ON HARDENED CHRYSALIS OIL

applied the method proposed by H. Kreis and E. Roth2 which had been modified and applied to the analysis of the hardened oil by W. Normann and E. Huge...
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T H E J O U R N A L O F I N D U S T R I A L A N D ENGI,%rEERIIVG C H E M I S T R Y ON HARDENED CHRYSALIS OIL B y MITSUMAKU TSUJIMOTO Received August 2, 1915

Raw chrysalis oil is unsuitable for t h e purpose of hydrogenation, as its nitrogenous a n d other impurities largely affect t h e activity of t h e catalyzer, even if we neglect t h e dark color a n d bad odor of t h e oil. Hon7ever: t h e refining of chrysalis oil is b y no means an easy one; b u t t h e process proposed by t h e author, which essentially consists in heating t h e oil with j t o I O per cent b y vol. of dilute sulfuric acid (sp. gr. 1.39) and then treating it with Kambara e a r t h , gives an excellent result.' The refined oil hardened by nickel catalyzer is a white fat which may be used as a useful raw material for soap-making. T h e composition of chrysalis oil has been as yet little investigated. T h e results of experiments published b y t h e author some years ago appear t o be t h e only report on this subject.2 According t o this rep o r t , t h e f a t t y acids of chrysalis oil consist of about 2 5 per cent saturated a n d 7 5 per cent unsaturated acids (iodine value 178.73). Among t h e saturated acids, palmitic acid was identified; stearic acid is probably not present. T h e unsaturated acids consist of oleic, linolenic and isolinolenic acids ; besides them, some isomers of linolic acid are present in a somewhat large quantity. If t h e conclusion of t h e above-mentioned investigation be really t h e case, t h e final product of t h e hydrogenation of these unsaturated acids must be stearic acid. X s t u d y of t h e product i s . i m p o r t a n t from t h e point of view of utilizing t h e hardened chrysalis oil for technical purposes. T h e author made a few experiments which are described below. I-HYDROGEK-ATIOZ

OB

THE

UXSATCRATED

(LIQUID)

FATTY ACIDS O F CHRYSALIS O I L

Fifty grams of chrysalis oil3 were saponified in a flask with 38 cc. of j o per cent aqueous solution of K O H a n d 113 cc. of 96 per cent alcohol, b y warming on a water b a t h ; t h e excess of alkali was neutralized with acetic acid and j o o cc. of 7 per cent aqueous lead acetate solution was stirred into. The resulting lead soap was twice washed with joo cc. of hot water a n d treated with 500 cc. of ether a t 10' C. a n d t h e n filtered (Tortelli and Ruggeri's method). T h e filtrate was t h e n treated with dilute HC1, in order t o decompose t h e lead soap, and was well washed with water: 2 5 0 cc. of t h e ethereal solution of t h e free unsaturated acids t h u s obtained. which contains about 2 0 g. of t h e acids of iodine value 176.17, were transferred into a strong glass bottle; 0 . j g. of Loew's platinum black was added. The bottle was t h e n connected t o a hydrogen h01der.~ On expelling t h e air from t h e bottle b y hydrogen, it was strongly shaken by means of a J . Chem Ind., Tokyo, 17, No. 191; Chem. Rev., 1914, 58. 2 J . toll. Eng., Tokro, 4 (1908). KO. 3 ; J . SOC.Chem. Ind., 1908, 455. 3 This sample of the oil was procured from an oil factory in Ibaraki prefecture. I t had the following properties: acid value 104.84, saponification value 187.03, and iodine value (Wijs) 140.33. 4 Hydrogen was prepared by pure zinc and dilute HzSOI, and passed through the wash bottles containing concentrated potassium permanganate solution and concentrated HISOP.

Vol. 8. No. 9

mechanical contrivance. After 31,"2 hrs. Shaking, a loss of about 2900 cc. of hydrogen was observed on t h e holder. Here t h e hydrogenation was stopped for a time. On evaporating off t h e ether, a residue amounting t o 1 7 . j 2 g. was obtained. It was a brown-yellow crystalline mass which when melted formed a brownred liquid; i t melted a t j6.2' C., having t h e neutralization value 188.92 a n d iodine value 45.91. The hydrogenation was apparently incomplete; b u t before continuing the operation, i t was found better t o remove t h e unsaponifiable a n d coloring matters from t h e product. Eleven grams of t h e above product were saponified with j o cc. of 8 per cent alcoholic solution of S a O H ; t h e n j g. of N a H C 0 8 a n d about j o g. of pure sand were thoroughly mixed with i t . The mass was dried, powdered and exhausted in a Soxhlet extractor with petroleum ether. The crude unsaponifiable matter thus extracted was 2 . 2 2 per cent. T h e soap i n t h e extractor was dissolved in hot water and decomposed with dilute HC1 a n d t h e n taken u p with ether. The ethereal solution of t h e f a t t y acids which appeared brownish yellow, was decolorized with animal charcoal, a n d made u p t o 2 j 0 cc. by adding ether; t h e n adding 0.3 g. of t h e platinum black. it was hydrogenized for 2 hrs. in t h e same way as before ( t h e reading of t h e volume of hydrogen was omitted). On evaporating off t h e ether, 8.3 g. of t h e hydrogenated acids were obtained. The white crystalline mass had a melting point of 68 t o 68. j oC., neutralization value 19j.19 a n d iodine value 0 . This product is therefore a saturated compound, which in its m. p. and neutralization value nearly coincides with stearic acid ( m . p. 69.3' C., neutralization value 197.5, molecular w t . 284). A mixture of t h e product with about a n equal quantity of pure stearic acid melted at 68 t o 68.3' C. In order t o perform t h e fractional crystallization of t h e acids, 5 g. of t h e hydrogenated product were dissolved i n IOO cc. of 90 per cent alcohol a n d separated into three portions successively as follows : (1) 4 . 2 i g . ; white laminae with pearly luster; m. p . 69.5 to 70' C . ; neutralization value 197.82; mean mol. wt. 283.59. A mixture with pure stearic acid melted at 69.5 to 69.7' C . (2) 0.21 g . ; m. p. 68' C.; neutralization value 197.20. (3) Residue left on evaporating the mother liquor. 0.41 g.; a little colored solid; m. p. 50' C . ; neutralization value 177.42.

The lorn. m. p . a n d neutralization value are probably due t o t h e accumulation of t h e impurities in this part a n d also t o t h e esterification of the acids on evaporating off alcohol. The result of t h e elementary analysis of ( I ) was as f olloa~s: 0.1245 gave 0.3487 COz and 0.1439 HzO; C = 76.39; H = 12.84 ClsHseOz requires C = 76.06; H = 12.68.

1

Therefore, t h e substance was confirmed t o be stearic acid. From t h e above experiment, i t was concluded t h a t t h e hydrogenated product of t h e unsaturated f a t t y acids of chrysalis oil consists mainly of stearic acid.

Sept., 1916

T H E J O U R N A L OF I N D U S T R I A L A N D E N G I N E E R I N G C H E M I S T R Y

11-ON T H E S A T U R A T E D (SOLID)

F A T T Y ACIDS OF

C H R Y S A L I S OIL

Although t h e saturated acids have no direct relation t o hydrogenation, a n experiment supplementary t o t h e former investigation1 was performed as follows : T h e impure lead soap of t h e solid f a t t y acids obtained in t h e previous experiment on t h e liquid acids, was carefully detached from t h e filter paper a n d heated i n a beaker with dilute HC1. T h e acids were t h e n dissolved in ether a n d decolorized with animal charcoal. T h e crude solid acid which was left on evaporating off t h e ether, formed a yellow colored crystalline mass. T h e yield amounted t o 11.j g. By dissolving i n IOO cc. of 96 per cent alcohol, it was fractionally crystallized into five parts. (1) 3.78 g . ; granular crystals; on melting. solidifies t o a grayish white mass; m. p. 55-55S0 C.; neutralization value 205.09. (2) 1.40 g.; m. p. 55.5-56' C.; neutralization value 209.30. (3) 0.77 g.; somewhat granular crystals, faintly yellow; m. p. 56.5' C.; neutralization value 210.70. (4) 0.21 g.; pale yellow laminae; m. p. 57' C. ( 5 ) 3.61 g.; residue from the mother liquor; an orange-yellow soft mass.

filtered through a filter paper; t h e precipitated lead salt was washed well with alcohol a n d decomposed b y dilute hydrochloric acid. T h e free acid was taken u p with ether, a n d washed free from t h e mineral acid; t h e ether was t h e n evaporated and a white solid acid was left. I t was dissolved in 2 5 cc. of 90 per cent alcohol a n d cooled t o room temperature for 30 min. The mother liquor was filtered off; t h e deposited crystals were dried b y pressing between dry filter papers. It was t h e n twice dissolved in 1 2 . 5 cc. a n d 6 cc., respectively, of 90 per cent alcohol b y repeating t h e same t r e a t m e n t as above. The final deposit weighed 0.35 g. and consisted of nacreous laminae; m. p. 69.5-70' C . ; neutralization value 194.76. This substance was, therefore, identified as stearic acid. No saturated acid higher t h a n stearic was found in t h e hardened chrysalis oil. This result is in a good accordance with t h a t obtained in t h e previous experiment. IV-INNER

A mixture of 3 g. consisting of 2 . 2 g. of ( I ) a n d 0.8 g. of (2) was dissolved in I O O cc. of 96 per cent alcohol a n d fractionally precipitated with magnesium acetate into the following fractions: (1) 0.9895 g.; m. p. 55.5' C.; neutralization value 203.22; mean mol. wt. 276.05. (2) 0.4920 g.; m. p. 56' C.; neutralization value 205.43; mean mol. wt. 273.09. (3) 0.4305 g.; m. p. 59' C.; neutralization value 207.98; mean mol, wt. 269.74. (4) 0.4785 g.; m. p. 60.5-61O C . ; neutralization value 215.25; mean mol. wt. 260.16. (5) No precipitate was obtained by adding an excess of the precipitant. Therefore, i t was abandoned. (The acid contained in this p a r t corresponds t o 0.6095 g.)

The result is not decisive, b u t i t is certain t h a t a n acid or acids higher t h a n palmitic are present. T h e mean molecular weight of about 2 7 0 seems t o point t o t h e presence of daturic acid, C17H34O2. But as b y repeated precipitations, t h e m. p. a n d neutralization values are regularly changed a little, i t is more probable t h a t the 'substance under examination consists of a n eutectic mixture of stearic a n d palmitic acids. 111-DETECTION

OB H I G H E R S A T U R A T E D F A T T Y ACIDS I N H A R D E K E D CHRYSALIS OIL

T o decide whether t h e hardened chrysalis oil contains s a t u r a t e d acids higher t h a n stearic, t h e author applied t h e method Proposed b y H. Kreis a n d E. R o t h ? which h a d been modified a n d applied t o t h e analysis of t h e hardened oil b y W. Normann a n d E. Hugel. 3 Ten grams of t h e mixed f a t t y acid obtained f r o m a hardened chrysalis oil4 (an oil f r o m Nagano prefecture hardened b y means of nickelcatalyzer) weredissolved in IOO cc. of 96 per cent alcohol in a flask. By heating it on a water b a t h , 0 . 7 5 g. of lead acetate dissolved in j o cc. of alcohol was added. On cooling t h e SOlUto the room temperature '*), it was Soon

' LOC. Cil.

Chem.-Zlg.. 1913, 58. Ibid., 1913, 815. Chem. Rea., 1914, 58. This sample is t h e No. B hardened oil. Its properties are as follows: m . p. 56' C.; acid value 57.16; saponification value 190.71; iodine value 35.81. 2

3

4

803

IODINE

VALUE

OF

HARDENED

CHRYSALIS

OIL

It has been shown by J. Marcusson a n d G. Meyerheim,' t h a t t h e inner iodine values of hardened fish oils are higher t h a n 100, whereas lower values are found in t h e cases of hardened terrestrial animal oils. With a sample of "Talgol" which is of fish oil origin, t h e y found a value of 107. While belonging t o a class of terrestrial animal oils, as chrysalis oil has a high iodine value, it appears not unlikely t h a t t h e inner value of t h e hardened product still exceeds 100, a n d so in this respect it may resemble fish oils. T o determine this, t h e author used t h e following two oils for examination: (A) T h e same sample used in t h e previous experiment 111. (B) A hardened oil having t h e following properties: m. p. 56-56.5" C.; acid value j7.46; saponification value 191.08; iodine value 45.j3. [The origi.naZ chrysalis oil was t h e same as ( A ) , t h e time of hydrogenation only being different.] Three grams of t h e sample were treated i n a manner equivalent t o Tortelli and Ruggeri's method. After keeping a t 6 t o 10' C. for 21/2 hrs., t h e ether solution of t h e lead soap was filtered off and decomposed with hydrochloric acid. T h e iodine values were determined b y Wijs' method. The inner iodine value of sample A? was 87.60; of sample B, I o 3 . 2 2 , nearly approaching t h a t of Talgol. " I n spite of t h e low iodine value (45.53) of Sample B, t h e inner value was comparatively very high, for a sample of t h e hardened chrysalis which has an iodine value near to t h a t of " ~ ~ 1 ~(iodine ~ 1 "value 65 t o 70), a still higher inner value m a y be expected. Of course, t h e process of hydrogenation, i. e., t h e catalyzer] temperature, time, a n d method of stirring, etc., will essentially influence t h e inner iodine value "

so,

angew. Chem., 1914, 201. T h e liquid f a t t y acids of this sample obtained as above, solidified a t the room temperature. It seems, therefore, t o have contained more or less solid f a t t y acids. 12.

2

804

T H E JOURNAL OF INDUSTRIAL A N D ENGIXEERING CHEMISTRY

of the product. T h a t hydrogenation takes place by degre’e according t o t h e unsaturation of t h e f a t t y acids, will not always be anticipated. It will be, therefore, unsafe t o attach too much importance t o the inner iodine value oi a hardened oil without taking into account the iodine value of the oil itself. For hardened chrysalis oil of a n iodine - \ d u e above jo, an inner iodine value exceeding I O O may probably be expected. V-

S U &I MAR Y

The results of t h e present investigations may be summarized as follows: I-The hydrogenated product of the unsaturated f a t t y acids of chrysalis oil consists mainly of stearic acid. 11-Besides palmitic acid. some higher saturated acid or acids are present in chrysalis oil. This substance is probably an eutectic mixture of stearic and palmitic acids. 111-By t h e Kreis and R o t h method, no saturated acid higher t h a n stearic was found in t h e hardened chrysalis oil. IV-An inner iodine value exceeding IOO may probably be expected in t h e case of a hardened chrysalis oil having t h e iodine value above 50. INDUSTRIAL EXPERIYEXT STATION

TOKYO, JAPAX

THE USE OF DIPHENYL GLYOXIME A S AN INDICATOR IN THE VOLUMETRIC DETERMINATION OF NICKEL BY FREVERT’S METHOD R p G. I,. KELLEYA N D J. B. CONANT Received December 2, 1915

A volumetric method for determining nickel in iron and steel as devised b y H. L. Frevert was published in Blair’s “Chemical Analysis of Iron,” 7th edition, 1912. Since t h a t time the method has been constantly in use in this laboratory, b u t inasmuch as some small changes have been made from time t o time i t seems best t o republish t h e method with these modifications. Accordingly me give below Frevert’s method as originally proposed. except for t h e modifications mentioned above, and follow it with a discussion of t h e use of diphenyl glyoxime as an indicator. FREVERT’S METHOD F O R THE DETERMINATIOK

OF NICKEL

I N STEEL

( A ) SOLUTION O F T H E sAI\IPLE-For ordinary nickel steels, a I-g. sample is taken, b u t mith less t h a n 0.10or more t h a n j per cent of nickel,larger orsmaller samples may be taken. I n t h e absence of more t h a n small amounts of chromium, solution is most rapid in j o cc. of hot dilute nitric acid (sp. gr. I . I ~ ) b, u t with chromium present in amounts greater t h a n 0 . 5 per cent, or under circumstances where chromium carbides are present, more satisfactory results are obtained b y dissolving t h e sample in 60 cc. of dilute hydrochloric acid ( I : I ) with t h e aid of heat. When solution is complete, t h e iron and t h e carbides are oxidized b y adding nitric acid, drop b y drop, until effervescence ceases. Boiling removes the products resulting from t h e decomposition of the nitric acid after which t h e solution is cooled. T h e quantities

VO~. 8, NO. 9

of acid given here are those which are convenient €or use with samples of I g. or less. ( B ) P R E C I P I T A T I O N O F K I C K E L D I X E T H Y L GLYOXIXE--

T h e solution obtained, as described above, is rapidly cooled b y the addition of a lump of ice, after which are added in succession: 1 2 g. of citric acid or equivalent solution, 20 cc. ammonia water (sp. gr. o . 9 0 ) , sufficient solution of dimethyl glyoxime t o precipitate all nickel present and enough more ammonia t o make the solution distinctly ammoniacal. The mixture is thoroughly stirred after each of these additions. The solution of dimethyl glyoxime is prepared b y dissolving 2 0 g. of the reagent in 1300 cc. of ammonia water (sp. gr. 0 . 9 0 ) , after which enough water is added t o bring the volume u p t o 2000 cc. Ten cc. of this solution allow sufficient excess t o completely precipitate 1 . 5 per cent of nickel in a I-g. sample, i. e., about 0.01 j o g. of nickel. (C) T R E A T X E N T O F K I C K E L D I M E T H Y L G L Y O X I b I E PRECIPITATE--When the amount of nickel is small (0.10 per cent or less), time must be allowed for complete precipitation- an hour is usually ample. With amounts larger t h a n this, no danger of lorn results attends immediate filtration. For this purpose an asbestos mat on a z-in. perforated porcelain plate or a Buchner funnel may be used. The solution containing the suspended precipitate will usually have a volume of zoo t o 2jo cc. It should be stirred thoroughly and poured on t o the asbestos mat in such a way t h a t the funnel always remains partly filled with liquid. Strong suction should be avoided. Quantities of precipitate corresponding t o less t h a n j per cent of nickel in a 1-g. sample rarely cause trouble in filtering. b u t the difficulty rapidly increases with larger amounts. When all of t h e precipitate has been transferred t o t h e asbestos, i t is thoroughly washed with water. Both wash water and filtrate are discarded, although t h e latter may be tested with dimethyl glyoxime if i t is believed that all of t h e nickel may not have been precipitated. (D)

SOLUTIOK

AND DECOhIPOSITIOK

O F THE PRECIPI-

TATE-The receiving flask and tip of t h e funnel are next well rinsed with water. With the mat still in place, b u t with suction off, enough nitric acid is added t o in. After a minute, cover the asbestos t o a depth of suction is applied, t h e acid drawn through t h e filter and about as much more added, taking care t o c o \ w the entire surface. At this po:nt there should remain no visible trace of the red precipitate. The mat is now t o be thoroughly washed with water, t h e washings being collected in t h e flask with the acid. The solution so obtained is then transferred t o a 400 cc. beaker in which it is heated t o boiling. Here the solution is ailotved t o cool slightly t o facilitate t h e addition of I g. of either potassium chlorate or ammonium persulfate. The solution is boiled until clear; this usually involves a considerable reduction in bulk, often as much as jo per cent, Insufficient boiling may cause trouble ( I ) through failure t o decompose t h e dimethyl glyoxime, which would reprecipitate when t h e s olution is subsequently made ammoniacal, or ( 2 ) because if t h e solution is not freed from oxidizing products