO. Kiby, W. ALCOHOL FROM SULPHITE LIQUOR. The author discusses the economic aspects of the newly established industry of the manufacture of spirit from the waste lyes of sulphite wood-pulp mills, taking as a basis the average yield of 60 litres (13-2 gallons) of absolute alcohol per metric ton (2,204 Ib.) of cellulose produced. The prospects of the industry depend on the cost of production, the capacity of the market, and the condition of taxation. In Sweden all the conditions are more favourable than in Germany. The total production of absolute alcohol in Sweden for the financial year 1908-9 was about 32 million litres (7,040,000 gallons) whilst imports amounted to 1-17 million litres (257,000 gallons). The sul- phite-pulp mill at Larkudden is now producing spirit at the rate of 600,000 litres (132,000 gallons) per annum and will soon be in a position to produce 1-2 million litres (264,000 gallons), so that the whole of the imports would be equalled by the product of this single mill. The pulp-mills of Sweden are capable of producing about 25 million litres (5,500,000 gallons) of absolute alcohol, and since the manufacture of spirit from the ordinary raw materials is intimately bound up with the other branches of agricultural industries it is hardly conceivable that the new sulphite spirit will be allowed to displace any considerable proportion of the present production. Further, since the sulphite spirit is of the denatured spirit, owing to its impurities, it must be conceded that the future of the industry depends on the opening up of new industrial sources of consumption. The author details the probable cost of production of spirit at a mill producing 60 metric tons (66 short tons') of cellulose per day. Such a mill could produce 1-3 million litres (286,000 gallons) of absolute alcohol per annum at a cost of 10 pfennigs ($0.024) per litre % ( $0.109 per gallon) allowing 10 per cent for depreciation of capital. In Sweden the larger distilleries bear a heavier tax the larger their production, so that including this tax 1-3 million litres (286,000 gallons) per annum could be produced for about 17 shillings ($4.14) per 100 litres ($0.188 per gal.) With the increasing consumption of industrial alcohol it is possible that even the full production of Swedish sulphite spirit could gradually be absorbed. Turning to Ger- many the author estimates that the maximum annual production of sulphite spirit might be about 33 million litres (7,260,000 gallons), which would be added to the present total production. The excise regulations in Germany are particularly severe and expressly penalize new distilleries, so that in addition to the production cost of 10-11 shillings ($2.44, $2.68) per 100 litres ($0.11, $0.122 per gal.) the sulphite spirit would be subject to an excise charge of 19 shillings ($4.63) per 100 litres ($0.21 per ALCOHOL FROM WASTE SULPHITE LIQUOB 111 gal.). German wood-pulp manufacturers could therefore only produce the spirit at a loss, which they would not consent to bear unless the production of spirit would offer a solution of the problem of the ultimate disposal of the waste lyes. This, however, is hardly likely to be the case, since the spent wash would in all probability be just as obnoxious as the original lye. Chem.-Ztg. vol. 34 (1910) ' pp. 1077, 1091. J. Sue. Chem. [nd. vol. '29 O910) 1265. Chem. Abs. vol. 5 (1911) p. 785 Ekstrom, G. ALCOHOL FROM SULPHITE LIQUORS. Alcohol is produced from the waste lyes obtained from the digestion of wood, etc., by the bisulphite process, by first precipitating the excess of sulphites and sulphurous acid by means of lime, chalk or other suitable neutralizing agent, concentrating the liquor, cooling to a temperature of 25 C., and fermenting the saccharine constituents by the addition of yeast and a yeast nutriment. The yeast nutriment is prepared from brewers' yeast or from yeast collected from an earlier fermentation by heating the yeast for a comparatively long time at a temperature of about 45 C., at which tem- perature the yeast is digested by the action of an enzyme contained in it. English Patent 6741 (1910). Canadian Patent 132717 (1911). J. Soc. Chem. Ind. vol. 30 '(1911) p. 504. Matheus ALCOHOL FROM SULPHITE LIQUOR, The author made experiments in 1892 on fermentation of sulphite liquor. Yield 0.7 per cent by volume. Papier-Fabr vol. 3 (1910) p. 532. Z. angew. Chem. vol. 23 (1910) p. 1584. Bergstrom, H METHYL ALCOHOL FROM THE MANUFACTURE OF CEL- LULOSE. Methyl alcohol is formed in the sulphite as well as in the sulphate digestion. One metric ton (2,204 Ib.) of cellulose produced in the sulphate cooking is accom- panied by 13 kilogrammes (28.6 Ib.) of methyl alcohol, while in the sulphite process 10 kilogrammes (22 Ib.) are produced. It is not practicable to separate the methyl alcohol from the ethyl alcohol produced by the fermentation of sulphite liquor. Papier-Fabr. vol. 8 (1910) p. 506. Z. angew. Chem. vol. 23 (1910) p. 1823. ETHYL ALCOHOL FROM SULPHITE LIQUOR. V-' Discussion on Schwalbe's paper. The employment of sulphite liquor for fermen- tation may be impossible in Germany on account of the heavy taxes. The sugar solution obtained from wood by hydrolysis could be used directly as a cattle food. Papier-Ztg. vol. 35 (1910) p. 2044. Z. angew Chem. vol. 23 (1910) p. 2057. WOOD SPIRIT FROM WOOD, ETC. For one metric ton (2,204 Ib.) of sulphite pulp 10 kilogrammes (22 Ib.) of wood spirit (methyl alcohol, acetone, and aldehyde) are formed. Jernkontorets Annaler (1909) No. 11. Papier-Fabr. vol. 7 (1909) p. 1314. Segerfeld, B ALCOHOL FROM WASTE SULPHITE LIQUOR History. Formation of fermentable sugars from wood and wood-gum. Quantity and composition of waste liquor. Neutralization and concentration. Precipitation of lime and recovery of same. " Kemi och Bergwetenskap " (Techn. Tid.) Papier-Ztg. vol. 35 (1910) pp. 2518, 2558. 112 FORESTRY BRANCH BULLETIN No. 66 SPIRIT FROM WASTE SULPHITE LIQUOR. The Company "Ethyl" in Falum (Sweden) will ope/ate Wallin's patent for the manufacture of sulphite spirit. Papier-Ztg. vol. 35 (1910) p. 2118. Papier-Fabr. vol. 8 (1910) p. 311. ALCOHOL FROM WASTE SULPHITE LIQUOR. Reports on the manufacture in Sweden. No reduction in volume of effluent to be expected. Opinions differ with regard to the injurious effect of the effluent. Svensk. Pap. Tid. '(1910). Papier-Ztg. vol. 35 (1910) pp. 569, 649, 690, 1110, 1387. Ekstrom, G. MANUFACTURE OF SPIRIT FROM WASTE SULPHITE LIQUOR. Paper read before the Swedish Technical Association. The waste liquor is mixed with lime sludge from the sulphate-pulp process and fermented in large vats. At the present time 30 million litres (6,600,000 gallons) sulphite spirit could be produced in Sweden and 250 million litres (55 million gallons) in the whole world. The price is 46-57 ore ($0-13) per litre ($0-585 per gallon). At 20 ore ($0-054 per litre ($0-245 per gallon) it could be used for motors. Svensk. Kern. Tid. (1907) (No. 7. Chem.-Ztg. vol. 34 (1910) p. 223. Wochbl. Papierfabr. vol. 41 (1910) p. 638. Papier-Fabr. vol. 8 (1910) pp. 238. 582. Papier-Ztg. vol. 35 (1910) pp. 649, 690. J. Soc. Chem. Ind. vol. 29 (1910) p. 810. Smart, B. SULPHITE SPIRIT. An acid is added to the waste liquor with simultaneous oxidation with air. After- wards the liquor is neutralized and fermented. Swedish Patent 31956 (1909). Chem. Abs. vol. 6 (1912) p. 2316. Ekstrom, G. UTILIZATION OF REMAINING SUBSTANCES AFTER DIS- TILLATION. In order to recover the organic matters an organic or inorganic base or a mixture of both is added to the distillation residue, which may be oxidized or reduced eventually using a contact substance previous to the treatment with basic substances. "Swedish Patent 32127 (1910). Canadian Patent 137007 (1911). Chem. Abs. vol. 6 (101*2) p. 2316. Paper vol. 10 (1912) No. 9 p. 16. Foth, G. MANUFACTURE OF SPIRIT FROM WOOD WASTE AND WASTE SULPHITE LIQUORS. Estimation of manufacturing cost. Under the present rate of taxation the manufacture is not feasible in Germany. It cannot be used for drinking purposes, as it contains large quantities of methyl alcohol and other by-products. Z. Spiritusind. (1910) p, 589. Chem.-Ztg. vol. 35 (1911) Rep. p. 35. Chem. Abs. vol. 5 (1911) p. 1970. Norton, T. H. ALCOHOL FROM SULPHITE LIQUOR. For every ton of cellulose made by the sulphite process there are 10 tons of waste lyes. Among the matters present are dextrose and various other sugars, xylose, acetic acid, tannic acid, nitrogen compounds, resins, etc., as well as the calcium lignin- sulphonate, the chief product of the reaction. Of the sugars present most are sus- ALCOHOL FROM WASTE SULPHITE LIQUOR 113 ceptible of fermentation. They constitute about 1 per cent of the lyes. The liquid is first neutralized with calcium carbonate, after which yeast is introduced. When the fermentation is complete the alcohol produced is secured in the ordinary manner. The process yields 6 gallons of alcohol (100 per cent) for 1,000 gallons of lye. About 14 gallons are secured to every ton of cellulose. Methyl alcohol and other volatile compounds are contained in this crude alcohol. It is used as denatured alcohol for heating and technical purposes. The excise rates in Sweden have been adjusted so as to aid this new industry. If the process were extended to all Swedish sulphite works the annual output would be about 3,500,000 gallons. It is doubtful whether a sufficient demand exists for this grade of alcohol to furnish a home market for such an amount. German chemists are sceptical as to the possibility of producing the alcohol econo- mically under existing conditions in the Empire, where, on a basis of the Swedish results, over 800,000 gallons could be produced Annually. United States Consular Report. J. Soc. Chem. Ind. (1911) p. 1466. World's Paper Tracle Rev. vol. 56 p. 1236. Chem. Abs. vol. 6 (1912) p. 929. Lassar-Cohn SPIRIT FROM WASTE SULPHITE LIQUOR. The alcohol legislation prevents the introduction of the manufacture of alcohol in Germany. Papier-Ztg. vol. 36 (1911) p. 677. Voerkelius. MANUFACTURE OF SPIRIT FROM CELLULOSE MATERIALS. Sulphite spirit for light and power can not be manufactured in German mills, as this spirit is subjected to taxation and would be about twice as expensive as benzine. Wochbl. Papierfabr. vol. 42 (1911) p. 853. COST OF MANUFACTURE OF SULPHITE SPIRIT. Experience in the plant at Kopmanholmen in Sweden shows the cost of 1 litre of 100 per cent spirit at a 12,000 metric ton (13,200 short tons) sulphite-mill to be 9.5-10.6 ore ($O.Q25-$0.029, equivalent to $0.114-$0.132 per gallon). By recovery of lime and sulphur this is reduced by 6-7 ore ($0.016-$0.019, equivalent to $0.073-$0.086 per gallon) giving a cost of 3-4 ore ($0,0086-$0.011) per litre ($0.04-$0.05 per gallon). The patentee, however, claims 5 ore ($.014) per litre (equivalent to $0.064 per gallon) license. Chem.-Ztg. vol. 35 (1911) p. 286. Wochbl. Papierfabr. vol. 42 (1911) p. 1440. Chem. Abs. vol. 5 (1911) p. 2942. MANUFACTURE OF ALCOHOL FROM SULPHITE-WASTE LYES. Description of Wallin's process under the following headings: (1) Composition of the lye, (2) Neutralization of the lye, (3) Graduation of the lye, (4) Separation of the lime, (5) Preparing the yeast, (6) The fermentation, (7) Results of fermentation, (8) Separating off the yeast, (9) The distillation and appar- atus, (10) The sulphite lye after distillation, (11) Pollution of rivers by the lye after alcohol distillation, (12) Cost of manufacture. .- i. Most of the figures given are based on alcohol plant at Kopmanholmen. For a 12,000-ton mill the cost of alcohol is given as A 720,000 litre production, 2-83 cents per litre of 100 per cent alcohol. 'B 840,000 litre production, 2-53 cents per litre of 100 per cent alcohol. If the profit from the reclaimed sulphur and lime which can be calculated to about 1-6-1-87 cents per litre of alcohol is also taken into consideration the actual cost of 1 litre of alcohol will be about 1 cent for 100 per cent alcohol. Pulp Paper Mag. Can. vol. 10 (1912) p. 358. 491208 114 FORESTRY BRANCH BULLETIN No. 66 Forrester, G. P. THE RECOVERY OF WASTE SULPHITE LIQUORS. Discusses Ekstrom's and Wallin's processes with regard to yield and costs. Paper vol. 6 ,(1912) No. 11 p. 15. PRODUCTION OF SULPHITE SPIRIT IN SWEDEN. The yearly production of spirit in three Swedish mills will now be 3,000,000 litres (660,000 gallons) which will be denatured with benzol. Papier-Fabr. vol. 9 (1911) p. 618. COST OF SULPHITE SPIRIT. From one metric ton (2,204 Ib.) of pulp 60-80 litres (13-2-17-6 gallons) of spirit can be manufactured at a cost of 17-18 pfennigs ($0.04-$0.043) per litre, equivalent to $0.182-$0.195 per gallon. The selling price is 45-50 pfennigs ($0.107-$0.119) per litre, equivalent to $0.486-$0.54 per gallon. Papier-Ztg. vol. 36 (1911) p. 937. Landmark, H. B. UTILIZATION OF WASTE SULPHITE LIQUOR. The lye is concentrated with an excess of an acid which forms with lime an in- soluble salt, neutralized with an insoluble salt, drawn off after the precipitate has settled, and evaporated to 30 Be. The product can be used as a ferment or as a glue for paper material. Norwegian Patent 21848 (1911). Chem. Abs. vol. 6 (1912) p. 2316. MANUFACTURE OF SULPHITE SPIRIT IN SWEDEN. The problem of using the spirit for motors is not yet solved. The manufacture cf sulphite spirit does not develop as rapidly as was expected, as its uses are still very limited. Wochbl. Papierfabr. vol. 43 (1912) p. 4829. SULPHITE SPIRIT IN SWEDEN. Uddeholms Aktiebolaz has built a motor car driven by sulphite spirit. It is hoped that it will be possible to utilize sulphite alcohol in the manufacture of artificial rubber. Papier-Ztg. vol. 36 (1912) p. 1856. Ljungberg, E. J. SULPHITE SPIRIT. The sulphite spirit is now purer than crude spirit from grain and nearly as pure as fine spirit. Sweden could with her yearly production of 700,000 metric tons (770,000 short tons) sulphite pulp (1912) produce 60 million litres (3,200,000 gallons) of normal spirit (50 per cent). The wholesale .prices are 50 ore ($0.134) per litre, equivalent to $0.61 per gallon for grain spirit, 30 ore ($0.084) per litre equivalent to $0.365 per gallon for potato spirit, and 25 ore ($0.067) per litre, equivalent to $0.304 per gallon, for sulphite spirit; therefore it cannot compete at the present time with benzine, in Sweden. Affars varlden (1912) p. 133. Papier-Ztg. vol. 36 /(1912) pp. 337, 490. Wallin, J. H ALCOHOL FROM WASTE SULPHITE LIQUOR. For one metric ton (2,204 Ib.) air-dry sulphite pulp 186.4 litres (41 gallons) of spirit (50 per cent) can be manufactured. In practice, however, only 120 litres (26.4 gallons) per metric ton (2,204 Ib.) pulp are obtained. Papier-Ztg. vol. 36 (1912) p. 1283. ALCOHOL FROM WASTE SULPHITE LIQUOR 115 Aktiebolaget Ethyl, Sweden. TREATMENT OF WASTE SULPHITE LIQl'OK FOR FERMENTATION- The lactic acid formed in. the fermentation vat sets sulphurous acid free, injuring the fermentation enzymes. After neutralization with lime (the liquor must he kept slightly acid during the fermentation) the waste .liquor is treated with ammonia CT ammonium salts. These are therehy transformed into amido-compounds, which are more valuable as nutriment for the enzyme than the ammonium salts. Previous to the aera- titn and fermentation oxidizing salts of manganese, chromium or cobalt are added to the boiling liquor, which is afterwards aerated with compressed air at 90-95 and at last in a coke tower at 25 -35 C. French Patent 446717 (1912). French Patent 446718 (i912). Chem.-Ztg. vol. 37 (1913) Rep. p. 116. J. Soc. Chem. Ind. vol. 32 (1913) pp. 133 377. Chem. Abs. vol. 7 (1913), pp. 1972, 2115. Ekstrom, G. ALCOHOL FROM WASTE SULPHITE LIQUOR. The SO2, which has a deleterious effect upon the fermentation, is counteracted by adding to the mass, before fermentation, an NH4 salt and a neutralizing agent. Swedish Patent 34623 {1912). Chem. Abs. vol. 8 (1914) p. 1669. Ekstrom, G. PURIFYING ALCOHOL FR:OM WASTE SULPHITE LIQUOR. The alcohol is freed from SO2 and aldehyde compounds by treating the alcohol vapour (during distillation) with a solution of soda, to fix the SO2 and decompose the aldehyde compounds. United States Patent 1095830 (1912). Canadian Patent 142290 (1912). Chem. Abs. vol. 8 (1914) p. 2251. Paper vol. 14 (1914) No. 22 p. 20. Ekstrom, G ALCOHOL FROM SULPHITE LIQUOR. The waste liquor from the sulphite-pulp process is treated with calcium carbonate (or similar material) and ammonium sulphate to neutralize free sulphurous acid, to convert organic compounds loosely combined with sulphurous acid into compounds innocuous to the subsequent fermentation, and to increase the quantity of nitrogenous matter in the liquor. United States Patent 1042332 (1912). Canadian Patent 142288 (1912). J. Soc. Chem. Ind. vol. 31 (1912) p. 1075 Paper vol. 10 (1912) No. 9 p. 16. Ekstrom, G ALCOHOL FROM SULPHITE LIQUOR. Urine is added to the sulphite liquor to be fermented. United States Patent 1046160 (1912). Canadian Patent 142289 (1912). J. Soc. Chem. Ind. vol. 31 (1913) p. 103. Chem. Abs. vol. 7 (1913) p. 677. Paper vol. 10 (1912) No. 9 p. 16. Wallin, J. H. THE RECOVERY OF WASTE SULPHITE LIQUOR. Mill at Kopmanholmen. Annual production of sulphite pulp 12,000 tons; daily yield of alcohol 520 gallons. Cost of production in Sweden said to be 11-2 cents per gallon. Expenses lower when large quantities of waste liquor are treated under special conditions. Cost of pulp reduced $2.65 per ton by manufacture of alcohol as a by- product. Alcohol only useful as fuel. Pulp Paper Mag. Can. vol. 11 (1913) p. 526. 4912081 116 FORESTRY BRANCH BULLETIN No. 66 Ekstrom, G. ALCOHOL FROM SULPHITE LIQUOR. As a preparatory step to the manufacture of alcohol by the fermentation of the saccharine matters of sulphite wood-pulp liquors, a catalyst for oxidation (e.g. a salt of pure Mn. Cr. or Co) and a base (e.g. CaO) are added to the liquor which is aerated while in a hot state; the solid matters are then separated, and the liquor is cooled and again aerated while cold before fermentation. United States Patent 1050723 (1913). Swedish Patent 34624 (1912). Canadian Patent 142287 (1912). J. Soc. Chem. Ind. vol. 32 (1913) p. 192. Chem. Abs. vol. 7 (1913) p. 889, vol. 8 (1914) p. 1669 Landmark, H. B. UTILIZING FERMENTABLE CARBOHYDRATES IN SUL- PHITE LYES. The sulphite liquor is treated with skimmed milk and dilute sulphuric acid, heated until casein is precipitated, and filtered. The filtrate is treated with more sulphite liquor and sulphuric acid, and heated in order to hydrolyze the lactose. The product may be used as a reducing agent or neutralized and fermented. Whey may be substi- tuted for skimmed milk and is added to the whole of the sulphite liquor at once, since no casein is precipitated. French Patent 456871 (1913). Norwegian Patent 23673 (1912). J. Soc. Chem. Ind. vol. 32 (1913) pp. 1063, 488. Chem. Abs. vol. 8 (1914) p. 822. Papir J. vol. 1 (1913) p. 15. Paper vol. 13 (1914) No. 18 p. 17. Walker W, THE PROBLEM OF THE WASTE LIQUOR FROM SULPHITE PULP-MILLS. It has been calculated that nearly two per cent of the organic material of the liquor is fermentable by yeast. The process is essentially as follows : The acid of the liquor is nearly neutralized with lime, the liquor is then aerated, and the lime sludge, consisting of calcium sulphate and part of the organic matter, is removed. The clear liquid is now treated with a special yeast cultivated for the pur- pose and a weak current of air is blown through, the liquid during the fermenting period. The fermentation is completed after four to six days. Upon distillation 1-2 per cent of alcohol by volume is obtained. The raw alcohol contains cymol, methyl alcohol, acetone, and acetaldehyde as impurities. There is considerable doubt in regard to the market for the large amount (of such a grade) of alcohol that could be made from such a tremendous supply of raw material. Further, since only about 2 per cent of the organic material is utilized, the process does not completely solve the problem of its disposal. J. Soc. Chem. Ind. vol. 32 ,(1913) p. 389. (See " General " p. 185.) Ekstrom, G. TRANSFORMATION OF CELLULOSE INTO FERMENTABLE SUGARS. Waste liquor is used for dilution in the transformation of cellulose into sugars, in order to heat and partly neutralize the acid. After the hydrolysis a new quantity of liquor is added in order to neutralize the free acid still present. Swedish Patent 33876. Chem.-Ztg. vol. 37i (1913) Nos. 31 and 32. Ekstrom, G. THE ALCOHOL LEGISLATION. A general introduction of sulphite-spirit manufacturing is made difficult by the legislation in Sweden. Svensk. Pap. Tid. (1913) p. 2258. Papir J. (1914) p. 298. Papier-Ztg. vol. 35 (1910) p. 3244 and vol. 38 (1913) p. 2258. ALCOHOL FROM WASTE SULPHITE LIQUOR 117 Aktiebolaget Ethyl and Ekstrom, G. APPARATUS FOR FERMENTATION OF LARGE QUANTITIES OF DILUTE SUGAR SOLUTIONS ESPECIALLY WASTE SULPHITE LIQUORS. Austrian Patent Application 940 (1913). Swedish Patent 35232 (1912). Foth, G. THE MANUFACTURE OF ALCOHOL FROM WOOD. Considerably more spirit can be obtained from saw-mill wastes than from waste sulphite liquor. Chem.-Ztg. vol. 37 (1913) p. 1221. Ekstrom, G. THE PRESENT SITUATION OF THE SULPHITE SPIRIT PROBLEM. The alcohol is still too expensive for motors. The value of the spirit from one cub. m. (220 gallons) of waste liquor is kr. 2.40 ($0.643). The value of the heat obtainable from 1 cub. m. (220 gallons) is at a maximum kr. 1.00 ($0.268). Svensk. Pap. Tid. (1914). Papier-Ztg. vol. 39 (1914) p. 269. Wochbl. Papierfabr. vol. 45 (1914) p. 825. THE PRESENCE OF METHYL ALCOHOL IN SULPHITE SPIRIT. The sulphite spirit contains methyl alcohol. It is possible to separate the two alcohols by distillation, but the process does not seem to be economical as the steam requirements are very high. Papier-Fabr. vol. 12 (1914) p. 947. Ekstrom, G. PURIFICATION OF ALCOHOL FROM SULPHITE LYES. Sulphite lyes and other liquids obtained by boiling cellulose materials with acid liquids are neutralized with a heavy, solid, neutralizing agent preparatory to further treatment for the production of alcohol. The solid neutralizing agent is added to the liquor in a vessel provided with a conical bottom, at the apex of which is a nozzle having helical passages. Air under pressure is supplied to the nozzle, whereby a spiral jet of air, entraining the solid reagent, is forced upward through the liquor. The neutralized liquor is drawn off near the surface through a siphon pipe supported by a float. Water under pressure may be forced through the nozzle, when desired to flush the bottom of the vessel, the flush water being drawn off through a pipe in axial align- ment with the nozzle. United States Patents 1098561 and 1098562 ,(1914). Canadian Patents 142285 and 142286 (1912). J. Soc. Chem. Ind. vol. 33 (1914) p. 785. Chem. Abs. vol. 8 (1914) p. 2803. Ekstrom, G. NEUTRALIZATION OF ACID LIQUORS. Limestone is used and a thorough mixing is effected by compressed air in a special apparatus. Swedish Patent 35706 (1912). Papier-Fabr. vol. 12 (1914) p. 727. Ekstrom, G. SULPHITE ALCOHOL IN SWEDEN. In 1912 about 4,500,000 litres (990,000 gallons) of alcohol of normal strength were produced in three Swedish mills. The producers sell to the alcohol trust at 6 cents per litre ($0-30 per gallon) absolute alcohol. Production is limited by faulty methods of distribution which make the retail price too high. Svensk. Teckn. Tid. Pulp Paper Mag. Can. vol. 13 (1915) p. 68. Chem. Abs. vol. 9 (1915) p. 1114. 118 FORESTRY BRANCH BULLETIN No. 66 Landmark, H. B. PROCESS OF MANUFACTURING ALCOHOL FROM WASTE SULPHITE LIQUOR. Previous to the neutralization and the fermentation about one-sixth of the volume of the liquor is evaporated, preferably in vacuo. Norwegian Patent 24562 (1914) Addition to 23673. Tidschrift vol. 4 (1914) p. 222. Papir J. vol. (1914) p. 186. METHYL ALCOHOL FROM THE SULPHITE PROCESS (BERGSTROM'S PROCESS). Installed in Sundsvall Cellulose Aktiebolag, Sundsvall, Sweden. The relief gases contain in the last period of the cook essential oils and methyl alcohol. Price of methyl alcohol 50 ore ($0-134) per kilogramme ($0-061 per Ib.) and with large market. The gas is conducted through condensation columns and by alternating distillation and condensation a pure product of 95 per cent is obtained. The process is continuous. In a 20,000 metric ton (22,000 short ton) mill (easy bleach), 40,000 kilogrammes (88,000 Ib.) of methyl alcohol were produced, giving a total profit of kr. 20,000 ($5,360). The cost of operation was kr. 5,700 ($1,528), which gave a net profit of kr. 14,300 ($3,832). This included depreciation and maintenance of plant amounting to kr. 8,000 ($2,144). The removal of essential oils and methyl alcohol also causes an im- provement of the liquor. Papir J. vol. 2 (1914) p. 56. Aktiebolaget Ethyl, PROCESS AND APPARATUS FOR FERMENTING LARGE QUANTITIES OF SOLUTIONS OF LOW SUGAR CONTENT, CHIEFLY WASTE SULPHITE LIQUOR. Norwegian Patent 24757 (1914). Papir J. .vol. 2 (1914) p. 263. Landmark, H, B. ALCOHOL FROM WASTE SULPHITE LIQUOR. According to Landmark's process the liquor is evaporated to five-sixths or seven- eighths of its original volume, whereby SOa is removed. The original liquor contains per 100 c.c. 2.27 grammes of sugar as dextrose; when concentrated, and after the addition of 0-33 per cent whey and neutralization with 2 grammes CaOOs per lOOrc.c., the wash contains 2.61 grammes of sugar. To 100 litres (22 gallons) of liquor about 500 c.c. (0.11 gallons) of waste brewers' yeast is added. The yield is 1-27 per cent by volume or assuming that 0-01 per cent originates from the milk sugar the liquor yields 1-26 per cent of alcohol. Wallin's and Ekstrom's methods yield 0-95-1-05 per cent. The manufacturing cost of alcohol in a mill producing 15,000 metric tons (17,000 short tons) of dry pulp, calculated on a yield of 1-2 per cent of alcohol by volume from the liquor and a recovery of 6 or 7 cub. m. (1,320-1,540 gallons) of liquor per metric ton (2,204 Ib.) of pulp, is 9-68-8-72 ore ($0.026-$0.023) per litre of 100 per cent alcohol, ($0.118-$0.105 per gallon). The use of denatured spirit for varnishes, lighting, etc., is increasing rapidly. The tax in Norway on 100-per-cent spirit is now 10 ore ($.0268) per litre ($0.122 per gallon) . Papir J. vol. 2 (1914) p. 63. Pulp Paper Mag. Can. vol. 12 (1914) p. 267. Ekstrom, G. THE SULPHITE ALCOHOL PROBLEM. The organic substances of waste liquor consist of 1-6-2-0 per cent of fermentable sugar, 6-7 per cent of precipitable substances, and 2-4-2-5 per cent of other organic substances. The liquor, therefore, contains on an average per cubic metre (220 gallons) : 18 kilogrammes (34-6 Ib.) of fermentable sugar, 65 kilogrammes (143 Ib.) of precipitable organic substances, and 24-5 kilogrammes (53-4 Ib.) of other organic substances. ALCOHOL FROM WASTE SULPHITE XIQUOR 119 If transformed into alcohol the fermentable sugar has value of kr. 2-38 ($0.638). The precipitable substances used as fuel have the value of kr. 1-3 ($0.348) per cubic metre (220 gallons). The sugar should, therefore, always be utilized before precipitation. Swedish legislation does not permit of the operation of distilleries producing taxable spirit for more than seven months yearly (October 1 to May 1) and the maximum production allowed is 600,000 litres (132,000 gallons) of 50 per cent alcohol. Denatured spirit may be manufactured in any quantity during the whole year, ^ost of the sulphite mills would produce 2,000,000 litres (440,000 gallons) of 50 per cent alcohol per year and would accordingly have to denature it all. The mills are now depending on a company which handles the whole alcohol pro- duction of Sweden. This company buys 50 per cent alcohol from the mils for 12^5 ore ($0.0336) per litre ($0.152 per gallon) and sells it for 16-17 ore ($0.043-$0.046) per litre, equivalent to $0.195-$0.21 per gallon. The retail price for 90-95 per cent alcohol is 40-75 ore ($0.107-$0.20) per litre ($0.486-$0.91 per gallon) and for 50 per cent alcohol 21-39 ore ($0.05 63 -$0.105) per litre ($0.256-$0.477 per gallon). Crude 50 per cent spirit from potatoes is paid for by the company at a price of 86-88 ore ($0.23- $0.2367 per litre ($1.05-$1.07 per gallon), that is 176 per cent of the price the sulphite- mills obtain. If the mills were allowed to produce 600,000 litres (132,000 gallons) taxable 50 per cent alcohol, they could afford to sell technical spirit without loss and be independent of the refining plants. Piapir J. vol. 2 (1914) p. 298. Landmark, H. B. UTILIZATION OF WASTE SULPHITE LIQUOK CHIEFLY WITH REGARD TO THE MANUFACTURE OF ALCOHOL- Description of Landmark's process and comparison with the Swedish method. The Wallin-Ekstrom process yields 0-7-0-95 per cent of alcohol by volume. A "tempered" yeast is used. For neutralization 11-13 grammes of CaO are used per litre (0-11-0-13 Ib. per gallon). In Landmark's process ordinary brewers' yeast can be used after addition of milk or whey and only 2-3 grammes of CaCOs are used per litre (0-02-0-03 Ib. per gallon.) for neutralization. Lignocasein is obtained as a by-product. In case of a yield of 1-1 per cent by volume and a recovery of 6-)5 cubic metres (1,430 gallons) of liquor per metric ton (2,204 Ib.) of pulp the manufacturing cost of one litre of 100 per cent alcohol is 8-5 ore ($0.0228) which is equivalent to $0.104 per gallon. This calculation includes depreciation and improvements and assumes a mill producing 15,000 metric tons (17,000 short tons) of pulp. With the cost of handling, etc., the total cost of onle litre is 10 ore ($0.0268) equivalent to $0.122 per gallon against 13-14 ore ($0.035-$0.375) equivalent to $0.16-$0.17 per gallon in the Swedish process. The residual liquor from the distillation can be worked up for fuel according to Strehlenert's process. This is not possible with the liquor from the Swedish process, due to the nature of the precipitate caused by the high lime content. Papier-Ztg. vol. 40 (1915) pp. 495, 519. Wochbl. Papierfabr. vol. 46 (1915) p. 834. Chem.-Ztg. vol. 39 (1915) p. 98. J. Soc. Chem. Ind. vol. 34 (1915) p. 275. Chem. Abs. vol. 9 (1915) p. 2709. Paper vol. 16 No. 11 (1915) p. 18. Marchand, C. PROCESS OF TREATING BY-PRODUCTS LIQUORS FROM WOOD SULPHITE PLANTS TO PRODUCE ALCOHOL. Sulphuric acid is added to the waste sulphite liquor and the major portion of the sulphur dioxide recovered while evaporating the liquor under vacuum. The remaining traces of sulphurous acid are oxidized (e.g. by the addition of a " peroxide material," K.MnO4, H2O2, Os) the acidity of the liquor is neutralized by lime, and the clear liquid decanted, after settling, and fermented to produce alcohol. United States Patent 11551256 (1915). J. Soc. Chem. Ind. vol. 34 (1915) p. 1087. Chem. Abs. vol. 9 (1915) p. 3358. 120 FORESTRY BRANCH BULLETIN No. 66 Marchand, C RECOVERING BY-PRODUCTS FROM THE RESIDUE OF WOOD SULPHITE PLANTS. The SO2 is expelled and the remaining acids in the liquor are neutralized with an alkali. The liquor is decanted and fermented and the alcohol distilled. To the residue, comminuted fuel is added and mixed, the mixture evaporated and pressed into briquettes and dried. .Canadian Patent 163400 (1915). See United States patent 1155256 (1915). Chem. Abs. vol. 9 (1915) p. 2980. Landmark, H. B. PROCESS FOR UTILIZING THE FERMENTABLE AND REDUCING CARBOHYDRATES IN SULPHITE-CELLULOSE WASTE LYES FOR OBTAINING -ALCOHOL OR A REDUCING AGENT. Addition to French Patent 456871 (1913). J. Soc. Chem. Ind. vol. 34 (1915) p. 488. E. Trainer's Heirs. UTILIZATION OF SULPHITE-CELLULOSE BACK WATER. German Patent 283931 (1911). (See "Fertilizer" p. 141.) ALCOHOL AND BENZOL FOB, AUTOMOBILES. According to v. Low experiments with a 1,360 kilogramme (2,990 Ib.) motor car with 14 metric H.P. (13.8 English H.P.) motor gave the following results: Km. Miles per Price Price per Km. Miles per Kind of Fuel. per Litre. Gal. per Litre. Gal. per Mark. dollar. Km. Miles. Pf. $ Km. Miles. Benzine a one 5-8 16-4 38-0 0-41 15-7 40-0 Benzol alone 7-1 20-0 37-5 0-406 18-9 44-3 1 part benzol -f 1 part alcohol 7-5 21-2 35-8 0-388 20-9 54-5 I part benzol -f 2 parts alcohol . . 7-2 20-3 35-2 0-38 20-4 53-5 1 part benzol + 3 parts alcohol 7-0 19-8 34-9 0-378 20-0 52-4 1 part benzol + 4 parts alcohol 6-6 18-6 34-7 0-376 19-0 49-5 1 part benzol -f 5 parts alcohol 6-0 16-95 35-5 0-384 17-3 44-2 Alcohol alone 5-4 15-25 34-0 0-368 15-8 41-4 The prices given are those that were fixed shortly after the beginning of the war. Papir J. vol. 3 (1915) p. 238. Onsager, G. T. ALCOHOL FERMENTATION OF WASTE LYES. The waste lye is subjected to alcoholic fermentation in presence of a yeast nutri- ment derived from milk sugar and made, for example, in the following manner : 1 litre of lye mixed with 1 litre of skimmed milk is slightly acidified with sulphuric acid and heated to about 50 C., the precipitate of casein and lignin compound is removed by filtration and the filtrate mixed with 299 litres of the waste lye. The mixture is boiled until about one-sixth of its volume has evaporated and the milk sugar is hydrolyzed ; the liquor is then neutralized with calcium carbonate, cooled to 28 C., and sown with waste brewers 7 yeast in the proportion of about 400 c.c. per 100 litres (0.4 gallons per 100 gallons). English Patent 24738 (1913). (See Landmark's Patent p. 116.) J. Soc. Chem. Ind. vol. 34 (1915) p. 25. Chem. Trade J. vol. 56 (1915) p. 355. Paper vol. 15 (1914) No. 21 p. 21 vol. 16 (1915) No. 7 p. 12. ALCOHOL FROM WASTE SULPHITE LIQUOR 121 THE SULPHITE-SPIRIT PROBLEM IN SWEDEN. The cost cf production of one litre of 100 per cent sulphite alcohol is on an aver- age for the whole country 18.5 ore ($0.05) equivalent to ($0.227 per gallon). One litre of ordinary denatured alcohol from this will cost 20.5 ore ($0.055) equivalent to ($0.25 per gallon), and motor spirit denatured with benzol and one-half of ordinary denaturing substance about the same. Motor fuel consisting of 100 parts of spirit and 20 parts of benzol will require a price of 19>.5 ore ($0.052&) equivalent to $0.287 per gallon. Alcohol can not compete with the cheap mineral oils used in the Diesel motor and crude-oil motors but can replace benzine in automobiles and motor-boats. The_ price of ordinary denatured alcohol is calculated to 19-5 ore ($0.0522) per litre, equivalent to $0.237 per gallon and would have the same economic value as ben- zine at a gross price of 30 ore ($0.084) per litre or $0.365 per gallon. If denatured with benzol the proportion would be that a price of 19.6 ore ($0.0525) per litre ($0.239 per gallon) of alcohol corresponds to a price of 27 ore ($0.0724) per litre ($0.326 per gallon) of benzine. The alcohol, therefore, cannot compete with benzine before the price of benzine is fixed at 27 ore ($0.0724) per litre ($0.326 per gallon) c.i.f. harbour. This would mean an increase in the operating cost of automobiles of 7-2 per cent. By special construction of the engine the increase in operating cost would amount to only 1-2-6 per cent. Alcohol is not economical for lighting purposes at this price. The Board of Trade proposes a protective import duty of 14 ore ($0.0375) per litre ($0.171 per gallon) of benzine. Papir J. vol. 4 (1916) p. 44. KIBY, W. SULPHITE-PULP WASTE LYES AND THEIR UTILIZATION FOR THE PRODUCTION OF ALCOHOL. The manufacture of alcohol from waste sulphite liquor according to Wallin's and Ekstrom's and Landmark's processes is discussed. Strehlenert's and Rmmaii's pro- cesses for manufacture of fuel are also reviewed. The author reaches the conclusion that the manufacture of alcohol from the lye must form the nucleus of any successful utilization, and that the recovery of other useful products must be made subsidiary to that object. With 8-10 parts of lye to 1 part of cellulose the fermentable sugars are at a concentration of 1-1-5 per cent and the unfermentable sugars at 0-5 per cent concentration. A higher yield than 88 litres (19-4 gallons) of 100 per cent alcohol per metric ton (2,204 Ib.) cellulose can hardly be expected. Calculations may be based on 80 litres (17-6 gallons). Points of fundamental importance are that the free SO2 must be expelled by heating, preferably in connection with a concentration of the lye, to about two-thirds its volume. The concentrated lye should be nearly neutralized with waste lime and the sludge removed, the final acidity being adjusted to the equivalent of 0-025 per cent H2&O4. It is imperative that complete attenuation should be effected with 24 hours fermentation. For this the yeast must be acclimatized to the lye and brought to the most active condition by preparation. Attenuation must be stimulated by continuous removal of CO2 and by keeping the yeast in active sus- pension. A triple effect evaporating apparatus is described in which the first and second effects are used for concentrating the lye and the last effect for concentrating the spent wash from the distillation. A distilling plant is described, capable of treating 15,430 litres (3,400 gallons) of wash per hour, producing rectified spirit of 97 per cent strength and the usual by-products, from washes used in the manufacture of bakers' yeast by the aeration process, containing no more alcohol than the fermented lye (0-77-1 -05 per cent by volume). This plant showed a consumption per 100 litres (22 gallons) of wash, of 14-15 kilogrammes (30-8-33 Ib.) of steam when producing rectified spirit and of 11-5 kilogrammes (25-3 Ib.) when making crude spirit. The cost of manufacturing alcohol from sulphite lye is estimated at 10-15 shillings ($2.44-$3.65) per hectolitre ($0.11-$0.16 per gallon) of 100 per cent alcohol. The spent wash may be used for destructive distillation or for " cell-pitch", or fodder. From the manufac- 122 FORESTRY BRANCH BULLETIN No. 66 ture of 500,000 metric tons (550,000 short tons) of sulphite pulp in Germany it is calculated that 400,000 hectolitres (8,800,000 gallons) of alcohol could be produced annually. Chem.-Ztg. vol. 39 (1915) pp. 212, 261, 284, 350. J. iSoc. Chein. Ind. vol. 34 (1916) p. 1085. Chem. Abs. vol. 10 i(1916) p. 116; vol. 9 (1915) p. 2311. Paper vol. 17 (1915) No. 15 p. 12. Hagglund. E. DIE SULFITABLAUGE UND IHRE VERARBEITUNG AUF ALKOHOL (WASTE SULPHITE LIQUOR AND ITS CONVERSION INTO ALCOHOL). A discussion of the manufacture of alcohol from waste liquor. Tr. Viemeg Sohn, Braunischweig, Germany (1915). Ekstrom, G. APPARATUS FOR FERMENTING SULPHITE-CELLULOSE LIQUOR. The liquor is supplied centrally to a fermentation vat by a pipe, which is provided at its end with an extension having horizontal discharging arms of different lengths which rotate close to the bottom of the vat, the ends being bent so as to discharge the liquor tangentially. The liquor is drawn off from the vat below the level of the spent yeast by means of a horizontal pipe provided with a valve to close its inner end, and with a vertical pipe extending upwards above the level of the healthy yeast, and open at its upper end, so that, by means of two valved discharge pipes, either fermented liquor or spent yeast may be drawn off. United States Patent 1139507 (1915). Canadian Patent 142542, 142543 (1912). J. Soc. Chem. Ind. vol. 34 (1915) p. 729. Chem. Abs. vol. 8 i(1914) pp. 2251, 2803; vol. 9 (1915) p. 1825. Hedalen, J. UTILIZATION OF SULPHITE WASTE LIQUOR. Describes the Landmark and Rinman Process. Pulp Paper Mag. Can. vol. 14 (1916) p. 176. Paper vol. 18 (1916) No. 17 p. 15. Chem. Abs. vol. 10 (1916) p. 2403. (See Landmark p. 119.) Oman, E. NEUTRALIZATION AND FERMENTATION OF WASTE SUL- PHITE LIQUOR. The author is of the opinion that a special cultivated yeast is not necessary and that aeration is of significance only in so far as it is capable of modifying the acidity of the liquor. Complete neutralization is not possible with calcium carbonate alone, the remaining acidity being equivalent to 0-05-0-06 N, varying with different lyes. Lime exerts only 40-50 per cent of its theoretical neutralizing power, apparently because some of it is precipitated with organic matter. The most favourable acidity for fermentation is that equivalent to 0-02-0-03 N. The best method is to add an excess of calcium carbonate, determining the acidity, and if it exceeds 0-Q3 N to add the calculated quantity of milk of lime. Papier-Fabr. vol. 13 (1915) pp. 534, 553. Z. angew. Chem. x vol. 28 (1915) 'Rep. p. 564. J. Soc. Chem. Ind. vol. 35 (1916) p. 172. Chem. Abs. vol. 10 (1916) pp. 3158, 527. MANUFACTURE OF SULPHITE SPIRIT IN SWEDEN. The Swedish Board of Trade has submitted a report to the iSwedish Government with proposals for encouragement of the use and manufacture in Sweden of sulphite spirit. The principle is laid down that the manufacture and sale of denatured spirit for the propulsion of motors and other technical purposes should be reserved as far as ALCOHOL FROM WASTE SULPHITE LIQUOR 123 possible to the sulphite-spirit factories, whereas the manufacture of spirits for con- sumption is to be left to factories hitherto engaged in that manufacture. Sulphite- spirit factories should be permitted to manufacture denatured spirit without restric- tion and should have the exclusive right of denaturing with benzol. It is further proposed to protect the sulphite-ispirit industry by levying on benzine a customs duty of 14 ore ($0.0375) per litre ($0.17 per gallon). Board of Trade J. Jan. 27 (1916). J. Soc. Chem. Ind. vol. 35 (1916) p. 192. Paper vol. 18 (1916) iNo. 4 p. 15. Chem. Abs. vol. 10 (1916) p. 2403. Tartar, H. V. PROPOSED METHOD FOR THE PROFITABLE UTILIZATION OF WASTE SULPHITE LIQUOR. The method is claimed to have several advantages over Ekstrom's process, among others the fact that no special yeast is required. The liquor is treated with a quantity of dilute (1:3) sulphuric acid equivalent to its content of total sulphurous acid, and is concentrated, preferably in vacuo, at a temperature not above 85 C. to half its bulk, the sulphur dioxide expelled being recovered. The concentrated liquor is treated with a small quantity of potassium permanganate (1/2 oz. to 500 gallons of original liquor) to oxidize any remaining sulphurous acid^ is made neutral to litmus by means of lime, allowed to settle, and the clear solution acidulated with 0-1 per cent of sulphuric acid and fermented with brewers' yeast for 40-60 hours at 27 C., the liquid being kept agitated. The concentrated liquor contains about 6 per cent of fermentable sugar, and the yield of alcohol ranges from 0.76-0.86 per cent by volume of the original liquor. In a properly controlled plant a yield of 1 per cent of alcohol should be attainable. The residue after distillation is not noticeably toxic to fish. J. Ind. Eng. Chem. vol. 8 (1916) p. 226. J. Soc. Chem. Ind. vol. 35 (1916) p. 483. Chem. Abs. vol. 10 (1916) p. 1268. Paper vol. 17 (1916) No. 26 p. 14. Oman, E. SUGAR FORMATION AND PRODUCTION OF DARK COLOUR- ATION IN THE SULPHITE PROCESS. Chem.-Ztg. vol. 39 (1915) p. 820. J. Soc. Chem. Ind. vol. 38 (1916) p. 172. Chem. Abs. vol. 10 (1916) p. 3158. Paper vol. 18 (1916) No. 1 p. 22. Marchand, C. ALCOHOL FROM WASTE SULPHITE LIQUOR. Description of the preparations of the Kimberly-Clark Co. to make alcohol from waste sulphite liquor. Experimental plant to give 500 gallons per day, to cost $15,000. Using Marchand process. Paper Trade J. vol. 62 No. 5 (1916) p. 201. Paper vol. 17 (1916) No. 23 p. 24. SULPHITE ALCOHOL IN SWEDEN.' According to Svensk Pap. Tid. the Swedish Pulp Manufacturers' Association has expressed the opinion that if the sulphite industry is to venture money in the erecting of alcohol plants it is necessary that the state guarantee a market and a market price which will secure depreciation and interest on the plant. Further suggestions. Pulp Paper Mag. Can. vol. 15 (1917) p. 247. Reilley, A. E. J. NEW SULPHITE MILL IN SWEDEN. At the Korsnas lumber mills work has begun on the erection of a plant to obtain sulphite spirit from sulphite lye. The yearly production will be 1,500,000 litres (334,000 Imperial gallons) and the plant will be the largest of its kind in Sweden. The Ekstrom process will be used. United (States Commerce Reports, No. 276 Nov. 24, 1917, p. 756. 124 FORESTRY BRANCH BULLETIN No. 66 Jernberg, A. V. FERMENTATION OF WASTE SULPHITE LIQUOR. The liquor is prepared for fermentation by the addition of a neutralizing agent and a suitable quantity of calcium cyariamide, previously treated with water or steam, corresponding to the need of nitrogen and the acidity of the lye. United States Patent 1221058 (1917). J. Soc. Chem. Ind. vol. 36 (1917) p. 561. Chem. Abs. vol. 11 (1917) p. 1760. Pulp Paper Mag Can. vol. 15 (1917) p. 719. Aktiebolaget Ethyl. ALCOHOL FROM WASTE SULPHITE LIQUOR. The tendency of fermenting viscose to foam in the digesting vessel is overcome, wholly or in part, by freeing it from CO2 by exposing it in a finely divided state to the action of air. Norwegian Patent 27613 (1917). Chem. Abs. vol. 11 (1917) p. 1903. Pulp Paper Mag. Can. vol. 15 (1917) pp. 765, 788. Aktieselskabet Sulfitsprit ALCOHOL FROM WASTE SULPHITE LIQUOR. To the lye is added milk, skim milk or whey, then the mass is slightly acidulated, heated, the casein-lignin precipitate filtered off, acid is added to the filtrate, and the liquid heated to hydrolyse. cooled to fermenting temperature, and fermented with ordin- ary ferment. Dutch Patent 1763 (1917). Chem. Abs. vol. 11 (1917) p. 1300. Pulp Paper Mag. Can. vol. 15 (1917) p. 541. Klason, P. THE SUGARS IN THE WASTE SULPHITE LIQUOR. The chief constituents of spruce wood are cellulose 50 per cent, carbohydrates 15 per cent, lignin 30 per cent, protein 0.7 per cent, rosin and fat 3.3 per cent. The author is of the opinion that the fermentable sugar in the waste sulphite liquor originated from- the carbohydrates. Analysis of the liquor gave the following sugars values calcu- lated on dry wood: Glucose, 7.9 per cent; mannose, 2.5 per cent; galactose, 1.3 per cent; arabinose, 4.3 per cent ;. total, 16.0 per cent. Xylose is not contained in spruce, or at most only in small quantity. Glucose and mannose ferment more easily than galactose and are apparently perfectly fermented, as the yield of alcohol usually obtained from the waste liquor is on an average 1 per cent by volume (3.8 per cent of alcohol by weight calculated on the wood or 7.6 per cent of fermentable sugars calculated on the wood) and the highest yield obtained is 1.4 per cent alcohol by volume (corresponding to 10.6 per cent of fermentable sugars, calculated on the wood). Svensk Pap. Tid. vol. 20 (1917) p. 176. (See " Composition " p. 12.) Leschly-Hansen, K. SULPHITE LIQUOR AND ITS USE FOR THE PRODUC- TION OF ALCOHOL. Extract of Hagglund's book on this subject. Papir J. vol. 5 (1917). Oman, E. PRECIPITATING ORGANIC SUBSTANCES CONTAINED IN SUL- PHITE SOLUTION. The sulphite liquors either concentrated or not are treated with substances yield- ing the radicals NH4, K, Na, Mg, or Ca, and Cl, S04, P04, and COs in such propor- tions that the liquor does not become alkaline, preferably heating the liquor and separat- ing the sugar by any preferred means. French Patent 481917 (1917). Pulp Paper Mag. Can. vol. 15 (1917) p. 1197. ALCOHOL FROM WASTE SULPHITE LIQUOR 125 Hagglund, E. WASTE SULPHITE LIQUOK AND ITS CONVERSION INTO ALCOHOL. This is a translation of "Die Sulfitablauge und ihre Verarbeitung auf Alkohol" by O. F. Bryant of the Pulp and Paper Division of the Forest Products Laboratories of Canada. Pulp Paper Mag. Can. vol. 15 (1917) pp. 1125, 1157, 1185. Paper vol. 21 ,(1917) No. 16 p. 11; No. 17 p. 16; No. 18 p. 13; No. 19 pp. 11, 20; No. 20 p. 15. PRODUCTION OF ALCOHOL FROM SULPHITE WASTE LIQUOR. A discussion as to whether it is the cellulose of the wood or the organic non- cellulose material, principally lignin, present in wood from which sugar is extracted. The sulphite lye contains in all 1-4 per cent of sugar of which 4 per cent is ferment- able. Excessive temperatures and SO2 prevent fermentation. Paper Trade J. vol. 65 (1917) 'No. 13, p. 40. Pulp Paper Mag. Can. vol. 15 (1917) p. 1118. FUEL The calorific value, of wood varies with the different species within wide limits and for spruce is found to be about 8,825 B.T.U. A high-grade sulphite pulp develops about 7,740 B.T.U. Assuming the sulphite pulp to represent 50 per cent of the wood, the solid substance of sulphite liquor from one ton of pulp would theoretically represent about 19,820,000 B.T.U. or about 1,375 pounds of coal of 14,400 B.T.U. In order to be able to utilize these substances for fuel it is necessary to separate them from the liquor and this can be done in one of two ways, either by evaporation of the water or by precipitation of the solid substances. The waste liquor from one ton of pulp repre- sents 2,000 gallons and if all this liquor could be separated from the pulp a consider- able quantity of coal would be required for the evaporation of the liquor to dryness. In the manufacture of cell-pitch it was found that one ton of coal was required per ton of cell-pitch of 10 per cent moisture-content. But the cell-pitch having a calorific power of only about 6,300 B.T.U. as against 12,600-14,400 B.T.U. for coal the scheme of direct evaporation would mean a considerable loss in fuel value. If modern multiple effect evaporators could be used for sulphite liquors, a surplus in fuel corresponding to about 500 pounds coal might possibly be obtained if all the liquor were recovered. But this is impossible. Assuming a maximum of 1,000 gallons of liquor per ton of pulp an amount of fuel corresponding only to 250 pounds of coal could be obtained per ton of pulp. This figure might possibly be increased considerably by employing evaporators of high efficiency utilizing the vapours from the evaporating liquor. The idea of Strehlen'ert's process for the recovery of "fuel from waste sulphite liquor is based upon the decomposition of the sulphur compounds of the lignin with sulphuric acid at high temperature and pressure. The sulphuric acid is formed by oxidation of the free SO2 by air or oxygen. The ash content of the fuel is decreased by a previous treatment of the liquor with sodium bisulphate whereby the calcium can be recovered as sulphate. Details of the. process are contained in the abstracts of literature given below. Since the first patents were granted Strehlenert has investigated and improved the process. It was noticed that the presence of small quantities of iron, zinc, man- ganese or other hydrogen-forming metals decreased the yield considerably and that a precipitation was almost impossible when as much as 0-004 per cent or more iron was present. According to the patent the oxidation begins at a comparatively low tem- perature whereas the decomposition takes place at a high temperature and pressure. By introducing the air at a higher temperature the oxidation and decomposition take place simultaneously, and so rapidly that the action of the metal is eliminated. In order to avoid oxidation of sulphurous acid during heating to the temperature of decomposition, relief %ases from the sulphite-mill (containing SCte) are introduced, so that a pressure of one or two atmospheres is secured from the beginning. The sul- phuric acid is then formed at the critical temperature according to the equation 3 S0i> = 2 80s + S, and theoretically no air is required. However, the introduction of air is always favourable as it causes the organic compound to precipitate in a coarser and more easily filtered form than without air. The sulphur formed according to this reaction sublimes and this as well as the excess of sulphurous acid which is set free during the decomposition of the sulphonic acid can be recovered. The relief gases also contain hydrogen sulphide which can be recovered and utilized in the pulp-mill. Under these working conditions only very little sulphuric acid is formed, so that after the reaction the liquor contains only from 0-2 to a maximum of 0-4 per cent total acid with 0-02 per cent free acid. When oxidation is allowed to take place at the early stage of process (at low temperature) the residual liquor contains up to 1-5 per FUEL FROM WASTE SULPHITE LIQUOR 127 cent sulphuric acid. A high sulphuric acid content is injurious to the autoclave and often makes the precipitate gelatinous and decreases its calorific value. It is therefore important that the oxidation take place as near the critical temperature as possible. According to the first method of operation the precipitation was effected by oxidation of SO2 to SOs. The free SO 2 present in the liquor (often only 0-1) was sufficient to introduce the reaction of decomposition of the lignin compound. The reaction of the inorganic substances is then: S0 2 + O = or finally 4 CaSOs => 3 CaSO4 + CaS. As copper autoclaves were used first copper oxide and finally copper sulphate were formed according to the following reaction: CuSO4 + CaS = OaS04 -f CuS, which gives with sulphuric acid OuS + 2H2 SO 4 = CuSO 4 + SO 2 + S + 2 H 2 O. The action of the copper, therefore, is advantageous as it causes the direct for- mation of fresh quantities of SO 2 , but this reaction, of course, is injurious to the autoclave and at the present time the autoclaves are made from iron and have a lead lining. The reaction in this case can be expressed by the following equations: 4 CaSOs=3 CaSO 4 + CaS + H 2 SO 4 = CaS04 + H 2 S. The formation of hydrogen sulphide may be regarded as a disadvantage but the new process requires only 20 to 25 per cent of the air used in the former process. This means that the autoclave can be charged to 75 per cent of its volume with liquor, while formerly only 60 per cent of the autoclave volume could be utilized. With regard to the yield it was stated that only about 75 per cent of the total solids are precipitated, and Strehlenert concludes that the portion precipitated consists of com- pounds of sulphinic acid while the remaining 25 per cent which are only precipitated with difficulty are sulphonic acid compounds. According to Strehlenert the remaining 25 per cent can be obtained by the addition of peat to the liquor. In calculating the yield per ton of pulp Strehlenert assumes that 1,200 gallons of waste liquor will drain off per ton of pulp and that by employing diffusers 1,800 gallons can easily be recovered. It is a fact, however, that only about 740 gallons of liquor will drain off from the blow-pits per ton of pulp, although 800 gallons can probably be obtained if the draining is continued for a longer period. Assuming that 800 gallons are recovered and that the liquor contains on an average 11 per cent solid substances, 880 pounds of dry substance are present in the liquor from one ton of pulp, of which a maximum of 880x0-75 = 660 pounds are precipitated, while 880x0-25 = 220 pounds remain in the liquor and can be recovered by precipitation in the presence of small quantities of peat. Diffusers provided with suction pumps remove the water from the precipitate up to 3.5 per cent. The ash content is about 17-18 per cent, if the liquor has not previously beer^ treated with sodium bisulphate or has not been concentrated. The fuel, free from ash and water, develops on an average 12,240 B.T.U. If the fuel contains 50 per cenft moisture the calorific value of the precipitate obtained per ton of pulp will amount to approximately 5,800,000 B.T.U., corresponding to about 400 pounds of coal of 14,400 B.T.U. This fuel-value will of course increase with the quantity of liquor which can be removed, and for 1,200 gallons per ton is equal to about 600 pounds of coal. In regard to the heat required in the process, according to Strehlenert, the heat developed in the reaction, should theoretically cover the heat requirements for raising the temperature of the liquor from 212-392 F., but disregarding this the heat requirements in the process when autoclaves of 2,200 gallons capacity are used would be: Heating of the metal of the autoclave about 180 F., approximately 436,480 B.T.U. Heating of 1,650 gallons liquor about 180 F., approximately 2,976,000 B.T.U. Total heat requirement, 3,412,480 B.T.U. 128 FORESTRY BRANCH BULLETIN No. 66 This figure, however, represents the heat required for one single cook. When several autoclaves are combined so that the excess heat from one cook can be utilized in the other autoclaves at least 50 per cent of the heat is saved, and assuming an efficiency of 80 per cent for the boiler and a calorific value of 14,400 B.T.U. for the coal the heat required for 1,650 gallons of liquor will be : 1706240 B. T. U. 14400 x 0-8 or, for 800 gallons, 72 pounds, and for 1,200 gallons, 108 pounds coal. This gives an actual yield of fuel per ton of pulp corresponding to 328 or 492 pounds coal having a calorific value of 14,400 B.T.U., depending upon whether 800 or 1,200 gallons of liquor are recovered. An estimation of operating costs for the production of fuel is made by Strehlenert fcr a plant in Scandinavia operating 3 autoclaves of 2,200 gallons volume in handling the liquor from a yearly production of 17,000 -metric tons (18,733 short tons) of pulp, assuming a recovery of 1,320 gallons of liquor per metric ton (1,200 gallons per short ton). The operating cost for one metric ten of fuel recovered is according to these calculations kr. 11.79 ($3.17) equivalent to $2.88 per short ton. This fuel however is of an inferior quality containing about 18 per cent ash and is generally used in a moist condition. Considering- these two points the price of the fuel would be equivalent to a price of about $5.25 per metric ton of good coal of 14,400 B.T.U. ($4.75 per short ton). Strehlenert further assumes the most favourable con- centration of the liqucr, namely about 17 per cent solid substances, which is very near the concentration of the liquor obtained by indirect heating and forced circulation. Assuming a concentration of 11 per cent the yield per autoclave charge will be considerably lower, and considering the higher cost of labour, etc., on this continent the price per ton of coal recovered will be $7 and $7.50 on the basis of a 30,000- metric-ton (33,075 short tons) mill and recovery of 1,320 and 880 gallons of liquor respectively per metric ton of pulp (1,200 and 800 gallons respectively per short ton). The calculations are as follows: In case of 880 gallons of liquor per metric ton (800 gallons per short ton) of pulp, 726 pounds of fuel, equivalent to 440 pounds of coal (14,400 B.T.U.) are obtained per metric ton of pulp (660 pounds of fuel, equi- valent to 400 pounds of coal per short ton). Eighteen per cent of this fuel is used in the process, leaving 361 pounds of ccal as actual yield per metric ton (328 pounds per short ton). The fuel recovery from a 30,000-metric-ton (33,075 short tons) mill would therefore correspond to 4,920 metric tons of coal per year (5,425 short tons). Four autoclaves are required, and 7 men in 3 shifts for their operation. The cost of build- ings is placed at $55,000 and the cost of apparatus at $89,000. Assuming a deprecia- tion of the buildings of 10 per cent and of the apparatus of 15 per cent the operating cost for the production of one ton of coal (14,400 B.T.U.) will be: Depreciation of buildings Metric tons $1 12 Short tons $1 02 Depreciation of apparatus 2 71 2 46 Labour 3 17 2 87 Power 02 02 Repairs 50 45 Total cost per ton of coal $7 52 $6 82 In case of 1,320 gallons of liquor per metric ton of pulp (1,200 gallons per short ton) fuel corresponding to 540 pounds of coal is obtained (492 pounds per short ton). Six autoclaves are required operated by 9 men in 3 shifts. The operating cost calculated as above is found to be about $7 per metric ton of coal ($6.35 per short ton). This very high cost might be considerably reduced by employing liquor from the Morterud process, which will increase the yield per autoclave as will also the addition of a small quantity (0.25-0.5 per cent) of peat in the decomposition process. The recovery of by-products such as acetone, acetic acid, formic acid, and methyl alcohol may also FUEL FROM WASTE SULPHITE LIQUOR 129 reduce the cost of the fuel considerably. Plans have been made to dry-distil the pre- cipitate of organic substances, using the residual coke for fuel. Very recently Landmark has proposed a modification of this process in which ozone is formed from the air in the upper part of the autoclave by an electric spark. The temperature and pressure required in the process should in this way be appreciably decreased. A discussion is at present going on between the two inventors which pro- bably will lead to interesting results. Dorenfeldt, L. J. WASTE LYES FROM CELLULOSE MILLS. The author claims that there is sufficient heat value in the organic substances of the waste liquor for evaporation and incineration and still a surplus of calorific power equal to about 58 kilogrammes (128 pounds) of good coal per cubic metre (220 gallons). Papier-Ztg. vol. 23 (1898) p. 1652. J. Soc. Chem. Ind. vol. 17 (1898) p. 788. Dorenfeldt, L, J. PROCESS FOR UTILIZING WASTE LIQUORS FROM THE MANUFACTURE OF PULP FROM WOOD, ESPARTO, ETC., AS A FUEL BY SPRAYING THROUGH NOZZLES. The liquors are evaporated to such an extent (40-50Be) that they can be atomized in a hot condition and after filtration. German Patent 122489 (1898). Austrian Privilegium 4602 (1898). Papier-Ztg. vol. 26 (1900) part I p. 2602. Chem. Zentr. (1900) part II p. 248. Cremer, B. (from Dorenfeldt, L. J.) APPARATUS FOR UTILIZING WASTE LIQUORS AS FUEL. English Patent 11974 (1898). J. Soc. Chem. Ind. vol. 18 (1899) p. 702. Dorenfeldt, L. J. HEAT VALUE OF WASTE LIQUORS FROM PULP MANU- FACTURING. Papier-Ztg. vol. 24 (1899). Nemethy, E COMBUSTION VALUE OF WASTE SULPHITE LIQUOR. Zentr. oesterr.-ung Papierind No. 18 (1903). Papier-Ztg. vol. 28 (1903) p. 1897. Trainer, E.GAS AND COKE FROM SULPHITE LIQUOR. The waste lyes are evaporated to dryness with the addition of compounds of the alkalies or alkaline-earths and of finely-divided lignite or low-grade coal, and the residue is formed into briquettes and carbonized. Claim is also made for the addition to the lyes of such substances as will produce slag during the carbonization process and thus render the coke stronger. German Patent 181126 (1905). Papier-Ztg. vol. 32 '(1907) p. 994. Wochbl. Papierfabr. vol. 38 (1907) p. 1307. J. Soc. Chem. Ind. vol. 26 (1907) p. 1272. Kayser H. PROCESS FOR EVAPORATING WASTE SULPHITE LIQUOR AND UTILIZING THE RESIDUES FOR FUEL. Papier-Ztg. vol. 35 (1910) p. 768. Stora Kopparbergs Bergslags Aktiebolag. HUMUS-LIKE SUBSTANCES FROM SULPHITE LYES. After the manufacture of alcohol from sulphite liquor or similar waste lyes from the treatment of cellulosic materials with acids, the residual liquor is treated with a 491209 130 FORESTRY BRANCH BULLETIN No. 66 basic substance, such as lime, to recover the humic substances; the amount of lime may be only sufficient to produce a feebly-alkaline solution, in which case its action may be intensified by passing air through the mixture after addition of a small quan- tity of an oxygen carrier, such as a manganese salt. The products may be used as fuel. 'German Patent 256,964. Papier-Ztg. vol. 37 (1913) p. 768. Papier-Fabr. vol. 11 (1913) p. 342. J. Soc. Chem. Ind. vol. 32 (1913) p. 421. Chem. Abs. vol. 7 (1913) p. 2472. Strehlenert, R. W. PKOCESS FOE OBTAINING THE ORGANIC AND INOR- GANIC CONSTITUENTS OF SULPHITE LIQUOR. The sulphurous acid in the waste liquors is oxidized by heating in an autoclave to a high temperature under pressure, in presence of air or oxygen, whereupon the sul- phuric acid formed precipitates the lignin substances. Before the oxidation process, a soluble acid salt such as sodium bisulphate (1-5-2-1 per cent) may be added to the waste lye. The precipitated substance may be used as a fuel, having a calorific value of 6,000-7,000 calories (10,600-12,600 B.T.U.) It is stated that the solution which remains is so free from solids that it can be safely run into any drain or stream. Swedish Patent 34941 (1912). Norwegian Patent 24140 (1912). German Patent 266096 (1912). Canadian Patent 151445 (1913). United States Patent 1149420 (1915). Papier-Fabr. vol. 9 (1913) p. 666. J. Soc. Chem. Ind. vol 33 (1913) p 1104, vol. 34 (1915) p. 957. Chem. Abs. vol. 8 (1914) p. 572. Paper vol. 17 (1915) No. 2 p. 19. Paper Trade J. vol. 63 (1916) (No. 19 p. 64. Strehlenert, R. W UTILIZATION OF WASTE SULPHITE LYE. Pulp Paper Mag. Can. vol. 11 (1913) p. 452. Chem. Abs. vol. 7 (1913) p. 3022. Strehlenert, R. W RECOVERY OF S0 2 , CAS0 4 , AND FUEL FROM SULPHITE LYES. The chief organic constituent of the waste lyes is the calcium salt of lignosulpho- nic acid; this is soluble in water and is decomposed in acid solution at a high tempera- ture in presence of air, yielding sulphuric and sulphurous acids and insoluble lignin. It is necessary to regulate the temperature and quantity of air to avoid carbonization of the precipitated lignin on the one hand and its formation in a gelatinous condition on the other hand. Under suitable conditions the lignin is precipitated in a granular form, which is easily separated and dried for use as a fuel; this fuel has a heating value of 7,000 calories (12,600 B.T.U.) calculated on the ash-free substance. In order to obtain the lignin as free from ash as possible, the calcium should first be precipi- tated by sodium bisulphate. The hot lyes from the digesters are treated with 1.5-2 per cent of sodium bisulphate and the calcium sulphate is separated and dried for sale. The clear solution of sodium ligninsulphonate is charged into pressure vessels to about 60 per cent of their total capacity and heated to 100 C. Air is then fojrced in up to a pressure of about 18 atmospheres (270 lb.). The temperature rises about 20C. as the result of the reaction and is slowly raised to 150 C. The sulphurous acid liberated from the lye is oxidized to sulphuric acid which induces the decomposition of the lignin salt between 160 and 170 C. After a temperature of 200 C. or higher has been reached, w T hich should be in about 40-60 minutes measured from the time of starting from 100 O, digestion is finished. At the critical moment when decomposi- tion sets in (160-170) the pressure in the vessel rises very rapidly and the sulphur dioxide is liberated and blown off through absorption towers for recovery. At the close of the heating period a feeble current of air must be blown through the liquid in order FUEL FROM WASTE SULPHITE LIQUOR 131 to granulate the precipitate. This air, together with the excess of steam, is utilized to heat the contents of a second digester. The precipitate of lignin is washed and drained in the centrifuge until it contains about 50 per cent of water. It may be dried further by a convenient source of waste heat but should retain 20 per cent of moisture when used for fuel, as when dry it burns too rapidly. From the manufac- ture of one metric ton (2,204 pounds) of cellulose about 10 cubic metres (2',000 gal- lons per short ton) of lye are obtained, containing, when the digestion is performed with indirect steam, 11.6 per cent of dry substance. From such a lye there were recovered 5-6 grammes of sulphur dioxide per litre, the original waste lye containing 8.6 grammes per litre. This corresponds to a recovery of 25-30 kilogrammes of sul- phur per metric ton (2,240 Ib.) of pulp (50-60 Ib. per short ton). There were also obtained, with a heating of 65 minutes, 74 grammes of dried lignin precipitate per litre (0.74 Ib. per gallon). The final waste liquor contained 0.19 per cent of sugars. The cost of treatment is estimated at about kr. 5 per metric ton (2,204 Ib.) of lignin ($1.22 per short ton). The quantity of lignin recovered is capable of furnishing, the whole of the fuel requirements of the pulp-mill. In addition there are obtained 140- 150 kilogrammes of commercial calcium sulphate per metric ton (2,204 Ib.) of cellu- lose produced (280-300 Ib. per short ton). Svensk Kem. Tid. vol. 25 (1913) p. 78. Papier-Fabr. vol. 11 (1913) pp. 646, 666. J. Soc. Chem. Ind. vol. 32 (1913) p. 652. Chem. Abs. vol. 7 (1913) p. 2471. Pulp and Paper Mag. Can. vol. 11 (1913) p. 7(78 vol. 12 (1914) p. 46. f Paper vol. 12 (1913) No. 9 p. 18. Strehlenert, R. W SULPHUK FKOM WASTE LIQUOR By Strehlenert's process a sulphite mill of 20,000 metric tons (22,050 short tons) production will save 100,000 kilogrammes (220,000 Ib.) of coal, assuming a price of kr. 15 ($4.02) per metric ton ($3.65 per short ton) and a coal consumption of 0-5 ton per ton of pulp. Svensk Kem. Tid. (1913) p. 78. Chem.-Ztg. vol. 37 (1913) Kep. p. 605. Wochbl Papierfabr. vol. 44 (1913) p. 4142. (See " Sulphur " p. 154.) Strehlenert, R. W. FUEL FROM WASTE SULPHITE LIQUOR. Description of process. Papier-Ztg. vol. $9 (1914) p. 414. Ekstrom, G. REMOVAL OF ORGANIC CONSTITUENTS FROM SULPHITE LIQUORS AFTER FERMENTATION. United States Patent 1087356 (1914). Briggs J F STREHLENERT'S PROCESS FOR TREATMENT OF SPENT ' SULPHITE LYES. Description of Strehlenert's process. Chem. World vol. 2 (1914) p. 346. Chem. Abs. vol. 8 (1914) p. 1204. Paper Maker Brit. Trade J. Annual 'No. 1913-14 p. 66. Paper vol. 13 (1913) No. 11 p. 21. Landmark H. B.-UTILIZATION OF WASTE SULPHITE LIQUOR CHIEFLY WITH REGARD TO THE MANUFACTURE OF ALCOHOL. The original liquor contains 60-80 grammes of lignin and small amounts of other organic matter per litre. (0-6-0-8 Ib. per gallon). The liquor may be evaporated and cell-pitch obtained. The mash from the alcohol distillation is concentrated to 75 per cent of its original volume and contains approximately 115 grammes of dry substance 49120 9i 132 FORESTRY BRANCH BULLETIN No. 66 per litre (1-15 Ib. per gallon). One cubic metre 0220 gallons) of waste liquor would then give 63-8 kilogrammes (140-3 Ib.) of air-dry cell-pitch. This is equivalent to 57-4 kilogrammes (126.3 Ib.) of absolutely dry cell-pitch as 37.6 kilogrammes (82-8 Ib.) of cell-pitch are required for the evaporation of water from 1 cubic metre (220 gallons) of wash, and 20 kilogrammes (44 Ib.) of sugar are removed in the fermentation process. 115 (20+37-6)=57-4 kilogrammes (126-3 Ib.) The heat value of cell-pitch is ,3,500 calories (6,300 B.T.U.) With a heat value of 6,000 calories (10,800 B.T.U.) for coal 63-8 kilogrammes (140-3 Ib.) of cell-pitch is AQ ft v Q t\ClC\ equal to ' ' =37-2 kilogrammes (82-8 Ib.) of coal. o,000 If 10 cubic metres of liquor can be recovered from 1 metric ton (2,204 Ib.) of pulp (2,000 gallons per short ton), 372 kilogrammes of coal of 6,000 calories (10,800 B.T.U.) is recovered from 1 metric ton (2,204 Ib.) of pulp (742 Ib. per short ton). But the cell-pitch contains all the organic substance of the liquor and may be used for other purposes as well. Strehlenert's method is described. This gives the same result with the mash as with the original liquor. Waste liquor gives by this process 60-90 grammes lignin substance per litre (0-6-0-9 Ib. per gallon). In this no subtraction is made for fuel required. This would be less than the cell-pitch obtainable, as in the latter case all the organic sub- stances are contained in the product. Wochbl. Papierfabr. vol 46 (1915) p. 843. Murbe, E. FUEL FROM LIGNIN PRECIPITATED FROM SULPHITE LIQUOR. Lignin is removed from the autoclave by rinsing with water and is freed from acid at the same time. The wet mass is dehydrated by filtering and treatment with hot flue-gases which are then directed against the furnace walls by means of a blower. Swedish Patent 41542 (1916). Chem. Abs. vol. 11 (1917) p. 535. Kjaer, A. H. & Co. DISINTEGRATING WASTE SULPHITE LIQUOR. Indirect heating is combined with direct heating so that the temperature of the liquor is first brought, by indirect heating, to a point where disintegration products are precipitated on highly heated surfaces, whereupon heating is continued by direct steam. Norwegian Patent 27637 (1917). Chem. Abs. vol. 11 <1917) p. 1902. Pulp Paper Mag. Can. vol. 15 (1917) p. 741. METHOD FOR PRECIPITATING THE, ORGANIC MATTER IN WASTE SULPHITE LIQUOR. A new method for precipitating the organic substances is proposed by H. B. Land- mark. The method is described and compared with Strehlenert's method. The two methods have the same principle, Landmark using ozone where Strehlenert used air or oxygen. The ozone is produced by means of. electric sparks in the upper part of the autoclave. The pressure is hereby reduced to 10-14 .atmospheres and no H2SO4 is required. Landmark uses a copper autoclave with a pressure of 2-5 atmospheres and a voltage of 10,000 volts. After 1 hour's boiling at 11 atmospheres the process was finished, and the black powder obtained yielded 60 grammes per litre of sulphite liquor. Instead of producing ozone in the autoclave it can be introduced into the autoclave at the required temperature and pressure. Papir J. vol. 4 (1916) No. 22, p. 260. Svensk Pap. Tid. (1916) No. 23 p. 25. Pulp Paper Mag. Can. vol. 15 (1917) p. 88. FUEL FROM WASTE SULPHITE LIQUOR 133 Landmark, H. B. PRECIPITATING ORGANIC SUBSTANCES IN WASTE SULPHITE LIQUOR. Waste sulphite liquor is reacted upon by H2SO4, produced in the liquor by oxid- izing its SO2 content with ozonized air formed by the discharge of electric sparks under pressure in the vessel containing the liquor. This effects the precipitation of organic substances, under a pressure of 6-7 atmospheres. United States Patent 1236948 Aug. 14 (1917). Chem. Abs. vol. 11 p. 2963. J. Soc. Chem. Ind. vol. 36 (1917) p. 1092. Landmark, H. B. METHOD FOR PRECIPITATING ORGANIC MATTERS IN WASTE SULPHITE LIQUOR- Answer by Landmark to Strehlenert: Landmark calls attention to the fact that Strehlenert in the demonstrations of his process has used 20 atmospheres pressure and 200 C. and that these figures are also used in the description of his .Norwegian patent. Even when copper sulphate was used as a catalyst, a pressure of 20 atmospheres was necessary. Landmark says that a precipitation of the lignin is possible at 7-9 atmos- pheres (2 per cent of the liquor) and Landmark has at this pressure obtained a product which can easily be filtered and washed. The precipitate may in that case be a little carbonized and the yield somewhat lower but the lower yield is then balanced by the better quality of the product, the fuel value being higher. The yield depends on the amount of solid matter in the liquor. Analysis of liquor from one mill gave 100-123 grammes per litre. With 100 grammes of solid substance, the liquor contained chiefly 14 grammes of ash and 18 grammes of sugar per litre. The rest is chiefly lignosul- phonic acid, and 60 grammes will be the maximum yield obtainable. Landmark obtained 60 grammes in a demonstration of his process. The gypsum in this test was previously removed with sodium sulphate. Landmark claims in his new patent the use of electric sparks for the ozonizing of the oxygen in the air. Papir. J. vol. 4 (1916) No. 24 p. 279. Pulp Paper Mag. Can. vol. 15 {1917) pp. 88, 101. Strehlenert, R. W. METHOD FOR PRECIPITATING ORGANIC MATTERS IN WASTE SULPHITE LIQUOR. Answer by Strehlenert to Landmark: Strehlenert claims that the oxidation of S02 in his process takes place at a temperature a little higher than 100 C. and a very little above atmospheric pressure. The addition of HaS04 is only required when autoclaves of other material than copper are used, and even then only if the S02 content of the liquor is very low or when the liquor had previously been neutralized. Strehlenert has, however, worked out a method by which even in such cases the small amount of H2SO4 (0-1-0-5 per cent) used for starting the reaction is made unneces- sary. The oxidation from S02 to SOa with oz6ne has been closely studied by Streh- lenert, who claims the method will be only of theoretical value. Even if the ozoniz- ation were practically possible the operation would hardly be cheaper than pressing some air into the autoclave and oxidizing at 4-5 atmospheres. With Landmark's process 60 grammes of precipitate were obtained per litre of liquor but the ash content was notgiven. This must be 22 per cent if the liquor has not been previously treated. By decomposition of the same kind of liquor Strehlenert has obtained between 87 and 98 grammes per litre and with an ash content up to 7 per cent when using his own method. Papir J. vol. 4 (1916) No. 23 p. 269. Pulp Paper Mag. Can. vol. 15 (1917) pp. 101, 88. Landmark, H. B. Strehlenert, R. W. METHOD FOR PRECIPITATING OR- GANIC SUBSTANCES FROM WASTE SULPHITE LIQUOR. In a continued discussion of the two processes Landmark makes the statement that with his process the oxidation of S02 to SOs can be effected at ordinary tempera- 134 FORESTRY BRANCH BULLETIN No. 66 tures and pressures, and that the decomposition of the lignin compounds takes place at less than 12 atmospheres whereas Strehlenert uses 20 atmospheres in his process. Arrangements will now be made to demonstrate the two processes in presence of both inventors. Papir J. vol. 5 (1917) pp. 36, 37. Pulp Paper Mag. Can. vol. 15 (1917) p. 449 (See this magazine, vol. 15 [1917] pp. 88, 101, 140, 343). Strehlenert, R. W. PROCESS FOR PRECIPITATING ORGANIC SUB- STANCES IN WASTE SULPHITE LIQUOR. In a continued discussion with Mr. Landmark (see Pulp Paper Mag. Can. vol. 14, 1916, p. 140) the statement is made that the oxidation of the SO2 to iSOs takes place, even when no ozone is present, at a low temperature and pressure (5-7 atmospheres). However, the critical temperature at which the decomposition of the liquor takes place is, under ordinary conditions, at about 190-195 C. and at the corresponding steam pressure (14 atmospheres), but it is more economical to raise the pressure a little higher. It is possible to decompose the liquor at a lower temperature when the neces- sary amount of H2S04 (2 per cent) is present, but this high acid content can never be obtained by oxidation of ordinary sulphite liquors as these contain a maximum of 0-1 per cent free SO2, and not all combined S02 can be oxidized. The formation of ozone can not increase the amount of sulphuric acid as this, in the first place, depends upon the available S02 in the liquor. In cases where the liquor has previously been used for the manufacture of spirit no free SO2 is present, and it will in any case be necessary to add a small amount of sulphuric acid. Papir. Jr-vol. 5 (1917) p. 14. Pulp Paper Mag. Can. vol. 15 (1917) p. 343'' See also vol. 15 (1917) pp. 88, 101, 140. FUEL BRIQUETTES FROM SULPHITE LYE. A Norwegian-Swedish company formed with capital of $426,667 to purchase and use Strehlenert's patent for fuel briquettes. Pulp Paper Mag. Can. vol. 12 (1914) p. 97. STREHLENERT'S PROCESS OF EXTRACTING FUEL FROM WASTE SUL- PHITE LIQUOR. General description of the process, estimation of cost of production, and yield. Translation from Papier-Ztg. Paper Trade J. vol. 45 (1917) No. 7, p. 36. Paper Makers' Mon. J. vol. 55 (1917) p. 284. Pulp Paper Mag. Can. vol. 15 (1917) p. 1073. STREHLENERT'S SULPHITE-FUEL PROCESS IN SCANDINAVIAN MILLS. In addition to plant at Greaaker, Norway, for manufacture of fuel from waste sulphite liquor,, according to Strehlenert's process, two Swedish companies are also installing the process in their mills. Several Swedish mills intend to install the process but the machinery cannot be delivered at present. Svensk Pap. Tid. (1917). Pulp Paper Mag. Can. vol. 15 (1917) p. 343. J. Ind. iEng. Chem. vol. 8 (1916) p. 1070. Strehlenert, R. W. PROCESS FOR EFFECTING A CHEMICAL DECOMPO- SITION OF WASTE SULPHITE LIQUOR. The liquor is heated indirectly by steam coils to a temperature at which the decomposition products are not appreciably precipitated on the highly heated coils. The final heating is effected by direct steam. Norwegian Patent 27637 (1917). Pulp Paper Mag. Can. vol. 15 (1917) p. 789. FUEL FROM WASTE SULPHITE LIQUOR 135 Reilley, A. E, J. (United States Vice Consul at Stockholm) UTILIZATION OF SULPHITE LYE IN SWEDEN. At the laboratory of the Reymerholm Company (Reymerholms Gamla Sprit- foradlings A.B.) experiments have recently been completed with a new method for the utilization of refuse lye in the manufacture of sulphite. The difficulty in using the lye has consisted in concentrating it. By the new method the water is removed by freezing, which eliminates four-fifths of the water. The method is cheaper than that formerly employed and is considered to involve a reduction of the expenses by about 40 per cent. While the older method is based on the use of steam, water-power is used for the new. By this method, also, the organic substances in the lye are obtained in such a form that they can be used in many ways for dyestuffs, agglutinative sub- stances, etc. United States Commerce Reports, No. 281 (1917) p. 843. Pulp Paper Mag. Can. vol. 15 (1917) p. 1220. Strehlenert, R. W, FUEL FROM WASTE SULPHITE LIQUOR. The author reports on a number of improvements in the process of precipitating organic substances in waste sulphite liquor. Discussion of the chemical reactions that take place, heat requirements, and cost data. Svensk Pap. Tid. vol. 20 (1917) No. 11 p. 128; No. 12, p. 144; No. 13, p. 158. CARBONIZATION PROCESS FOR SULPHITE WASTE. Waste liquor is evaporated to dryness and powdered to give 98 per cent through a 200-mesh screen. This fine material is burnt similarly to powdered coal. The fuel feed varied from 0-78 to 1 Ib. per minute. Gas samples drawn from combustion chamber and along flame passages showed a furnace temperature of approximately 2,100 degrees. Tests were carried out at the demonstration plant of the Powdered-Coal Engineering anSoc. Chem. Ind. vol. 36 (1917) p. 870. Paper Makers' Monthly J. vol. 55 (1917) p. 303. Kuhn, A. D. J. RECOVERY OF SO 2 IN SULPHITE COOKING. Deals with three different types of recovery system in sulphite cooking 1 . Wochbl. Papierfabr. vol. 47 (1916) pp. 2139, 2179, 2233, 2270. J. -Soc. Chem. Ind. vol. 36 (1917) p. 639. Chem.-Ztg. vol. 41 (1917) Rep. p. 148. Paper vol. 20 (1917) No. 24 p. 13. Pulp Paper Mag. Can. vol. 15 (1917) pp. 857, 1009. Landmark, H. B METHOD AND APPARATUS FOR RECOVERY OF FREE SO 2 FROM WASTE SULPHITE LIQUOR WITH SIMULTANEOUS CONCENTRATION OF THIS BY MEANS OF ITS LATENT HEAT. ' Norwegian Patent 28147 (1917). (See " Evaporation " p. 162.) 4912011 EVAPORATION Novak, J. PKOCESS FOR EVAPORATION OF SULPHITE LIQUOR IN VACUO. Liquor evaporated in multiple effects. This has not as yet been possible on account of the great foaming. This is overcome by saturating with quicklime, then with C02, and filtering off the precipitate. German Patent 74031 (1893). Ber. vol. 27 (1898) p. 474. Papier- Ztg. vol. 19 (1894) p. 1196. Kumpfmiller, A. and Schultgen, E. PROCESS FOR CONCENTRATING WASTE SULPHITE LIQUOR AND RECLAIMING FREE AND COMBINED SULPHUROUS ACID. The roast gases from the pyrites furnaces are conducted into the waste liquors which have not previously been neutralized. In this way the sulphuric acid is also removed from the roast gases. The waste liquor may afterwards be evaporated. German Patent 81338 (1894). Ber. vol. 28 (1895) p. 685. Kumpfmiller, A. and Schultgen, E. PROCESS AND APPARATUS FOR CON- CENTRATING WASTE SULPHITE LIQUORS- Vacuum evaporator on the counter-current principle in connection with German Patent 81338. German Patent 83438 (1894). Austrian Privilegium 5849 (1894). Ber. vol. 28 (1896) p. 1030. Seidel, H. and Hanak, L. WASTE SULPHITE LIQUOR. Various schemes have been proposed to render the sulphite liquor harmless, either by rendering the lye innocuous by evaporation, by recovering the sulphur or by utilizing for other purposes the organic substances formed from the non-cellulose portions of the wood in the boiling process. According to the first method, patents have been taken out in Germany for treating the liquor with lime, saturating with carbonic acid, and evaporating the filtrate in a vacuum or multiple-effect apparatus or else by employ- ing a particular form of evaporating plant. The liquor is evaporated to about 30 Be., when it contains more than 50 per cent of dry substance, and is mixed with wood shavings and burned. In order to effect this evaporation about nine times the quantity of water has to be evaporated compared to the dry substance obtained, and the calorific value of the fuel produced is only about 60 per cent of that of medium coal. Mitt. Techn. Gew. Mus. (Vienna) vol. 8 (1898) p. 337. J. Soc. Chem. Ind. vol. 17 (1898) p. 863. Hofmann, C. HANDBUCH DER PAPIERFABR1KATION. 2nd Edition (1897) 1628 pages. Y Szamek, J PROCESS FOR BURNING ORGANIC SUBSTANCES IN LIQUORS. The partially evaporated liquor (30 Be.) is mixed with combustible absorbent substances (as sawdust, peat, cork, etc.) and burnt in open furnaces. German Patent 130665 (1901). Biedermanns Chem. Techn. Jahrb. (1901) p. 590. Chem. Zentr. (1902) part I p. 1082. 162 EVAPORATION OF WASTE SULPHITE LIQUOR 163 Schwager J. EVAPORATION OF WASTE SULPHITE LIQUOR. Heat necessary for evaporation of water as compared with sulphite liquor. Use of waste steam for evaporation of the liquor. Papier-Ztg. vol. 28 (1903) part II pp. 2075, 2183. Wernecke, E. APPARATUS FOR CONCENTRATING LIQUIDS. Continuous evaporation apparatus with direct heating with cups placed on the inside of the walls. The steam space has the form of an inverted cone so that the level of the liquid in the different cups decreases from top to bottom. It is possible by means of this apparatus to evaporate to high consistency by separate removal of liquor and vapours of various specific gravity. German Patent 201372 (1907). Kayser, H. EVAPORATION OF WASTE SULPHITE LIQUOR. (See " Binding Material " p. 52.) Opitz & Kayser. CELL-PITCH FROM WASTE SULPHITE LIQUOR. (See " Binding Material " p. 52.) Muller, M. EVAPORATION OF WASTE SULPHITE LIQUOR. (See " Binding Material " p. 52.) Sembritzki, W MANUFACTURE OF CELL-PITCH FROM SULPHITE LIQUORS. The success of the Walsum experiments is attributed in large part to the sextuple- effect Kestner evaporator used. Each effect has a heating surface of 55 sq. m. (592 sq. ft.), the first vessel is heated with steam at 3-4 atmospheres (45-60 Ib. per sq. in.), and the boiling point in the last effect is 50 C. The liquor requires about three hours for its concentration to 35 Be. This syrup is converted into solid pitch by two steam-heated drums which dip below its surface. The (first dirum concentrates the syrup from 35 to 60 Be., the second drum converts it into a solid film which is removed by a scraper. Ten kilogrammes (22 Ib.) of waste lye yield 1 kilogramme (2.2 Ib.) of dry substance. It is stated that a selling price of 40 marks ($9.52) per metric ton (2,204 Ib.) would show a good profit. This is equivalent to $8.64 per short ton. Papier-Ztg. vol. 33 (1908) part I p. 872. Wochbl. Papierfabr. vol. 39 (1908) p. 2866. J. Soc. Chem. Ind. vol. 27 (1908) p. 915. Chem. Abs. voL 2 (1908) p. 3403. Kestner, P. PROCESS AND APPARATUS FOR CONCENTRATION OF EXTRACTS OR LIQUORS. The liquors are forced, by means of the steam produced by the evaporation, at high speed through one or several heated pipes which are joined together, and at last leave the end of the pipe at a high velocity. The pipes are arranged almost vertically and are connected in series. At the point where the liquor enters the system a pump is placed, and at the lower end of the last pipe a steam separator is placed. German Patent Application 46236 (1910). Kestner P EVAPORATION APPARATUS WITH LONG VERTICAL PIPES ' 'AND A CONTAINER FOR SEPARATION OF THE STEAM. The pipes reach into the separation container to a little beneath the cover. German Patent 226106 (1910). Z. angew. Chem. vol. 23 (1910) p. 2282. 49120 11J 164 . FORESTRY BRANCH BULLETIN No. 66^ Kumpfmiller, A. REPORT ON EVAPORATION OF AND DETERMINATION OF THE COEFFICIENT OF HEAT TRANSMISSION, "K" OF WASTE SULPHITE LIQUORS, AND THE USE OF THE LIQUOR FOR TAN- NING PURPOSES. Report on Annual Meeting of German Pulp anl Paper Chemists 1910 p. 51. Muller, M. PROCESS FOR PURIFICATION AND EVAPORATION OF WASTE SULPHITE LIQUOR FOR USE AS FORAGE OR MANURE Lime is removed from the liquor by the addition of sodium sulphate. The liquor is then evaporated in vacuo whereby, the SO 2 is driven off with the steam. The vapours are conducted through lime in which the SO2 is absorbed. The remaining liquor is treated in the multiple-effect counter-current evaporator without any mechan- ical conveyance. The removal of SO2 and the evaporation to the desired concentration may be effected simultaneously. German Patent 241282 (1911). Wochbl. Papierfabr. vol. 42 (1911) p. 4864. Sudenburger Maschinenfabrik u. Eisengisserei. APPARATUS FOR AUTOMATIC REGULATIONS OF THE STEAM INLET IN APPARATUS FOR HEATING AND EVAPORATING SOLUTIONS. German Patent 266909 (1912). Addition to German Patent 219294. Liese, H. M. PROCESS AND APPARATUS FOR THE UTILIZATION OF HEAT OF WASTE INDUSTRIAL WATER AND OTHER LIQUIDS. The process is adapted for recovering heat from waste liquids containing sus- pended or dissolved matter which would deposit on cooking, and consists in bringing heat-exchanging surfaces into contact with steam generated from the liquid by a reduction of pressure, so that no deposit or incrustation is formed upon them. The waste liquid is passed through the lower portion of a series of chambers, in the upper portion of which are situated vessels or coils containing the liquid to be heated. The chambers are arranged so that a large surface of the liquid is exposed to the influence of the reduced pressure. The suction pipes are connected with the top of the chamber. English Patent 1832 (1911). J. 'Soc. Chem. Ind. vol. 30 (1911) p. 1441. Buisson, J. APPARATUS FOR EVAPORATING LIQUIDS, MORE PARTI- ' CULARLY PULP-MILL LIQUORS. The vapours primarily obtained by the evaporation are again heated in order to evaporate fresh amounts of liquor. . ''*' French Patent 442809 (1912). Chem.-Ztg. vol. 36 (1912) Rep. p. 69. J. Soc. Chem. Ind. vol. 31 (1912) p. 1069. ELLIS, C. CONCENTRATION OF WASTE SULPHITE LIQUOR. Concentrated sulphite liquor suitable for use as a binding material for road- surface is prepared by approximately neutralizing the waste sulphite liquor containing the diffusible constituents, separating the solid matters, aerating the liquid, fermenting it with yeast to remove the saccharine matter, separating volatile substances from the product, and concentrating the residue to a density of about 30 Be. (specific gravity 1-263). United 'States Patent 1042538 (1912). J. Soc. Chem. Ind. vol. 31 (1912) p. 1120. Brunei, L. PURIFYING AND CONCENTRATING SULPHITE LYES. The lyes are sprayed into the top of a tower up which a current of heated air is passed. The sulphurous acid compounds are thus oxidized and the lye is concentrated EVAPORATION OF WASTE SULPHITE LIQUOR 165 by evaporation, issuing at the bottom of the tower as a thick liquid containing calcium sulphate in suspension. French Patent 459069 (1912). J. Soc. Chem. Ind. vol. 32 (1913) p. 1153. Ellis, C PROCESS OF CONCENTRATING SULPHITE WASTE LIQUOR. The waste liquors are freed from a portion of the free sulphur dioxide by air- blowing, the remainder being neutralized with alkali. The alkaline liquor is then heated to promote hydrolysis, concentrated under reduced pressure, and finally freed from insoluble products of hydrolysis. It is recommended to blow air heated to 60O. through the liquor heated to 40C., make alkaline with lime, continue the aeration at 60,>C., filter, concentrate, and again filter. United States Patent 1057416 (1912). J. Soc. Chem. Ind. vol. 32 (1913) p. 482. Chem. Abs. vol. 7 (1913) p. 1806. Pulp Paper Mag. Can. vol. 10 (1912) p. 372. Dickerson, W. H. METHOD OF TREATING LIQUORS CONTAINING SUL- PHUROUS ACID OR SULPHITES. In order to prevent the decomposition of waste sulphite liquors during evaporation, a part of the basic constituents is precipitated with sulphuric acid and the solution kept acid. Another method is to concentrate in an acid state in the presence of soluble barium compounds. United States Patent 1059716 (1913). J. Soc. Chem. Ind. vol. 32 (1913) p. 531. Chem. Abs. vol. 7 (1913) p. 2115. Wolesky, F. CONTINUOUS APPARATUS FOR EVAPORATION AND CON- CENTRATION OF WASTE LIQUORS. Papier-Ztg. vol. 39 (1914) p. 1006. Rosenthal. CONCENTRATION OF LIQUORS IN THE "STEP" EVAPORATOR. Papier-Ztg. vol. 39 (1914) p. 1007. Wochbl. Papierfabr. vol. 45 (1914) p. 1847. Chem.-Ztg. vol. 38 (1914) p. 126. Muller, M. NEW SUGGESTIONS IN THE EVAPORATION AND PREPARA- TION OF WASTE LIQUORS FROM THE INDUSTRY. Wochbl. Papierfabr. vol. 45. Annual 'Number (1914) p. 2276. Chem. Abs. vol. 8 (1914) p. 3119. Kennard, F. H. PROCESS OF REDUCING WASTE SULPHITE LIQUOR TO A POWDER. The waste liquor is concentrated to a viscous state in vacuo and the product is applied in the form of a thin film to a heated surface also in vacuo, being retained thereon until it . is dry. United States Patent 1138118 (1915). ,1. Soc. Chem. Ind. vol. 34 (1915) p. 656. Chem. Abs. vol. 9 (1915) p. 1691. J. Ind. Eng. Chem. vol. 7 (1915) p. 1008. Lehmann, E. CONCENTRATION OF LYES, ESPECIALLY SULPHITE CEL- LULOSE WASTE LYES. The hot waste lye is discharged under pressure from the digester, through a pipe, into a vessel where a lower pressure prevails. The steam evolved escapes at the upper part of the vessel and the residual liquor is drawn into the steam injectors and dis- 166 FORESTRY BRANCH BULLETIN No. 66 charged together with the steam through nozzles, against baffles. The lye is thus atomized and a high degree of concentration is obtained. German Patent 282950 (1912). Norwegian Patent 24561 (1913). J. Soc. Chem. Ind. vol. 34 (1915) p. 656. Chem. Abs. vol. 9 (1916) p. 2590. Wochbl. Papierfabr. vol. 46 (1916) p. 1178. Papier-Fabr. vol. 13 (1915) p. 314. Papir J. vol. 2 (1914) p. 185. Murbe, E. EVAPORATION OF WASTE LIQUORS, ESPECIALLY SULPHITE AND SULPHATE LIQUORS. The liquor is sprayed under pressure into a chamber in which it comes in direct contact with hot waste gases from the boiler furnace. Further concentration is effected in the usual way in separate evaporating chambers. German Patent 293394 (1914). J. Soc. Chem. Ind. vol. 35 (1916) p. 1106. SOME MODERN EVAPORATORS. The Kestner climbing film evaporator, the Soderlund and Boberg evaporator, and the Proche and Bodllon "thermo-compressor" are described. A very high efficiency is claimed for the Soderlund and Boberg evaporator in virtue of the fact that the differ- ence in temperature between the boiling liquid and the heating steam is very small (from 1 to 3 C.) A plant on this system is being erected in Sweden for treating waste liquors from wood-pulp manufacture. J. Soc. Chem. Ind. vol. 36 (1917) p. 70. Krause, G. A VAPORIZING OR CONCENTRATING LIQUIDS, SOLUTIONS, EMULSIONS, SUSPENSIONS, ETC. The finely divided substance is injected upwords into a vertical cylindrical chamber, from a nozzle. A heated, gaseous drying-medium is injected tangentially at the bottom of the chamber so as to pass upwards to the outlet in a spiral (path of uniform diameter around the jet of substance to be desiccated. United States Patent 1213887 (1917). J. feoc. Chem. Ind. vol. 36 (1917) p. 329. Murbe, E. PROCESS FOR THE EVAPORATION OF WASTE SULPHITE AND SULPHATE LIQUORS. The waste liquors are sprayed in contact with furnace gases with simultaneous admission of air, the temperature of the mixing chamber and of the saturated flue- gases being, maintained above the boiling point of water, preferably at 110-120C. A fan is arranged for the introduction of air into the lower portion of the mixing chamber and a drying arrangement is provided beneath the mixing chamber to receive the aqueous lignin liquor discharged from the bottom of the mixing chamber. German Patent 297440 (1914). Addition to German Patent 293394. J. Soc. Chem. Ind. vol. 36 (1917) p. 870. EVAPORATOR FOR WASTE LIQUOR. A new evaporator, invented by Soderlund and Boberg, is described. The principle of the usual multiple-effect evaporators is the use of the steam formed in one evaporator for the liquor in the second evaporator. Hereby at least one-third or one-fourth of the steam is lost. With the new evaporator all steam or heat is utilized by increasing the temperature of the steam formed by the evaporation and using this warm steam for evaporation of further volumes of liquor. The increase in temperature is effected EVAPORATION OF WASTE SULPHITE LIQUOR 167 by a slight compression of steam. The new evaporator is put on 'the market by Aktiebolaget Industare, Gothenburg, 5, Sweden. Svensk Pap. Tid. (1917) p. 22. Papir. J. vol. 5 (1917) p. 92. Pulp Paper Mag. Can. vol. 15 (1917) p. 445. landmark, H. B. METHOD AND APPAEATUS FOR RECOVERY OF FREE SO 2 FROM WASTE SULPHITE LIQUOR, WITH SIMULTANEOUS CONCENTRATION OF THIS BY MEANS OF ITS LATENT HEAT. The liquor is atomized in an atomizer at its own pressure, whereby the S02 gas is removed. The liquor is afterwards passed into a container which is kept under strong vacuum in order to effect a high concentration by means of the latent heat of the liquor. Norwegian Patent 28147 (1917). Papir. J. vol. 5 (1917) p. 173. MISCELLANEOUS Zawadski and Meyer. PROCESS FOR PRODUCTION OF VOLATILE DISTIL- LATION PRODUCTS FROM WASTE LIQUORS. Claims: Process for production of wood alcohol, acetone, and other distillation products of wood from the waste liquors. The liquors concentrated as far as possible are made into a paste with charcoal, pressed into briquettes, and subjected to dry distillation. The free acid is removed, precipitated with sodium sulphate. Dry distilla- tion of the residue is obtained by evaporation in mixture with charcoal. German Patent 45951 (1888). Austrian Privilegium 1210 (1889), Ber. vol. 22 (1889) p. 76. Nettl, A. S. PROCESS FOR PREPARATION OF OXALIC ACID FROM SUL- PHITE LIQUOR. The liquor filtered from mechanical impurities is treated with sulphuric acid and warmed to drive off all the SO2. At the same time the lime is precipitated as CaSO4. The H2&O4 is neutralized with CaCOs and the liquor is freed from the resulting CaSO4 by filtration. The liquor is evaporated to 40 Be., and finally to dryness, and is then mixed with 2 parts of caustic potash and 1 part of caustic soda. The mixture is heated in cast-iron vessels from 1 to 4 hours, above 180 C., avoiding carbonization. The mixture is then extracted for oxalic acid. Or the sulphite liquor freed from lime salts is concentrated to 30 Be., and then mixed with sawdust and worked up to a thick paste which is then decomposed with caustic potash. German Patent 52491 (1889). Ber. vol. 24. (1891) p. 102. Mitscherlich, A. INNOVATIONS IN THE PROCESS OF PRODUCING TAN- NING MATERIALS WITH THE PRODUCTION OF THE BY-PRO- DUCTS CELLULOSE, GUMS, ACETIC ACID, AND CALCIUM BISUL- PHITE. German Patent 4179. (See " Tanning Materials " p. 78.) Mitscherlich, A. COOKING OF WOOD WITH CALCIUM BISULPHITE. RE- COVERING CELLULOSE, TANNING MATERIALS, GUMS AND ACETIC ACID. English Patent 1668 (1882). (See " Tanning Materials " p. 78.) Hartmann. LIGNOSULPHITE. The new treatment for pulmonary diseases by inhaling sulphite liquor vapours^ Papier-Ztg. vol. 20 :(1896) pp. 822, 952. 1084, vol. 21 >(1896) p. 764, vol. 24 -(1899) p. 1667. SULPHITE VAPOURS FROM THE SPENT LIQUORS OF WOOD-PULP MILLS AS A REMEDY FOR PULMONARY DISEASES. An establishment has been opened at Hallein (Austria) for the treatment of patients suffering from lung and bronchial disorders by inhalation of " lignosulphite " as proposed by Dr. Hartmann. In the address at the opening of the institute Dr. Kellner said that "lignosulphite" was the name given to the lignin compound of the sulphurous acid. For the production of suitable compounds for inhalation, the diges- tion of the wood is conducted in a particular manner so as to obtain a considerable 168 MISCELLANEOUS !69 quantity of the volatile derivatives. For lung diseases, air is inhaled containing 0-003 per cent by volume of these volatile compounds (the compounds of the ethers of camphene and terebene with sulphurous acid being specially mentioned), the result of which is a distinct change in the bacillus expectorated. It is well known that a small quantity of sulphurous acid in the atmosphere kills coniferous trees, and the ash obtained by burning the foliage of trees thus destroyed contains a considerable quantity of sulphurous acid. It has been shown that these plants possess the power of taking in, through the " stoma " of the epidermis, sul- phurous acid which is _pxidized to sulphuric acid and accumulates until it destroys the plant. The action of the sulphurous acid in the serum of the blood is somewhat similar to that in the plants, and owing to the large surface of the bronchial tubes of the lungs, the compounds of lignin and sulphurous acid are readily brought into contact with the blood, and absorbed. Tubercular laryngeal abscesses have been cured by a similar inhalation of antiseptic air. Papier-Ztg. vol. 19 (1894) p. 2779. J. Soc. Chem. Ind. vol. 14 (1895) p. 57. fiemy, P. UTILIZATION OF SULPHITE LYE AS A WATERPROOFING SOLUTION FOR PAPER. The liquor is treated with iron or lead salts in quantities equal to the calcium salts present, whereby a waterproofing solution is obtained. The iron salts are the more suitable, as lead salts are poisonous and also discolour the paper. The solution contains salts of other metals which may be removed before the treatment, and the lye may be evaporated before treatment to remove some of the SO2. Examples of treatment of the liquor are given. German Patent 90798. Papier-Ztg. vol. 22 (1897) p. 426. J. 'Soc. Chem. Ind. vol. 16 (1897) p. 630. Schmidt, H. PREPARATION OF ARTIFICIAL WOOD FROM WOOD AND WASTE LIQUOR. Wood, sawdust, etc., are mixed with liquor that has been evaporated arid treated with glue. The mixture is subjected to high pressure. The resulting product is preferable to wood in being lighter and in not swelling. German Patent 86542 (1895.) Ber. vol. 29 (1896) p. 462. Hofmann, C. KELLNER'S SULPHITE AND ELECTRIC PROCESS. The author discusses Hartmann's "lignosulphite", the method of preparation of which is secret. It may be formed from sulphonated-lignin compounds with aromatic substances and combined with sulphurous acid. Papier-Ztg. vol. 21 (1896) part II p. 2483. WASTE SULPHITE LYE AND COMMON SALT. As in most countries salt is taxed for manufacturing purposes whilst farmers who use it as a cattle food are exempt from the tax, a method of rendering the common salt unfit for manufacturing purposes but fit for cattle food is very much required. An addition of 5 to 10 per cent of waste sulphite lye is found to answer this purpose, being very difficult to remove from the salt and not rendering it distasteful to the cattle. Papier-Ztg. vol. 23 (1898) p. 951. J. Soc. Chem. Ind. vol. 17 (1898) p. 485. Mullner F -PROCESS FOR REGENERATION OF -ALKALI OF SULPHITE ' AND SULPHATE PROCESSES BY ALUMINA. The partially evaporated liquor is treated with alumina and with a quantity of lime equivalent to the sulphur content, to prevent formation of sulphides of the alka- 170 FORESTRY BRANCH BULLETIN No. 66 lies. The mass is decomposed and calcined. The alkalies form aluminates which are treated with either C 62 or SO2. German Patent 96467 (1897). Chem. Zentr. (1897) part I p. 1183. Papier-Ztg. vol. 23 (1898) pp. 687, 1062, 1218. J. Soc. Chem. Ind. vol. 17 (1898) p. 688. Pollacsek, E. PROCESS FOR PURIFICATION AND UTILIZATION OF WASTE EFFLUENTS FROM SULPHITE MILLS. Oxidation with air and ferric chloride, iron precipitated with caustic lime, and filtrate made acid. Recovery of gypsum from filtrate. A plastic mass of basic iron- stone is obtained if pyrites residues or iron ore are added to the filtrate. Austrian Privilegium 967 (1898). Pollacsek, E. PROCESS FOR RECOVERING VANILLIN FROM WASTE SUL- PHITE LIQUOR. The liquor is treated with air and iron chloride, precipitated with caustic lime, and afterwards with sulphuric acid. To the filtrate, sodium hydroxide or another alkali is added, and the precipitate, containing vanillin, is dissolved in hydrochloric acid. The vanillin is shaken out with ether or other solvent. Austrian Privilegium 1524 (1898) and Austrian Privilegium 967. Drewsen, V. and Dorenfeldt, L, J. UTILIZATION OF WASTE SULPHITE LIQUORS. Recovery of inorganic substances by treating the lye with lime in closed vessels and then treating the precipitate with sulphurous acid. United States Patent 620761 and 620776 (1899). Chem.-Ztg. vol. 23 (1899) p. 276. Gawalowski, A. WASTE SULPHITE LIQUOR AS DISINFECTING MATE- RIAL. Papier-Ztg. vol. 24 (1899) p. 3112. Chem. Tech. Ztg. (1899). Bache-Wiig, B. PRESERVATION OF FOODSTUFFS, PARTICULARLY EGOS. The eggs are given a protective coating, which can be easily washed off, by dipping in concentrated sulphite liquor. German Patent 129326 (1901). Chem. Zentr. (1902) part I p. 740. Koppert, K., Kammerer, F. J. F., Chem. Fabr. PREPARATION OF BLACK- ING BY THE USE OF SULPHITE LIQUOR. In place of crude glycerol, glue, gums, and molasses, thickened sulphite liquor is used to prepare acid-free blackings with the usual constituents. German Patent 114401 (1899). Chem. Zentr. (1900) part II p. 1046. Drewsen, V. and Dorenfeldt, L. J. PROCESS OF UTILIZING SULPHITE LYES. The waste liquor of sulphite mills, containing sulphonates, is neutralized with liquor from the soda pulp, containing sodium sulphite, and the mixture is concentrated and calcined. The product is lixiviated and the solution is treated with lime, the soluble salts being drained off for further use. United (States Patent 726036 (1903). J. Soc. Chem. Ind. vol. 22 (1903) p. 627. MISCELLANEOUS 171 UTILIZATION OF WASTE SULPHITE LIQUOR. Drewsen and Dorenfeldt's process of mixing the waste liquor with recovered soda, and concentrating, has one drawback, namely that even with an excess of alkali during the concentration process aldehydes are formed which with the hot steam form alcohols and acid. This is not the case when the soda is replaced by waste liquor from a soda-pulp mill. The loss of about 10 per cent which is experienced in the recovery plant of soda mills is also eliminated by this method. The process is as follows: 1. Neutralization by mixing sulphite and soda liquor; 2. Concentration of the neutralized liquor; 3. Fusing of the concentrated liquor; 4. Leaching of the residue; 5. Treatment of the solution with quicklime for the prepara- tion of soda-cooking liquor. Wochbl. Papierfabr. vol. 34 (1903) p. 2261. Morterud, E. PROCESS FOR OBTAINING GAS AND HEAT IN THE MANU- FACTURE OF SULPHITE PULP. The waste liquor (together with the pulp) is placed in an air-tight container under reduced pressure, whereby gas and excess heat is removed. The steam is condensed and the gas absorbed, or recovered, in other ways. German Patent 180168 (1905). United States Patent 833936 (1906). Austrian Patent Application 6383 (1905). Chem. Abs. vol. J (1907) p. 2204. Wochbl. Papierfabr. vol. 38 (1907) p. 1056. Papier-Ztg. vol. 31 (1906) part II p. 3819 vol. 32 (1907) part I p. 296. Kumpfmiller, A. PROCESS FOR PURIFICATION OF WASTE SULPHITE LIQUOR. Recovery of an adhesive, binding, tanning, and filling material. The sulphurous acid is removed at high temperature. The calcium is precipitated by the addition of an acid. One modification of the process is to spray the hot liquor continuously or intermittently into a container under high vacuum. Austrian Patent 40657 (1906). Tillberg, E. W. PROCESS FOR OBTAINING TANNINS, ALCOHOL, AND CELLULOSE FROM WOOD. Swedish Patent 25283 (1907). Trainer, E. UTILIZATION OF WASTE SULPHITE LIQUOR. Low-grade coal is mixed with waste liquor, the water evaporated, and the bri- quettes obtained by pressing are subjected to dry distillation. Combustible gases and fuel material are obtained. Papier-Fabr. (1907) p. 641. Papier-Ztg. vol. 32 (1907) p. 994. Chem. Zentr. (1907) part II p. 109. Ellis, C.-WASTE SULPHITE LIQUOR DISINFECTANT. Claim is made for a disinfectant composition comprising creosote of about 1-1 sp. gr. and concentrated waste sulphite-cellulose liquor of about 1-3 sp. gr., the latter being present in excess. United States Patent 877414 (1908). Chem.-Ztg. vol. 32 (1908) Rep. p. 111. J. Soc. Chem. Ind. vol. 27 (1908) p. 177. Trainer, E.-RENDERING ORGANIC CONSTITUENTS OF SULPHITE 'LIQUOR INSOLUBLE. The waste lyes are concentrated to about 30Be. and then heated with acids, when, according to the nature of the acid and the temperature, gelatinization of the mass takes place more or less rapidly. The gelatinization proceeds more quickly if an alde- hyde be added to the lye before the treatment with acid. After treatment with for- 172 FORESTRY BRANCH BULLETIN No. 66 maldehyde and concentrated hydrochloric acid, for example, the whole mass solidifies almost immediately on heating. The process may be carried out in a closed vessel under pressure. The product may be used for the preparation of insulating materials, artificial leather, etc. German Patent 197195 (1906). Austrian Patent 36847 (1908). J. Soc. Chem. Ind. vol. 27 (1908) p. 708. Chem. Zentr. (1908) part I p. 1595. Papier-Ztg. vol. 33 (1908) part I p. 1516. Z. angew. Chem. vol. 21 (1908) p. 2539. Chem. ADS. vol. 2 (1908) p. 2301. Trainer, E RENDERING THE ORGANIC CONSTITUENTS OF WASTE SULPHITE LIQUORS INSOLUBLE. The product obtained by treatment according to German Patent 197195 is dehy- drated and heated to above 100C. It can also be used as a decolorizing substance. German Patent 202132 (1907). Addition to German Patent 197195. Chem. Zentr. (1908) part II p. 1389. Wochbl. Papierfabr. vol. 39 (1908) p. 3238. J. Soc. Chem. Ind. vol. 27 (1908) p. 117,3. Chem. Abs. vol. 3 (1909) p. 491. Hough, W. J. Precipitation of resin from the liquor and the use of this material for the pre- paration of soaps and oils. Evaporation of liquor and destructive distillation of the lignin for obtaining gas and oil. United States Patent 931608. Papier-Ztg. vol. 34. (1909) p. 2787. Pulp Paper Mag. Can. vol. 8 (1910) p. 48. Diamond, B. PREPARATION OF NEUTRAL SALT SOLUTIONS FOR WOOD PRESERVATION. The liquor is neutralized with soda and then made strongly alkaline. The pre- cipitate produced is filtered off. In the filtrate, iron vitriol, aluminium sulphate, and sodium fluoride are dissolved in the proportions of 6 :1 :1. No precipitate is produced. The resulting solution can be used to impregnate wood. German Patent 216798 (1907) Cf. United States Patent 938128. Chem.-Ztg. Rep. vol. 33 (1909) pp. 607, 624. Jahrb. Chem. Techn (1909) part I p. 492. Kirchner, E. DAS PAPIER. Das Papier, vol. 2, parts >B and C. (See " Effluents " p. 35.) Melhardt, C. CONVERSION OF PEAT LIGNITE INTO CHARCOAL. Sulphite liquors which have been concentrated to a certain degree are non-hygro- scopic, i. e. they will not absorb moisture from the air, but if mixed with substances containing water the concentrated liquor will take up the water, becoming more dilute thereby. By mixing peat with sulphite liquor the water of the peat is extracted, and after standing a short time the dehydrated peat after separation from the liquor may be used to make charcoal. German Patent 148276 (1903). Papier-Ztg. vol. 29 (1904) part I p. 574. Jahrb. Chem. Techn. (1904) part I p. 6. UTILIZATION OF LIQUOR. The liquor, after addition of clay, may be used as a cementing material in the brick walls of kettles. Deut. Techn. Ztg. vol. 20 (1903) p. 274. MISCELLANEOUS 173 Spatz, H. PREPARATION OF FIREPROOF BRICK. To highly silicious substances such as quartz, sand, and kieselguhr, sulphite liquor is added as a cementing material. German Patent 159377 (1903). Jahrb. Chem. Techn. (1905) part I p. 379. Papier-Ztg. vol. 30 (1905) p. 1054. Bergerhoff, E. PREPARATION OF HALF-STUFF. 4 A pulp suitable for wrapping paper may be made by boiling the wood with waste liquor with the addition of some fresh bisulphite. German Patent 160151 (1903). Biedermann. Tech. Chem. Jahrb. (1904) p. 558. Chem. Zentr. (1905) part I p. 1576. . : PAPER-MILL WASTE TURPENTINE. Refers to work to be done in the engineering laboratories of the University of Wisconsin at Madison, Wisconsin, U.S.A., on waste products from pulp-mills. The attempt will be made to utilize the so-called " spruce turpentine " as a fuel for internal combustion engines. Tests on the oil show that fully 85 per cent is cymol. It is claimed that about 50 barrels per year are available from a 25-ton mill using slabs. A higher yield is claimed from sound timber. Pulp Paper M>ag. Can. vol. 7 (1909) p. 145. Diamond, B. RENDERING BARRELS TIGHT. The interior of the barrel is treated with waste sulphite pulp liquor resulting from the manufacture of cellulose from wood. The liquor should have a specific gravity of from 25 to 35 Be., and is previously mixed with treacle, starch-paste or water-glass. English Patent 5206 (1909). J. Soc. Chem. Ind. vol. 28 (1909) p. 1239. Diamond B. NEUTRALIZATION OF AQUEOUS SALT SOLUTIONS. The process depends on the fact that liquors of the kind in question hinder the precipitation of salts. The solutions obtained can be used to impregnate wood as a protective agent. German Patent 222193 (1909) (Addition to German Patent 216798). United States Patent 940394 (1909). Z. angew. Chem. (1910) p. 1390. Badische Anilin und Soda Fabrik. PROCESS FOR MAKING SUSPENSIONS OF INSOLUBLE DYES IN WATER. The dyestuff is heated with sulphite liquor. In certain cases the dye assumes the colloidal condition. Chem. Zentr. (1910) part I p. 1998. Deutsche Saduyn Gesellschaft M.B.H.-MEANS OF MAKING AUTOMOBILE GASES ODOURLESS. Produce salts of lignosulphonic acid by addition of sodium chloride to liquor at 80-100. One kilogramme (2-2 Ib.) of the. dried substance in 5 litres (1-1 gallons) of water produces a solution which absorbs acrolein and other gases with an unpleasant odour. Wochbl. Papierfabr. vol. 41 (1910) p. 3847. Matheus. BEHAVIOUR OF SULPHITE LYES WITH MILK OF LIME. If cold or hot sulphite waste lye be treated with milk of lime until neutralized, a precipitate is formed containing calcium sulphate, calcium sulphite, and calcium salts of organic acids. If more lime be added, the precipitate is increased and the liquid assumes a yellowish colour. On filtering the liquid and adding a further quantity of lime it is found that a considerable portion of the latter is dissolved. If the yellow lye 174 FORESTRY BRANCH BULLETIN No. 66 be then heated or if more milk of lime be added a large quantity of yellow precipitate is suddenly produced and the entire mass forms a thick paste. The liquid portion can be separated by filtration and the precipitate then appears to be composed of very small crystals of the calcium salt or salts of one or several very similar organic compounds. The moist precipitate readily dissolves when acidified with sulphuric acid; when it is decomposed, calcium sulphate separates out and a yellow or brown solution remains. If this be poured slowly into sulphuric acid at 30 Be. whilst stirring, each drop congeals at once into a flaky grey mass, so that a large quantity of an organic substance is obtained which can be filtered off from the excess of acid. This organic substance when oxidized by nitric acid yields large quantities of crystals of oxalic acid. Papier-Fabr. vol. 9 (1911) p. 1407. J. Soc. Chem. Ind. vol. 30 (1911) p. 1375. Chem. Abs. vol. 6 (1912) p. 1365. Pulp Paper Mag. Can. vol. 10 (1912) p. 53. Paper vol. 6 (1912) No. 5 p. 16. Matheus. DECOLORIZING CHARCOAL FROM SULPHITE LYES. The sulphite waste lyes, either fresh or freed from sulphur dioxide by boiling, are neutralized, preferably with milk of lime, in a suitable vessel. The liquor is then con- centrated to a thick syrup, and this is further evaporated in flat vessels until it swells up and solidifies on cooling to a brittle and readily friable mass. The powdered product is heated next with exclusion of air to product destructive distillation, and an extremely porous charcoal is obtained possessing good decolorizing properties and capable of serving as a substitute for bone charcoal. At the same time a distillate is obtained closely resembling the distillate from wood. Papier-Fabr. vol. 9 i(1911) p. 1435. J. Soc. Chem. Ind. vol. 30 (1911) p. 1446. Chem. Abs. vol. 6 (1912) p. 1365. DeCew, J, A. PROCESS FOR PRESERVING WOOD. The product is obtained by treating a fibro-cellular body with waste sulphite liquor under the action of heat and pressure. United States Patent 1010122 (1911). J. Soc. Chem. Ind. vol. 31 (1912) p. 29. Stutzer, A. SULPHITE LYES AS A PREVENTIVE FOR FOOT-AND-MOUTH DISEASE. The foot-and-mouth disease is one of which the propagation is stimulated by an alkaline condition of the stalls and bedding; as a preventive the spraying with a dilute mineral acid has met with a fair success. But the handling of those acids prior to dilution, by farm labourers, presents a certain amount of risk, so the author suggests that the waste lyes from sulphite wood-pulp mills might be tried with good effect. The lyes should be transported either in barrels or absorbed in sawdust. In the former case the farmer should make a heap of dry sand or earth and pour the lye in the centre, subsequently mixing well. The material impregnated with the sulphite lye should be spread daily over the stalls and yards inhabited by the animals; treatment should be commenced before the disease has actually lyoken out. Papier-Ztg. vol. 36 (1911) p. 3738. Wochbl. Papierfabr. vol. 42 (1911) p. 4956. Chem. Abs. vol. 6 (1912) p. 1850. J. Soc. Chem. Ind. vol. 31 (1912) p. 121. Bergstrom, H. VOLATILE OIL FROM SULPHITE DIGESTION. The vapours condensed from the digesters in the manufacture of sulphite wood- pulp yield an aqueous distillate containing methyl alcohol, acetone, aldehyde, and traces of acetic and formic acids, together with a brown oil which floats on the surface. This oil was formerly supposed to consist entirely of cymene, but the author's invest- igations show that it is a complex mixture. Fractional distillation of the oil between MISCELLANEOUS. 175 the limits of 150 and 270 C. yielded 7 per cent of a fraction, boiling point 150-160O. having a specific gravity of 0.845 optically inactive; this fraction was identical with that boiling at 149 C. obtained from the sulphate cellulose oil; it contains no terpene and is probably an oxygenated compound. The main product, distilling between 160 and 190 C., amounted to 55 per cent of the original oil and consisted mainly of cymene. The fraction 190-210C., amounting to 17 per cent of the oil, showed the maximum specific gravity of 0.951 and [a] D=1.95 ; it was a thick, pale yellow oil. The distillate coming over between 205 and 250 C. solidified in the condenser to a mass of white crystals of the composition, CioHisO. The fraction 190 -210 0. probably contained also an acid body of the terpene series. Above 250 C. a fraction having a specific gravity of 0.925 and a slight dextrorotatory power distilled over; this fraction contained a sesquiterpene. Papier-Fabr. vol. 10 (1912) p. 359. J. Soc. Chem. Ind. vol. 31 (1912) p. 381. Chem. Abs. vol. 6 (1912) p. 2528. Kaschig, F. UTILIZATION OF SULPHITE LIQUOR IN AMMONIUM-NI- TRATE EXPLOSIVES. The use of the evaporation residue of waste lyes from the manufacture of sulphite cellulose as a combustible substance in ammonium-nitrate explosives is claimed. The lye may be evaporated and the dry residue mixed with powdered ammonium nitrate or ammonium nitrate may be dissolved in the lye and the latter then evaporated, pre- ferably on heated rotating drums. The explosives thus obtained detonate readily with fulminate caps, and may be admixed with up to 30 per cent of an inert substance and yet be capable of detonating. The products containing an admixture of an inert substance are specially suitable as safety explosives for mines. French Patent 447419 (1912). J. Soc. Chem. Ind vol. 31 (1912) p. 845. Raschig, F. EXPLOSIVE FROM WASTE SULPHITE LIQUOR. Potassium or sodium nitrate is mixed with the waste lyes coming from the ma- nufacture of cellulose by the sulphite or soda process. The liquid then flows on td highly-heated revolving rollers whereby almost immediate evaporation to dry ness is obtained without any separation of the ingredients of the mixture. The dry material when scraped from the rollers is immediately ready for use and can be pressed in the dry state. The following are given as examples of this explosive: (1) Sodium nitrate (68 per cent), dry matter from either sulphite or soda-cellulose waste lyes (32 iper cent). (2) Potassium nitrate (70 per cent), dry matter from sulphite-cellulose waste lyes (30 per cent). English Patents 29696, 2069 (1912), Addition to English Patent 11668 (1912). See French Patents 447419, 44149 (1912). - United States Patents 1056366 and 1056367 (1913). J. Soc. Chem. Ind. vol. 32 (1913) p. 454. Bergstrom, H. 0. V. and Lindquist, B. 0. PURIFICATION OF LIQUID RESIN OBTAINED IN THE MANUFACTURE OF SULPHITE PULP. The liquid resin is subjected to a distillation in vacuo at a temperature not exceed- ing 230 -250 C. with a view to destroying the lignin and similar compounds. The malodorous compounds go over first, the distillate being further purified with sul- phuric acid, with passage of air if necessary. Swedish Patent 33333 (1910). Chem. Abs. vol. 7 (1913) p. 1288. Sandberg, E. S. and Sundblad, G. K.-DESTRUCTIVE DISTILLATION OF ORGANIC MATTER IN WASTE LYES. Waste lye from the manufacture of wood-pulp or other liquid containing organic matter is treated in two stages. The liquid is first spread in a thin layer on heated 176 FORESTRY BRANCH BULLETIN No. 66 surfaces, whereby about 80 litres (17-6 gallons) of lye per minute are evaporated and the residue partially decomposed and carbonized, the carbon acting so as to remove adhesiveness. The solid residue then being easily and continuously removed by scrapers is passed through heated tubes by means of screw conveyors or is heated in ordinary retorts so as to be completely carbonized. English Patent 24125 (1912). J. Soc. Chem. Ind. vol. 32 (1913) p. 279. Chem. Abs. vol. 8 (1914) p. 1346. LIGNOSULPHITE INHALABO'RIUM. An inhalaborium for lignosulphite is in continuous operation in Soolbad Frank - enhausen. Muller, Literatur der Sulfitablauge 1914 p. 30. Muller, P. G. PREPARATION OF AN ELASTIC MASS FROM WASTE SUL- PHITE LIQUOR. Belgian Patent 255636 (1913). Robeson, J. S PLASTIC MASSES FROM WASTE SULPHITE LIQUOR. From concentrated liquor and clays. United iStates Patent 1069031 (1913). J. Soc. Chem. Ind. vol. 32 (1913) p. 864. Platsch, M. PRECIPITATION OF THE OBJECTIONABLE CONSTITUENTS OF WASTE SULPHITE LYES BY MEANS OF REAGENTS AFTER CONCENTRATION OF THE LYE. The precipitation of the calcium salts as sulphate can be completely effected only after elimination of the volatile organic acids (acetic acid) by evaporation of the lyes to a syrupy consistency. The reagents then used must be such that their bases form with sulphurous acid only readily decomposable compounds or else do not combine at all. Aluminium sulphate, for instance, would be suitable, but precipitation may equally well be effected by sulphuric acid, provided the liquor be neutralized after the separa- tion of the precipitate of calcium sulphate. French Patent 447578 (1912). United States Patent 1054141 (1913). English Patent 19600 (1912). J. Soc. Chem. Ind. vol. 3? (1913) pp. 284, 823 Chem. Abs. vol. 7 (1913) p. 1415. Ferenczi, S. USE OF SULPHITE LIQUOR IN FOOT-AND-MOUTH DISEASE. Sulphite liquor which had been made alkaline with NaOH was run into a stream. Cattle drinking from this stream were free from foot-and-mouth disease. J. Landw. vol. 60 p. 183. Z. angew. Chem. vol. 25 (1912) p. 2088. Baekeland, L. H. IMPREGNATING WOOD WITH SULPHITE LIQUOR. A "fibrocellular body" is treated with waste sulphite liquor under the action of heat and pressure. United States Patent 1057211 (1913). J. Soc. Chem. Ind. vol. 32 (1913) p. 427. Baekeland, I. H. IMPREGNATED WOOD. The pores of the wood are impregnated with mineral salts ZnCl 2 with or without water-glass and with the solid constituents of sulphite waste liquor. United States Patent 1057319 (1913). J. Soc. Chem. Ind. vol. 32 (1913) p. 428. Chem. Abs. vol. 7 (1913) p. 1796. Paper Trade J. vol. 57 (1913) No. 20 p. 46. MISCELLANEOUS 177 Kinman, E. L. APPARATUS FOR DESTRUCTIVE DISTILLATION OF SUL- PHITE LYES. Distillation is effected in an annular furnace in which an annular hearth is mounted. The material is distributed over the hearth and heating gases are passed through an annular space below the hearth, the latter 'being rotated in the opposite direction to the flow of the heating gases. The heating chamber is closed against the space above the hearth by liquid or sand-seal, and the conduit through which the distillation residue is discharged is connected with a vertical pipe of such height that the column of residue therein is sufficient to provide a gas-tight seal. German Patent 269994 (1913). J. Soc. Chem. Ind. vol. 33 (1914) p. 346. Coughlin, M. F. COMPOSITION FOR VARNISH, CONTAINING WASTE SULPHITE LIQUOR AND SHELLAC. The composition consists of an ammoniacal solution of shellac together with the solid constituents of waste sulphite liquor. United States Patent 1103267 (1914). J. Soc. Chem. Ind. vol. 38 (1914) p. 931. Lederer, A. and E. RECOVERY OF VOLATILE ACIDS, ETC. FROM HYDRO- LYSIS OF LIGNOCELLULOSES. The volatile products formed in the hydrolysis of lignocelluloses are removed by distillation under pressure from the mass in course of hydrolysis. The condensed liquid is fractionated by subsequent distillation, volatile acids, furfural, methyl alcohol, and acetone being obtained. The volatile products still remaining in the hydrolysed mass are separated by drying the latter in vacuo at not above 80O. until it contains only 5-10 per cent of moisture. No destruction of sugar takes place at this temperature, but if a higher temperature be desired calcium acetate may be added to neutralize the mineral acid present. French Patent 464608 (1913). : - J. Soc. Chem. Ind. vol. 33 (1914) p. 478. Meunier, L. USE OF SULPHITE-CELLULOSE EXTRACTS FOR VARNISH. A varnish giving rapidly drying, uniform coatings is prepared by mixing commer- cial concentrated sulphite-cellulose extract with a substance, especially a solution of a terpene in a sulphoricinate, which diminishes the surface tension of the product. For example, 4 litres (0.88 gallons) of oil of turpentine are added gradually, with constant agitation, to 25 kilogrammes (55 Ib.) of neutral sodium sulphoricinate heated to 60 C., and the resulting thick liquid is incorporated with 25 times its weight of sulphite- cellulose extract of 30Be. (specific gravity 1.263). French Patent 460196 i(1913). J. Soc. Chem. Ind. vol. 33 (1914) p. 604. Ekstrom, G REMOVAL OF ORGANIC CONSTITUENTS FROM SULPHITE LIQUORS AFTER FERMENTATION. Alcohol is first produced from the lye in the usual manner and the residual lye treated with a basic reagent, e.g. caustic lime, and then oxidized by aeration. Humus- like calcium compounds are precipitated; alternatively, aeration may be performed in the presence of an oxidizing catalyser. United States Patent 1087356 (1914). Chem.-Ztg. vol. 38 (1914) p. 25. J. Soc. Chem. Ind. vol. 33 (1914) p. 349. Chem. Abs. vol. 8 (1914) p. 1346. Grothe, 0. PROCESS FOR TREATING SULPHITE LIQUOR. The neutral liquid, after the removal of the free sulphurous acid, is concentrated and the sulphur-bearing groups of the organic compounds are removed by subjecting the liquor to the action of a cyanide or cyanamide compound under heat and pressure. 4912012 178 FORESTRY BRANCH BULLETIN No. 66 The product of the reaction is diluted with water and an organic cyanogen or cyana- mide compound precipitated by a mineral acid; the precipitate is filtered off and dried at the ordinary temperature and used for tannin. United States Patent 1087911 (1911). J. Soc. Chem. Ind. vol. 33 (1914) p. 349. Coughlin, M. F. and Sweet, C. .E. PKOCESS OF BLEACHING SULPHITE LIQUOR. The waste sulphite liquor is first treated with an oxidizing agent (permanganate) arid then with a reducing agent (hydrosulphite). United States Patent 1114120 (1914). J. Soc. Chem. Ind. vol. 33 (1914) p. 1152. Chem. Abs. vol. 8 (1914) p. 3858. Paper vol. 15 (1914) No. 7 pp. 24, 32. Coughlin, M. F. and Sweet, C. E PREPARATION OF A FINISHING COM- POSITION. A waxy material, with or without a soluble soap, is incorporated with waste sul- phite liquor in. such proportion as to be readily emulsified with water. United States Patent 1114119 (1914).. J. Soc. Chem. Ind. vol. 33 (1914) p. 1153. Ceughlin, M. F. VARNISH CONTAINING SULPHITE LYE AND SHELLAC. The composition consists of an ammoniacal solution of shellac together with the solid constituents of waste sulphite liquor. United States Patent 1103267 (1914). J. Soc. Chem. Ind. vol. 33 (1914) p. 931. Bantlin, G. PYROGENIC DECOMPOSITION OF WASTE SULPHITE LIQUOR. Methyl alcohol is not formed, but large quantities of hydrogen disulphide and mer- captans are produced. The coking of the liquor therefore seems economically impos- sible. J. Gasbel. vol. 57 (1914) p. 32. Chem. Zentr. (1914) part I p. 923. Chem. Abs. vol. 8 (1914) p. 1344. Kinman, E. L. UTILIZATION OF WASTE SULPHITE LIQUOR. The organic substances in the waste sulphite liquor can be transformed into the same products as are formed in the soda or sulphate process by a special treatment with lime at high temperature. By dry distillation, acetone spirit, light and heavy oils, and combustible gases are obtained. Also SO2 recovered in form of CaSOs. Sawdust, etc., may be added to the liquor with advantage. Description of process and results obtained are given. Five cubic metres (220 gallons) 'of sulphite lye. from one metric ton (2,204 Ib.) of pulp, yield: 125 kilogrammes (275 Ib.) calcium sulphate; 250 kilo- grammes (550 Ib.) humic substances; 16-5 kilogrammes (36-3 Ib.) acetone spirit; 15 kilogrammes (33 Ib.) light oils; 10 kilogrammes (22 Ib.) heavy oils. If sawdust is added to the lye the yield is higher. Rep. Assoc. German Pulp and Paper Chemists (1914). Wochbl. Papierfabr. vol. 46 (1915) p. 990. Chem.-Ztg. vol. 39 (1915) p. 99. J. Soc. Chem. Ind. vol. 34 (1915) p. 274. Papier-Ztg. vol. 40 (1915) pp. 569, 974. Chem. Abs. vol. 9 (1915) p. 2709. Paper vol. 16 (1915) No. 9 p 11. Pulp Paper Mag. Can. vol. 13 (1915) p. 337. Gunther, W STABILIZING SULPHITE LYE. In stabilizing sulphite lyes used for water purification, the disadvantages resulting from the varying composition of the concentrated lyes is overcome by evaporating MISCELLANEOUS 179 them at the lowest possible temperature to dryness so that the organic matter will not be destroyed and by combining the free alkali at the same time or subsequently with CO2 (air combustion gases). French Patent 457159 (1913). Chem. Abs. vol. 8 (1914) p. 2018. MulleiyM. NEW SUGGESTIONS WITH KEGARD TO EVAPORATION AND TREATMENT OF INDUSTRIAL WASTE WATERS. Wochbl. Papierfabr. Annual number (1914) p. 2276. Oman, E. PROCESS FOR MANUFACTURING SULPHITE PULP. Waste liquor is used instead of water for preparation of cooking liquor by dissolv- ing lime and sulphurous acid. When the liquor after several "cooks" has reached a certain concentration of organic matters it is worked up for by-products. French Patent 467466 0914). English Patent 1145 (1914). Canadian Patent 154165 (1914). United States Patent 1130192 (1915). J. $oc. Chem. Ind. vol. 33 (1914) p. 348, vol. 34 (1915) p. 419. Chem. Abs. vol. 8 (1914) p. 2805, vol. 9 (1915) pp. 1319, 1843. Pulp Paper Mag. Can. vol. 12 (1914) p. 282. Paper vol. 14 (1914) No. 8 p. 20 also vol. 16 (1915) No. 6 p. 19. Aktieselskabet Sulfitsprit. PROCESS FOR OBTAINING ORGANIC SUBS- TANCES FROM WASTE SULPHITE LIQUOR. The remaining liquor after the alcohol has been distilled off is mixed with sul- phuric acid containing wash water from the washing of the SO 2 gases and boiled at a pressure of less than 12 atmospheres. Norwegian Patent 25927 (1915). Papir J. vol. 3 (1915) No. 15 p. 190. Platsch, M. PROCESS FOR PURIFICATION OF CONCENTRATED WASTE SULPHITE LIQUOR BY PRECIPITATING THE LIME WITH SUL PHURIC ACID. Sulphuric acid is added to the cold liquor in such a quantity as to precipitate all the lime. Traces of sulphuric acid are afterwards removed by the addition of a base. Norwegian Patent 26028 (1915). Papir J. vol. 3 (1915) No. 15 p. 203. Schmidt, A. A NON-EXPLOSIVE FUNGICIDE. United 'States Patent 1136723 (1915). Chem. Abs. vol. 9 (1915) p. 1526. DeCew J A PROCESS FOR PRESERVING AND HARDENING OF WOOD ' AND THE LIKE AND FOR RENDERING WOOD AND WOOD PRO- DUCTS FIREPROOF. Creosote oil or crude petroleum is 'emulsified with the waste sulphite liquor, and the emulsion is used for impregnating the wood after the addition of magnesium chloride, mercury chloride or copper sulphate. Norwegian Patent 26293 (1915). United States Patent 1155708 (1915). Papir J. vol. 3 (1915) p. 262. J. Soc. Chem. Ind. vol. 34 (1915) p. 1244. Paper-Maker Brit. Trade J. vol. 49 (1915) p. 332. 49120 12*J 180 FORESTRY BRANCH BULLETIN No. 66 Hedden, M. W PROCESS OF TREATING WASTE SULPHITE LIQUOR. Neutralized waste sulphite liquor is digested with a cyanogen compound to remove all the sulphur-bearing groups and then saturated with sodium chloride or an electrolyte, other than a mineral acid, to precipitate organic cyanogen compounds. United States Patent 1130817 (1915). J. Soc. Chem. Ind. vol. 34 (1915) p. 419. Chem. Abs. vol. 9 (1915) p. 1115. Knight, 0. W. PROCESS OF TREATING SULPHITE WASTE LIQUOR AND PRODUCT THEREOF- A liquor containing a lignone derivative, e.g. fermented waste sulphite liquor, in which at least part of the alcohol has been oxidized to aldehyde, is treated with a phenolic substance in presence or absence of a condensing agent at a temperature suffi- cient to produce a condensation product. United States Patent 1143714 (1915). J. Soc. Chem. Ind. vol. 34 (1915) p. 830. Paper Trade J. vol. 61 (1915) No. 3 p. 50. Paper vol. 17 (1915) No. 2 p. 18. Wegelin, A. Akt. Ges. f. Russfabrikation. MANUFACTURE OF AN EXPLO- SIVE FROM LIQUID AIR AND CARBON FROM WASTE SULPHITE CELLULOSE LYE. Coke prepared by carbonization of waste sulphite liquor is impregnated with liquid air. French Patent 474819 (1914). J. Soc. Chem. Ind. vol. 34 (1915) p. 1119. Bergstrom, H. UTILIZATION OF VOLATILE WASTE PRODUCTS OF SUL- PHITE-CELLULOSE MANUFACTURE. If the vapours "blown off" from the sulphite digesters be condensed, sulphurous acid, methyl alcohol, cymene, and small quantities of furfural and of a solid terpene alcohol can be recovered from the condensed liquid, which contains 100 grammes of sulphurous acid (1 Ib. per gallon) and 5-5.5 grammes of methyl alcohol per litre (0.05-0.055 Ib. per gallon), and 1-1.5 litres (0.22-0.33 gallons) of oil, furfural, etc. per metric ton (2204 Ib.) of cellulose. Moreover, the quality of the cellulose would be improved by removing these products from the condensed liquid before using it again in the boiling process. Considerable quantities of methyl alcohol, and possibly also some acetic acid, could be recovered by evaporating the spirit lyes from the digesters. Papier-Fabr. vol. 12 (1914) p. 1040. Z. angew Chem. vol. 28 (1915) Rep. 47. J. Soc. Chem. Ind. vol. 34 (1915) p. 487. Chem. Abs. vol. 9 (1915) p. 149. Chem. Trade J. vol. 57 (1915) p. 208. Papir J. vol. 2 (1914) p. 389. Fosse, H. W. NORWEGIAN TURPENTINE OIL FROM SULPHITE-CELLU- LOSE MANUFACTURE. The crude oil, obtained as 1 a by-product in sulphite-cellulose manufacture, had a specific gravity at 15/15C. of 0.8918 Fa] -^ = + 7.8 and contained no free acids; the greater part boiled between 157 and 160C. The oil contained sulphur compounds and oxygenated substances, and had an unpleasant odour. The sulphur compounds and unpleasant odour were largely removed by treatment with calcium hypochloride. The oil contains about 80 per cent of J-pinene, with small amounts of sylvestrene and sesquiterpenes. Ber. Pharm. Ges. vol. 25 (1915) p. 303. J. Soc. Chem. Ind. vol. 34 (1915) p. 1261. MISCELLANEOUS 181 Lorentz, K. LIQUID SWEDISH RESIN FROM WOOD-PULP WASTE LIQUOR. The resin from sulphite pulp waste lye has a high sulphur content and an un- pleasant odour. It is soluble in water and has drying properties. It is not suitable for soap manufacture but may find application in the varnish industry, in the prepar- ation of wagon grease, lubricants for driving belts, and bird lime. The crude resin may be refined by distillation by boiling with sulphuric acid or with a strong solution of sodium chloride and milk of lime, or by saponification. Seifensieder-Ztg. vol. 43 (1916) pp. 400, 501. Z. angew. Chem. vol. 29 (1916) Rep. p. 445. J. Soc. Chem. Ind. vol. 35 (1916) p. 1163. Freeman, W. K. INSULATING MATERIAL, PLASTIC COMPOSITION, AND CEMENT COMPOSITION FROM WASTE SULPHITE LIQUOR. The liquor is concentrated, treated with hydrochloric acid, agitated and boiled, partially cooled, treated with ammonia, agitated by beating so as to precipitate sulphur calcium compound in an inert form, allowed to settle, and the product evaporated. Par- tially evaporated lye may be treated with an alkali chloride, agitated while hot, par- tially cooled, and treated with barium chloride. The liquor treated in this way may be dried with the precipitate therein, mixed with an oxide and chloride capable of form- ing an oxychloride binding agent for insulating purposes. The liquor treated as above may be separated from the precipitates evaporated, dried and powdered, and mixed with a small quantity of gum camphor, with or without powdered, indurated, vegetable fibre, and then with a mixture of powdered metallic oxide and chloride adapted when wet to form an oxychloride binding agent. The liquor treated as above, dried without remov- ing the precipitate, and powdered, is mixed with the powdered components of an oxy- chloride binding agent and with finely disintegrated wood which has previously been treated with an oxychloride cement, allowed to set, and then disintegrated. United States Patent 11764,22-1175426 (1916). J. Soc. Chem. Ind. vol. 35 (1916) p. 533. Chem. Abs. vol. 10 (1916) p. 1434. Welsh, J SULPHITE LIQUOR FOR RE-PULPING NEWSPAPER. The process of removing ink, colouring matter or pigments from waste papers by the use of spent digester liquids. United States Patent 1175853. Paper vol. 18 (1916) No. 2, p. 14. Freeman, W. K. PLASTIC COMPOSITION FROM WASTE SULPHITE LIQUOR. Composition articles are made by mixing powdered "xylium" with powdered magnesium oxide and disintegrated fibrous material, moistening the mass with a solution containing magnesium chloride to form a plastic mass, the chloride being in sufficient quantity to form an oxychloride bond, and bringing the mass in contact with hot surfaces to remove excess moisture and press it into form. United States Patent 1175427 (1916). J. 'Soc. Chem. Ind. vol. 35 (1916) p. 534. Beveridge, J. THE UTILIZATION OF WASTE SULPHITE LYES. The author mentions the various processes for utilization, especially the manufac- ture of tanning extracts. Finally the recovery of inorganic substances is discussed. J. Soc. Chem. Ind. vol. 35 (1916) p. 563. Paper vol. 18 (1916) No. 16, p. 17. Chem. Abs. vol. 10 (1916) p. 2799. (See " Tanning Materials " p. 78.) Kinman, E. I.-PROCESS FOR TREATING WASTE SULPHITE LIQUORS WITH ALKALI. Sulphite residues are boiled with alkalies, particularly calcium hydroxide, pre- ferably under pressure, until they are transformed into a precipitate of lignih and 182 FORESTRY BRANCH BULLETIN No. 66 calcium hydroxide, with or without superheated steam. Organic substances such as sawdust and bark may be adcbd and the soluble product, especially if freed from cal- cium sulphite, may be made into briquettes for fuel, with or without admixture of other organic material. No mercaptans are formed in the dry distillation, provided that the boiling, with lime has been continued long enough and at sufficiently high temperature. The distillate contains acetone, wood spirit, ethyl alcohol, ammonia and other nitrogenous compounds, and an oily mixture of higher alcohols, aldehydes, ketones, and hydrocarbons. By admitting sufficient air to the hot residue it may be burnt to lime, which is used again, and the heat developed may be used for another dry distillation. The waste lye may be freed from sulphurous acid before treatment and may also be previously fermented. German Patent 285752 (1914). United States Patent 1202317 (1916). Swedish Patent 42106 (1917). J. Soc. Chem. Ind. vol. 34 (1915) p. 1139, vol. 35 (1916) pp. 1010, 1215. Chem. Abs. vol. 10 (1916) p. 1595 vol. 11 (1917) pp. 99, 2153. Messow, H. MANUFACTURE OF ARTIFICIAL GRAPHITE FROM WASTE LYES FROM CELLULOSE MANUFACTURE. Waste lyes from the manufacture of cellulose are mixed with oxides of heavy metals, e.g. ferric oxide, and with calcium phosphate, and the mixture is exposed to high temperature and a very high pressure. German Patent 297075 (1915). J. Soc. Chem. Ind. vol. 36 (1917) p. 873. Oman, E, LIGNIN AND LIGNONE DERIVATIVES. Lignin stilphonates and lignone sulphonates separated by saturating waste liquor with a salt such as Na, K, NH4 chloride or sulphate; lignin sulphonates are precipi- tated, lignone sulphonates remain in solution. Oxyligiiin and oxylignon are obtained by treating the lignin or lignone sulphonates with alkali. British Patent 106493 (1917). Pulp Paper Mag. Can. vol. 15 (1917) p. 924. Loffl, K SULPHITE LIQUOR FOR WASHING PURPOSES. By making the liquor into a paste with infusorial earth or sand it could be used by the soldiers in the field for washing. The addition of per cent Na2COs increases its detersive powers. By adding 2 per cent of crude cresol to the liquor it makes an excellent agent for killing body lice, and by incorporating 10 per cent of cresol it makes a good and cheap cleanser and disinfectant for floors. Seifenseder-Ztg. vol. 42 (1915) p. 431. Chem. Abs. vol. 10 (1916) p. 1443. Rinman, E. L. TREATMENT OF WASTE SULPHITE LIQUOR. Treatment with caustic lime and destructive distillation of precipitate. Norwegian Patent 26603 (1914). Swedish Patent 42108 (1917). Papir J. vol. 4 (1916) p. 47. Chem. Abs. vol. 11 (1917) p. 2153. Pulp Paper Mag. Can. vol. 15 (1917) p. 741. Puring, J., Robeson Process Co. WOOD STAIN FROM WASTE SULPHITE LIQUOR. The stain consists of an emulsion of concentrated sulphite-cellulose waste liquor, linseed oil, and a little sulphuric acid, with or without the addition of formaldehyde. United iStates Patent 1185604 (1916). J. Soc. Chem. Ind. vol. 35 .(1916) p. 747. Chem. Abs. vol. 10 (1916) p. 1939. MISCELLANEOUS 1 g^ Kertesq, Z. VOLATILE ORGANIC COMPOUNDS, ESPECIALLY ESSENTIAL OILS FORMED IN THE SULPHITE PROCESS. The liquor mixed with (1) powdered chalk, (2) ammonium sulphate, or (3) man- ganese sulphate aerated and fermented. The alcohol yields, including methyl alcohol acetone, and acetaldehyde were: (1) 0-894 per cent, (2) 0-874 per cent, (3) 0-868 per cent. From 1,000 litres (220 gallons) of liquor were separated, 0-06 kilogrammes (0-132 Ib.) acetaldehyde, 0-2 kilogrammes (0-44 Ib.) acetone, 0-53 kilogrammes (1-17 Ib.) methyl alcohol, and 6-33 kilogrammes (13-9 Ib.) ethyl alcohol. Further there were isolated a sesquiterpene CisH 2 4 (B. p. 250 -260 C., sp. gr. 0-925) and a diterpene C^oHso (B. p. above 300 C., sp. gr. 0-950). Chem.-Ztg. vol. 40 (1916) p. 945. Chem. Abs. vol. 12 (1917) p. 1040. Paper-Maker and Brit. Trade J. vol. 52 (1917) p. 36. Pulp Paper Mag. Can. vol. 15 (1917) pp. 236, 306. Paper Makers' Monthly J vol. 55 (1917) p 49 Paper vol. 19 (1917) No. 17, p. 15. Strehlenert, E. W HYDROLYSIS OF PEAT: STREHLENERT'S SULPHITE FUEL PROCESS. About 75 per cent of the dry substances in the waste sulphite liquor are easily decomposed by Strehlenert's process. The remaining 25 per cent can only be decom- posed at considerably higher temperatures and by the addition of larger quantities of sulphuric acid. In order to facilitate the removal of water from peat this is heated to 180 C. at 8 atmospheres pressure, whereby the humic acids present in peat serve as hydrolyziiig agents. By using the liquor from the fuel process which contains 0-35 per cent sulphuric acid, of which 0-2 per cent is free acid, the hydrolysis can be effected at 140 C. and 6 atmospheres pressure within 20 minutes. At the same time the dry substance remaining in the liquor after the fuel process is precipitated in the peat. With a centrifuge, the peat can be dried to 25 per cent and by pressing after centrifuging to 50-55 per cent dry substance. The calorific value of the peat obtained in^this was 5,260 calories at a moisture content of 6-4 per cent and an ash content of 3 6 per cent. Calculations show that at the same time one ton of sulphite fuel is pro- duced 1,550 kilogrammes peat fuel can be obtained. The heat required for the pro- duction of peat fuel amounts to 20 per cent of the heat value produced. Papir J. vol. 5 (1917) p. 101. Pulp Paper Mag. Can. vol. 15 (1917) p. 764. Enger, P. G APPARATUS FOR THE EXTRACTION OF HYDROCARBONS, ETC. ESPECIALLY CYMOL, IN THE MANUFACTURE OF SULPHITE PULP. Several tanks are provided, one of them having an inlet connected with the top of the digester and an outlet near the top of the tank leading to an inlet near the bottom of the second tank. The second tank has an outlet near the bottom diametrically opposite the inlet, leading to an inlet in the third tank at a slightly higher level than the outlet in the second tank, and a return pipe is provided from the third tank to the digester. United States Patent 1223158 (1917). J. Soc. Chem. Ind. vol. 36 (1917) p. 593. Chem. Abs. vol. 11 (1917) p. 1903. Pulp Paper Mag. Can. vol. 15 (1917) p. 741. Reed, H. C. OXALIC ACID FROM WASTE PULP LYES. The liquor is reduced to an approximately dry residue and concentrated nitric acid added in the proportion of 300 Ib. of acid to 100 Ib. of residue, the temperature being maintained at about 95 C. until oxidation is complete. Excess of nitric acid and water are then driven off by heat, and the oxalic acid is recovered by crystallization. United States Patent 1217218 (1917). J. Soc. Chem. Ind. vol. 36 (1917) p. 503. Chem Abs. vol. 11 (1917) p. 1545. 184 FORESTRY BRANCH BULLETIN No. 66 Coughlin, M. F. RUBBER COMPOSITION AND PROCESS FOR MAKING THE SAME. Rubber is incorporated with dry sulphite waste lye solids, blown petroleum, and asphalt, with or without other loading materials. United States Patent 1217167 (1917). J. Soc. Chem. Ind. vol. 36 (1917) p. 512. Knopflmocher, A. CHARCOAL FROM WASTE SULPHITE LIQUOR. Four thousand kilogrammes (8800 lib.) of waste liquor, 400 kilogrammes (880 Ib.) of potassium carbonate, 38 kilogrammes (83-5 Ib.) of calcium oxide, and 60 kilogram- mes (132 Ib.) of ground unburnt lime are evaporated to dryness and heated to redness in an iron vessel with the exclusion of air, the evolved gases being drawn off. The resulting material is treated in a Shanks lixiviating "apparatus, and the residue extracted in a centrifuge or filter press. The calcium compound may be extracted with acids, e.g. hydrochloric acid, and the remaining charcoal dried and ground. The filtered potassium carbonate solution of about 25Be. (specific gravity 1-21) is mixed with about 30 kilogrammes (66 Ib.) of potassium bicarbonate, evaporated to 50Be. (specific gravity 1-53) drawn off from the slight residue of potassium sulphate, and added to a fresh quantity of waste liquor for treatment as above. About 100 kilogrammes (220 Ib.) of highly active decolorizing charcoal is obtained. To obtain charcoal free from ash a mixture of 4,000 kilogrammes (8,800 Ib.) of waste liquor, 38 kilogrammes (83-5 Ib.) of calcium oxide, and 100 kilogrammes (2~20 Ib.) of unburnt lime is evap- orated to dryness and the residue lixiviated with 645 litres (142 gallons) of potassium carbonate of density 45Be. (specific gravity 1-45) derived from the preceding operation. The mixture is filtered, dried, and heated to redness, and then treated as in the first example, with the omission of the acid treatment. English Patent 102606 (1916). Paper Makers' Monthly J. vol. 55 (1917) p. 259. J. Soc. Chem. Ind. vol. 36 (1917) p. 589. Oman, E . LIGNIN AND LIGNONE DERIVATIVES. Precipitation of lignin compounds, formatiofl of nitro compounds, etc. English Patent 103649-103655 (1917). Chem. Abs. vol. 11 (1917) p. 1749. Pulp Paper Mag. Can. vol. 15 (1917) p. 719. GENERAL Ekman, C. D. WASTE SULPHITE LIQUOR. A discussion of various methods of utilization. See " Gums, Adhesives, and Sizing Materials " p. 68.) POLLUTION OF RIVERS BY, AND UTILIZATION OF, WASTE SULPHITE LIQUOR (DISCUSSION). Hofmann, C., Handbuch der Papierfabrikation (1897) 2nd edition pp. 1618, 1622. Schubert: The Manufacture of Cellulose (1899) p. 174. Griffin, R. iB. md Little, A. D.: Chemistry of Paper-making, New York (1894) p 270 and (1917) p. 270. Seidel, H. DEXTRONE. According to Seidel, Ekman's Dextrone is impure lignosulphonic calcium. The most important quality of the dry residue of waste liquors is the reducing quality. From dinitronaphthalene a brown dyestuff can be obtained as well as from dextrose. Third International Congress for Applied Chemistry, Vienna, 1898. Harpf, H UTILIZATION OF WASTE SULPHITE LIQUOR. Paper read before the third International Congress for Applied Chemistry, Vienna, 1898. Z. angew. Chem. vol. 11 (1898) pp. 876, 925, 1169. Chem. Zentr. (1899) p. 313. (See " Composition " p. 12.) . Seidel, H. and Hanak, I. WASTE SULPHITE LIQUOR. (See " Composition " p. 12.) Harpf, A. -UTILIZATION OF WASTE SULPHITE LIQUOR. Z. angew. Chem. (1898) p. 925. Jahrb. Chem. Techn. (1898) p. 114. J. Soc. Chem. Ind. vol. 17 (1898) p. 1171. Ferenczi, S RECOVERY OF WASTE FROM SULPHITE LIQUORS. Papier-Ztg. vol. 22 (1897) pp. 35715, 3647, 3679. J. Soc. Chem. Ind. vol. 17 (1898) p. 264. Seidel, H WASTE SULPHITE LIQUOR. Review of literature connected with the composition and utilization of the waste liquor. (See " Composition " p. 12.) Dorenfeldt, L. J. WASTE SULPHITE LIQUOR. A short notice explanatory of Seidel's comment (1900) on the Dorenfeldt-Drewsen process. Z. angew. Chem. vol. 14 (1901) p. 82. Gottstein, L. THE PAPER PULPS FROM WOOD AND WASTE WATER FROM THE SAME. Papier-Ztg. vol. 26 part I (1907) p. 828. J. 'Soc. Chem. Ind. vol. 20 (1901) p. 495. Fittica, F.-HISTORY OF THE MANUFACTURE OF SULPHITE PULP. L. Hirzel, Leipzig (1902). Papier-Ztg. vol. 27 (1902) part IT p. 3144. 185 186 FORESTRY BRANCH BULLETIN No. 66 . WASTE LIQUORS FROM CELLULOSE. Discuss sulphite process, and general mention of utilization as adhesives, tannins, alcohol, tannin glue. Also includes discussion of waste liquors from soda process. Pulp Paper Mag. Can. vol. 1 (1903) p. 80-82. HOW STRAWBOARD FACTORIES KILL FISH. Fish killed in White River, Indiana, U.S.A. by a sediment of gluey consistency which lodges in the gills. Pulp Paper Mag. Can. vol. 2 (1904) p. 150. Faust, A. UTILIZATION OF WASTE LIQUOR FROM PULP-MILLS. Manure, rosin, gum, tannin, alcohol. Papier-Fabr. vol. 3 (1905) p. 785. Gottstein, L. ON THE PRODUCTION OF CELLULOSE FROM STRAW AND SUPHITE WASTE LIQUOR. Remarks on R. Dietz's paper on same subject. Neither Dorenfeldt's nor Frank's process have been adopted in the pulp-mills. In the few cases where Frank's process was put into use it has in each case been given up. All the proposed uses take care of liquor from only a small fraction of the output. Refers briefly to Lindhardt's propo- sals. Wochbl. Papierfabr. vol. 36 part I (1905) pp. 1390, 1616, 1779. Z. angew. Chem. vol. 18 (1905) p. 983. Lindhardt CONTRIBUTION OF THE IMPROVEMENTS OF COOKING LIQUORS AND UTILIZATION QF COOKING LIQUORS. Zentr. oesterr-ungar. Papierind. (1905) p. 13. Z. angew. Chem. vol. 18 (1905) p. 983. UTILIZATION OF SULPHITE LIQUOR. Conference of the Verein Deutscher Zellstoffabrikanten. Behrend reported on the position of the sulphite liquor question in America. Gottstein stated that Knoesel- meal was useless. The liquor was not suitable for paper-sizing. Schacht said that Leowe, Berlin, .was using only 5 tons of liquor yearly for briquetting sand moulds. Schott had not found the liquor good for binding cement. Ferenczi said that a Hunga- rian coke-oven factory had used the liquor for briquetting but had given it up. Stein- bock held that the use of evaporated sulphite liquor as a fuel was not practicable on account of the large amount of ash and the bad odour. The amount of liquor used in Mitscherlich's factory according to Mitscherlich's patents amounts to 3 per cent of the output of that factory. Papier-Ztg. vol. 30 (1905) p. 1961. Griffin, M. L. WASTE FROM PULP-MILLS AND PAPER-MILLS. Extracts from paiper read before International Congress .of Applied Chemistry. General discussion of waste waters from soda mills and sulphite mills. Pulp Paper Mag. Can. vol. 4 (1906) p. 75. Konig, J. POLLUTION OF WATERS AND UTILIZATION OF WASTE SUL- PHITE LIQUOR. Z. angew. Chem. vol. 19 (1906) p. 750. Leisenberg, C. PURIFICATION OF WASTE SULPHITE LIQUOR WITH MILK OF LIME, FERRITE, AND ALUMINATE. Schubert, Zellstoffabrikation (1906) p. 253. Vogel, J. H. WASTE LIQUORS AND WASTE WATER FROM SULPHITE MILLS. ((See "Effluents " p. 35.) GENERAL 187 Little, A. D. PROGRESS IN THE MANUFACTURE OF SULPHITE PULP IN 1906. Experiments with waste liquor as a dust binder for roads, binder for moulding sand, tanning material. Papier-Fabr. vol. 5 (1907) p. 649. Schwalbe, C. G. LITERATURE AUSZUGE. An abstract of literature connected with the pulp and paper industry and published annually by the German Association of Pulp and Paper Chemists. Volume I, 1909, also contains literature on the waste sulphite liquor. Phelps, E. B. THE POLLUTION OF STREAMS BY SULPHITE PULP WASTE. (A STUDY OF POSSIBLE REMEDIES). The author discussed the question of stream pollution by sulphite pulp liquor referring more (particularly to conditions in the United States. A summary of the literature, taken for the most part from Cross and Bevan, Researches on Cellulose, and Seidel's Papers is given. The author investigated the action of phosphorous pentachloride on the lignin sulphonate and did not observe any reaction. No results were obtained on investigating the fusion of the lignin sulphonate with alkalies. The author tried to purify the products resulting from the treatment of the liquor with a large number of aromatic amines. The Diazo reaction was applied to these conden- sation products but without result. The action of nitric acid on waste liquor was tried and it was found that a yellow solution was produced, due to what the author calls lignum-yellow, which was capable of dyeing wool and silk. This colouring substance was isolated by evaporating the solution in vacuo. It is a light yellow ipowder, very porous and extremely hygroscopic. When dried at 100 it is decomposed with evolu- tion of nitrous oxide. It can eventually be oxidized with nitric acid to oxalic acid. Attempts to reduce this substance by various means resulted in failure. This subs- tance was also treated with amines, resulting in the production of various coloured substances. An attempt was made to prepare sulphur dyes from sulphite liquor by heating lignin sulphonate, sodium sulphide, and sulphur. A green powder resulted which seemed to act as a true sulphur dye. In place of the lignin sulphonate, some of the above mentioned amine condensation products were used, but with no different result. Water Supply Paper 226, Government Printing Office, Washington. The Paper-mill vol. 32 (No. 2 p. 19. Papier-Ztg. vol. 34 (1909) p. 726. Pritzkow, A THE PRESENT SITUATION OF THE WASTE WATER PRO- BLEM IN THE SULPHITE MILLS. In the production of 100 kilogrammes (220 lb.) of cellulose 1,000 litres (220 gallons) of sulphite liquor are produced. Some other general figures given. Mentions different proposals for utilization of liquors. (See " Effluents " p. 35.) Stutzer, A. WASTE SULPHITE LIQUOR. Z. angew. Chem. vol. 22 (1909) p. 1999. Ohem. Abs. vol. 4 (1910) p. 107. Klein A -DISCUSSION ON WASTE SULPHITE LIQUOR AT THE ANNUAL MEETING OF THE GERMAN PULP AND PAPER CHEMISTS 1909. Papier-Ztg. vol. 34 part I (1909) p. 227. Wochbl. Papierfabr. vol. 40 (1909) p. 240. Kumpf miller, A. WASTE SULPHITE LIQUOR. Contains a description of evaporation apparatus for sulphite liquor. Thesis, Munchen 1909. 188 FORESTRY BRANCH BULLETIN No. 66 WASTE LIQUOR PROBLEMS. Papier-Ztg. vol. 35 (1910) p. 2075. EFFLUENTS FROM PULP-MILLS. World's Paper Trade Review (1909) No. 3, p. 36. Fischer, E. J THE WASTE LIQUOR FROM SULPHITE MILLS. A technological study. Papier-Kalender Pfaff-Lohne, 1910. Frank, A SOLUBILITY OF CALCIUM MONOSULPHITE IN WATER. Papier-Ztg. vol. 35 (1910) part I p. 145. Stutzer, A. INVESTIGATIONS ON WASTE SULPHITE LIQUOR. a. Determination of sulphurous acid. Acetic acid recommended instead of phos- phoric acid for driving off the SO2. Description of method of analyses. ~b. Removal of the sulphurous acid from the waste liquor. In order to reduce the amount of ash substances ammonia is recommended. By evaporation to dryness all sul- phurous acid that can be driven off with acetic acid is removed. c. By addition of calcium carbonate only part of the ammonia is recovered. A large quantity remains in the residue. d. Considerably more calcium sulphite can be precipitated with ammonia than with lime sludge. Papier-Ztg. vol. 35 (1910) part II pp. 3091, 3167. Sander, A. PROGRESS IN THE CHEMISTRY AND INDUSTRY OF CEL- LULOSE 1909-1910. A review of literature on utilization of waste sulphite liquor. Fortschritte Ohemie, vol. 4 (Oebr. Borntrager Berlin 1911) p. 300. WASTE SULPHITE LIQUORS. General Discussion of the utilization of waste sulphite liquors, with notes on the following methods of utilization : (1) wood preservatives, (2) tanning materials, (3) road binder and briquettes, (4) sizing paper, (5) alcohol. Canada could produce 1,800,000 gallons of industrial alcohol worth $1,000,000 and the United States could produce 11,000,000 gallons worth $6,000,000. Pulp Paper Mag. Can. vol. 10 (1912) p. 46. WASTE SULPHITE LIQUORS. A criticism of the article on "Waste Sulphite Liquors" in the Pulp and Paper Magazine of Canada, vol. 10 (1912) p. 45. The writer states that the use of the liquor for alcohol does not solve the problem, as the waste discharged into small rivers from the alcohol plants is much more disastrous than the original waste. He regards its use as tanning and wood-preserving material as the more useful in eliminating discharge troubles. He claims that when wood is treated with waste liquor as part of the preserving material, and dried, it takes a much better finish, is harder in character, and is more highly lignified. Pulp Paper Mag. Can. vol. 10 <1912) p. 176. DEVELOPMENT OF CHEMICAL WOOD-PULP INDUSTRY IN SWEDEN AND RECLAIMING OF BY-PRODUCTS. Article contains general notes on the various attempts to utilize waste sulphite liquor. Pulp Paper Mag. Can. vol. 10 (1912) p. 314. GENERAL ^9 Muller, M. LITERATURE ON WASTE SULPHITE LIQUOR. "Literatur der Sulfitablauge " Berlin 1911 giving patents and literature on Waste Liquor up to 1911. Hutchins, E. METHODS OF TREATING PAPER-MILL WASTES. Refers to waste sulphite, liquor. Very complete articles on paper-mill waste as treated in United States. P-aper vol. 13 (1913) No. 3 p. 17; No. 4 p. 15; No. 5 p. 17. Chem. Abs. vol. 7 (1913) p. 2856.. Muller, M. RECENT RESEARCHES ON THE WASTE SULPHITE LIQUOR PROBLEM. Wochbl. Papierfabr. vol. 44 (1913) p. 2206. Chem. Abs. vol. 7 (1913) p. 3022. Walker, W. 0. THE PROBLEM OF THE WASTE LIQUORS FROM SUL- PHITE PULP-MILLS. General discussion of processes of utilization. Suggestion for research. In spite of the fact that a tremendous amount of work has been done on the subject, the problem still remains for the most part unsolved. It is to be noted that most of the investigative work that has been (gfcried on in the past has not been for the purpose of determining the actual structuraPrelations existing in the molecule of the main constituent of the organic substance of the waste liquor. This accounts, no doubt, for the meagre knowledge we possess of this substance. We can scarcely hope to make much advancement in the utilization of this substance until we know more about its composition. What we need is more purely scientific investiga- tion into the structure of the main organic substance. It is true that such an invest- igation is beset with great difficulties, owing to the inertness of the substance towards solvents. Attempts should be made toward recovery of the sulphur on the under- standing that it is in the form of a sulphonic group. At present this seems to be a chemical impossibility. If such could be accom- plished, however, the cost of the production of pulp would be considerably reduced. The work of the amine condensation products should be extended with the purpose of solving their structure, as well as for working up useful substances from them. Further work might be done to try to increase the amount of fermentable material for the production of alcohol. The subject of its use in the treatment of roads should be investigated more fully and on existing roads. Its possible use a si a binding mater- ial should be tried with a larger number of materials. In connection with this, a method for making it waterproof would be a great help. A patent has lately been granted for obtaining hydrocarbons of formula CsHs, and multiples thereof, from carbohydrates. As the liquor contains carbohydrates it would be possible to obtain turpentine and, consequently, rubber from the liquor. This should be investigated more fully. In fact, it might well form the subject of a research to be undertaken by the Canadian Government in connection with the conservation of our natural resources. ,T. Soc. Chem. Ind. vol. 32 (1913) p. 389. Chem. Eng. vol. 17 '(1913) p. 246. (See " Tanning Materials " p. 78, " Binding Materials " p. 52, and " Dye " p. 148.) Paper vol. 11 (1913) No. 9 p. 21. Klein, A. PROGRESS IN CHEMICAL PULP INDUSTRY. Deals with various improvements in the cooking process and in the digesters, and also discusses the waste liquor. Of the numerous proposals for the utilization of waste liquors for the manufacture of tanning materials, fertilizers, feeding stuffs, dyes, alcohol, etc. the author states that none has given practical results ; the most promising are the processes devised for alcohol production (see J. Soc. Chem. Ind. vol. 29 (1910) pp. 810, 1052, 1265). Strehlenert's process (J. Soc. Chem. Ind. vol. 12 (1913) p. 652) seems to be practicable. In this the sulphite liquor yields alcohol, plaster of Paris, sul- 190 FORESTRY BRANCH BULLETIN No. 66 phur dioxide and a fuel with a calorific value of 7,000 calories (12,600 B.T.U.). By Rinman's process (see J. Soc. Chem. Ind. vol. 31 (1914) p. 307) 500 kilogrammes (1,100 Ib.) of "carbon", 100 kilogrammes (220 Ib.) of spirit and acetone, and 100 kilo- grammes (220 Ib.) of motor spirit are said to be recovered per metric ton (2,204 Ib.) of cellulose. Papier-Fabr. vol. 12 (1914) pp. 601, 630. J. Soc. Chem. Ind. vol. 33 (1914) p. 1201. Paper vol. 14 (1914) No. 22 p. 15; No. 23 p. 16; 'No. 24 p. 22; No. 25 p. 17. Lassar-Cohn THE PROBLEM OF UTILIZATION OF WASTE WATER FROM THE SULPHITE MILLS. The addition of waste liquor to the city sewer for irrigation fields has proved successful in Konigsberg (Germany). Leading the waste liquor into the Haff has proved beneficial to the fish. Chem.-Ztg. vol. 38 (1914) pp. 639, 657. Paper vol. 14 (1914) No. 17 p. 23. Gottstein, I. THE PROBLEM OF UTILIZATION OF WASTE WATER FROM SULPHITE MILLS. A criticism of tfe Lassar-Co'hai article. Chem.-Ztg. vol. 3#'(1914) p. 804. Scott, J. UTILIZATION OF WASTE SULPHITE LYE. Piaper-Maker British Trade J. vol. 47 (1914) p 396. Chem. Abs. vol. 8. (1914) p. 2620. Muller, M. LITERATUR DER SULFITABLAUGE. A collection of literature upon the waste sulphite liquors problem from 1910 to 1913. Giintter-Staib, Biberach, 1914. Bryant, 0. F. SULPHITE PULP LOSSES. Paper read before Canadian Pulp and Paper Association. Short description of Kumpfmiller's process for tanning, Ekstrom's alcohol process, and Strehlenert's fuel process. Pulp Paper Mag. Can. vol. 13 (1915) p. 139. Paper, vol. 15 (1915) No. 26, p. 15. McKee, K. H PROGRESS IN PAPER-MAKING CHEMISTRY. Note on sulphite waste liquors. Two mills in the United States are producing alcohol from the waste liquor. The yield is about 15 gallons (U.S.) of 95 per cent alcohol per ton of sulphite pulp. The slops are as objectional as the original waste liquor. Pulp Paper Mag. Can. vol. 13 (1915) p. 165. \ Dickerson, W. H. THE DISPOSAL OF WASTE SULPHITE- LIQUORS. Paper read before the Technical Association of the Pulp and Paper Industry. Discussion of the problem in a general way: Robeson Process Co., International Paper Company (binder) ; West Virginia Pulp and Paper Co., N.Y. (alcohol) ; Crown- Willamette Paper Company and Kimberley-Clark Co. (development work on alcohol). "Whatever use or uses are to solve the problem, it is not going to be the dye in- dustry or similar outlets consuming a small quantity of high-class materials. It will rather be by some use or uses that will consume a large tonnage at a very small margin of profit." GENERAL 191 The sulphite production in the United States amounts to about 4,500 tons per day which involves the production of approximately 7,500,000 imperial gallons of waste sulphite liquor containing 4,500 tons of solid material. It was shown in the discussion that for each ton of pulp about 1,500 pounds of solid matter drained off and this could be increased to 2,000-2,100 pounds by the use of special apparatus. Paper vol. 19 (1917) No. 20 p. 19, No. 21 p. 17. Bates, J. S. PRESENT AND POSSIBLE PRODUCTS FROM 'CANADIAN WOODS. Possible products of waste sulphite liquors. With Chart. Pulp Paper Mag. Can. vol. 15 (1917) p. 553. INDEX OF AUTHORS Abraham, F., 96 Achenbach, H., 159, 160 Ahrens, F. B., '19, 26, 142 Aktiebolaget Ethyl, 11-5, 117, 118, 124 Aktieselskabet ISulfltsprit, 124, 179 Albersheim, M., 94 Albert, K., 61 . Y Alt, H., 151 Appelius, IW., lO'O, 102 Arlt, O., 141 Auerbach, J., 94 Aufhauser, D., 63 Bache-Wiig, B., 170 iBadermann, G., 58 :Bactische Anilin und Soda Fabrik, 1512, 173 Baekeland, L. H., 176 IBanning, 3>9 IBanthier, G., 32 Bantlin, G. 178 Earth, K., 16 'Bates, J. S.. 191 iBeeker, H., 101 .Behrend, OL., 61 ^Bennett, H. G., 91 Bergerhoff, E., 173 IBergstrom, (H. O. V., M, 108, 111, 161, 174-5, 180 Bevan, E. J., 69, 148 Beveridge, J., 1'03, 181 Bibb, D. H., 66 iBlackman, IB., 82, 15 G Blockmann, R., 1'59 iBloesch, K., 72 Brelaz, G. H., 69, 81 iBriggs, J. F., 131 iBrookes, A. G., 72:, 141, 156 ;Bruck, E., '38 (Brunet, iL., 157, 159, 164 'Bryant, O. iF., 19'0 Bucherer, H., 166 ,Buddens, W., 17 \Buisson, J.. 6)3, 164 Byrom, F. G., 103 Carlson, T., 27, 44 Carpenter, 58 Chemische Fabrik Floersheim, 144 Chemische IFabrfk Grxinan, 155 Chemische Industrie und Handelsgesellschaft, 92 Claflin, A. A., 9 1 Classen, A., 107 Coughlin, iM. F., 177-8, 184 Cremer, B., 12*9 (Cross, C. F., 6'9, 148 Cushman, A. iS., 62 De'Cew, J. A., 7'6, 174, 179 Detsinyi, F., 136 Deutsche ISaduyn Gesellschaft, 17'3 Diamond, B., 17I2-.3 Dickerson, W. H., 34, 89, 94, 100, 157, 165, 190 Dieckmann, R.. 34 Dorenfeldt, IL. J., 129, 156, 17'0, 185 Drewsen, V., 155, 170 Dunbar, IL., 161 Durr & Co.. 37 4912013 Eitner, W., 89,, 96 Ekman, C. D., 38, 70, 71, 72, 82, 148-9, 185 Ekstrom, G,, 10-8-9, 111, 112, 115-18, 122^ 131, 177 Elb, M., .55, 73 Ellis, C., 62, &5, 66', 76, 158, 164-5, 171 Enger, P. G., 183 Engler, 13'7 Erste Oesterreichische Sodafabrik, 151 Farbenfabriken vorm. Friedr. Bayer, 157-8 Farbwerke, Friedrichsfeld, 71 Faust, A., 92, 186 Ferenczi, IS., 3'9, 176, 18>5 Fest, A. D., 160 Fischer, E. J., 188 Fischer, F., 39 Fittica, F., 185 Forrester, G. P., 114 Fosse, H. W., 18*0 Foth, G., 112, 117 Frank, A., 16, 2'7, 37, 136, 137, 139, 141, 154-5, 188' Franke, G., 6'0 Franke, H., 93 Freeman, (W. K., 67, 181 Gansser, A., 9.3, 100 Gawalowski, "A., 170 Gewerkschaft, lEduard, 55>-8 Gianoli, G., 94 Goldschmidt, E., 3'9, 136 Gottstein, iL., 37, 40, 49, '50, 18-5-6, 190 Goy, S., 140 Graetz, B., 51, 63, 66 Graf, G., 157 Grempe, P. M., 6'3 Griffin, (M. 'L., 5,3, 157, 186 Grimm, H., 31 Gross, F. F., 91, 101, 10-3 Grosser, G., 9'3 Grothe, O., lO'O, 10'2, 177 Gumbel, G., 53, 7'0 Gunther, W., 61, 178 Haage, ,W., 5'9, 6*0 Haeffner, A. H., 77 Hagglund, E., 33, 122, 125 Hanak, L., 2)3, 2'5, 15-0, 162, 18'5 Harpf, A., 17, 122 Harpf, H., 1815 iHar rocks, W. E., 101 iHartmann, 168 Harvey, A., 104 Haussner, A., <37 Hedalen, J., 122 Hedden, M. W., 180 Hirst, S., 86 Hoesch & Co., 64, 144^5 Hofer, H., 41, 50 Hoffmann, M., 142 Hofmann, C., 22, 38, 156, 162, 169 Honig, M., 2*9, 31, 82-4, 87, 88, 91, 100 Hoskins, W., 51 Hough, Wm. J., 7i5, 17'2 Hurt, H. H., 97, 102 Hutchins, E., 189 194 FORESTRY BRANCH BULLETIN No. 66 International Association of (Leather Trade lOhemists, 9'3 International Congress Appl. 'Chem., Vienna, (2nd., 1898) 150 Jabs, iA., 6-6 Jedlica, F., 9-5 Jernberg, A. V., 124 Johnson, J. Y., 8'5, 86 Jiirgensen, F., 5'3, 70 Rammer er, IF. J. F., 170 Karr, O., S3 Katz, A., 73 , Kausch, 6(3, 7'6 Kayser, H., '57, 58, H29, 163 Kempe, D., 82 Kennard, F. H., 1&5 Kern, (L., .146-6 Kerp, rw., 27, 31 Kerschaw, G. B., 47 Kertesq, Z., 34, 18-3 Kestner, P., 16'3 Kiby, W., 110, 121 Kielmeyer, A., 151 Kirchner, E., 42, 172 Kiteee, I.. 75 Kjaer, A. H. & Co., 132 Klason, P., 2-9, 32, 34, 4-5, 75, 124 Klein, A., 18>7<-9 Klemm, P., 40 Knight, O. -W., 18-0 Knoesel, Th., 22, 57, 137, 141-4 Knopflmocher, A., 184 Kolkwitz, R., 43, 44, 49 Konig, J., .36, 4)2, 139, 140, 186 ' Koppert, K., 17 ( KonwJorff, Th., '36 Krause, G. A., 16<6 Krause, H., 26 Kressel, E. C. L., 147 Kruger, F., 7i3 Kuhn, A. D. J., 161 Kuhn, R., 71 Kumpfmiller, A., S6. 74, S<3-5, 87 1.5-7, 162, 16'4, 171, 187 (Landmark, H. /B., 76', 89, 102-3, 114, 116, 118^20, 131, 1313, 161, 167 (Landshoff, 156 Nitsche, P., 144 iNorton, T. H., 11,2 Novak, J., 16-2 Oberlander, IL., 7'0 Oesterreichischer Verein fur Cellulosefabri- kation, 43, l'5'O Oman, E.. 33. 34, 122-4, 153, 179, 182, 184 Onsager, G. T., 12iO Opitz, '58, 16'3 Opl, C., 81 Oulman, C., 55, 59 Paeszler, 84, 91, 101 Parker. J. G., 98 Partington, E., '5*5 Patch, F. H., 76' Phelps, E. B., 151, 153, 18>7 Philippi, W. H., 84, 87, 92 Pictet, R. P., 69, 81, 154 Platseh, M., 6-2, 64, 89, 94, 176, 179 Pollacsek, E., 39, 54, 6>2, 613, 6"5, 66, 17'0 Pollak, J., 151 Polz, H., 48 Pritzkow, A., 4.3, 44, 46, 48, 187 Procter, H. R., 86 Puririg, J., 182 Raaz, A., 14'9 Ramsay, W., 40 Raschig, F., 175 Reed, >H. C., 183 Reilley, A. E. J., 12-3, 13-5 Reinitzer, IB., 4'7 Remy, P., 71, 169 Richter, A., 61, 161 Rinman, E. L., 177-8, 181, 18 ! 2 Robeson, J. IS., -57, 68, &4, 6-5, 74, 75, 86, 176 Robeson Process Co., 67, 182 Rogers, J. J., 7'3 Rohland, P., 48, 49 Rosenband, M., 108 Rosenblatt, 9 Strehlenert, R. W., 130-1, 133-5, 158, 183 IStutzer, A., 28, 29, 39, 49, 9-5, 137-9, 142, 145, 151-2, 157-8, 174, 18*7-8 Sudenburger iMaschinenfabrik, 164 Sundiblad, G. K., 175 Szamek, J., 162 Tartar^ H. V., 12*3 Tavernier, A. E., 5>5, 59 Teas, 'W. H., 8 ft Techn. Verein fur Zuckerfabrikation, 49 Thalan, W., 145 Thorne, C. >B., 158, l&O Tilghman, B. C., 68, 141 Tillberg, E. W., 8>5, 108, 171 Tillmann, J., 49 Tollens, IB., 17, 18 Trainer, E., 64, 55, 59, 76, 129, 171, 172 Trainer E., Heirs of, 12'0, 140, 146 Trippe, W., 156 Tullis, J. K., 101 Turk, G., H56 Ullmann, H., 53 Ulzer, F., 22 Verein Deut&cher Zellstoffabrikanten, 42 Voerkelius, 113 Vogel, J. H., 40-44, 46, 49, 138, 186 Voitel, K., 94 'Wagner, B. f 56 Walker, W. O., 3-0, 50, 64, 97, 116, 189 Wallin, J. H., 108-9, 114-15 Walsh, J. P., 66 Walther, R. von., 159 Webster. M., 3<7 Wegelin.'A., 180 'Weigelt, C., 3'9, 4<3 Weiskopf, A., &3 Weld, F. W., 17 Weldert, R., 59 Wellensick, IF., 48 Welsh, J., 181 Wernecke, E., 163 Wichelhaus, ., 38, 155 Winter, H., 94 Wint'hol, A. G., 66 Woddrop, L,. H., 67 Wohler, P., 27, 31 Wolesky, F., 165 Wolf, R. B., 160 Tocum, J. H., 92 Zawadski, 168 Ziegler, A., 82 , . Zweiberg, G. von., 30 .'.I PUBLICATIONS ISSUED BY THE FORESTRY BRANCH Annual Report of the Director of Forestry, 1914-15-16-17. Bulletin 1. Tree-Planting on the Prairies. 8. Forest Product* of Canada, 1908. 11. Forest Products of Canada, 1909: Lumber, Square Timber, Lath and Shingles. 12. Forest Products of Canada, 19O9: Pnlpwood. 14. Forest Products of Canada, 1909: Cross-ties Purchased. 15. Forest Products of Canada, 1909. (Being Bulletins 11, 12, 13, 14, 19 and 2O.) French edition only. 16. Forest Fires and Railways. 22. Forest Products of Canada, 19 1O: Cross-ties. 23. Forest Products of Canada, 1910: Timber Used in Mining Oper- ations. 24. Wood-using Industries of Canada, 1910: Agricultural Implements and Vehicles, Furniture and Cars and Veneer. 27. Forest Products of Canada, 1910: Cooperage. 32. The Turtle Mountain Forest Reserve. 33. Forest Conditions in the Rocky Mountains Forest Reserve. 34. Forest Products of Canada, 1911: Lumber, Square Timber, Lath and Shingles. 35. Forest Products of Canada, 1911: Poles and Cross-ties. 36. Wood-using Industries of Ontario. 37. Forest Products of Canada, 1911. (Being Bulletins 30, 31, 34 and 35.) 38. Forest Products of Canada, 1912; Pnlpwood. 39. Forest Products of Canada, 1912: Poles and Ties. 40. Forest Products of Canada, 1912; Lumber, Lath and Shingles. 42. Co-operative Forest Fire Protection. 44. Wood-using Industries of the Maritime Provinces. 46. Forest Products of Canada, 1913: Pulp wood. 47. Forest Products of Canada, 1913: Poles and Cross-ties. 48. Forest Products of Canada, 1913: Lumber, Lath and Shingles, 49. Treated Wood-block Paving. 51. Game Preservation in the Rocky Mountains Forest Reserve. 52. Forest Products of Canada, 1913. (Being Bulletins 46, 47 and 48.) 53. Timber Conditions in the Smoky River Valley and Grande-Prairie Country. 54. Forest Products of Canada, 1914: Pulpwood. 56. Forest Products of Canada, 1914: Lumber, Lath and Shingles. 57. Forest Products of Canada, 1914: (Being Bulletins 54, 55 and 56.) 58. Forest Products of Canada, 1915: (Being Bulletins 58a, 58b, and 58c). 58a. Forest Products of Canada, 1915: Lumber, Lath and Shingles. " 58b. Forest Products of Canada, 1915: Pulpwood. 58c. Foresit Products of Canada, 1915: Poles and Cross-ties. 59. Canadian Woods for Structural Timbers. 60. Canadian Douglas Fir: Its Mechanical and Physical Properties. 62a. Forest Products of Canada, 1916: Lumber, Lath and Shingles. 62b. Forest Products of Canada: Pulpwood. " 62c. Forest Products of Canada: Pales and Cross-ties. " 02(1. Forest Products of Canada: Directory of Saw-mills in Canada. " 63. Wood-using Industrie* of Quebec. 64. Forest Fires in Canada, 1914-15-16. 65. Forest Products of Canada, 1917: Poles and Cross-ties. Circular 5. Planning a Tree Plantation for a Prairie Homestead. " 6. Preservative Treatment of Fence-posts. 8. The Forest Prodnets Laboratories. 9. Chemical Methods for Utilizing Wood Wastes. Makers Syracuse, N. Y. PAT. JAN. 21, 1908 43 UNIVERSITY OF CALIFORNIA LIBRARY