July, 1917 THE JOURNAL OF INDUSTRIAL AND ENGINEERING

July, 1917. THE JOURNAL OF INDUSTRIAL AND ENGINEERING CHEMISTRY. 68j of magnesium salts. Both of these prxciples we have found in our hands to ...
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July, 1917

T H E J O U R N A L OF I N D U S T R I A L A N D ENGINEERING CHEMISTRY

of magnesium salts. Both of these prxciples we have found in our hands t o be efficient. We wish, however, t o present an additional method which is based on a somewhat different principle, and in certain kinds of molybdate residues may be desirable. T h e method consists in t h e precipitation of molybdenum sulfide from a solution slightly acid with nitric acid by means of hydrogen sulfide or t h e formation of a sulfomolybdate solution b y adding hydrogen sulfide t o t h e alkaline solution of t h e “yellow precipitate” a n d subsequently adding hydrochloric acid t o precipitate t h e molybdenum sulfide. Molybdenum sulfide when ignited gives Moo3, which is in condition t o be used again. I n applying t h e method t o waste molybdate liquors which are usually quite strongly acid with nitric acid, t h e solutions should be strongly diluted or t h e excess of free acid should be in large part neutralized with sodium hydroxide, so t h a t t h e limits of acidity should be between 0.1 a n d 0.4 per cent. Hydrogen sulfide gas is t h e n passed through t h e solution. The sulfide settles more rapidly, however, if t h e solution is previously heated. The supernatant liquid can t h e n be siphoned off a n d t h e sulfide washed with water, after which i t can be filtered, dried and roasted. When much iron is present in t h e liquors t h e sulfide should be washed with water containing hydrochloric acid t o remove t h e iron completely. T h e “yellow precipitate” is handled by dissolving in sufficient sodium hydroxide t o make a solution just slightly alkaline t o phenolphthalein. Should t h e precipitate be contaminated b y iron, t h e ferric hydroxide produced b y t h e addition of t h e alkali should be filtered off. T h e filtrate is t h e n diluted a n d hydrogen sulfide conducted through t h e solution t o saturation. Dilute hydrochloric acid is now added until a n excess is present, when molybdenum sulfide separates. The sulfide of molybdenum can be filtered, washed with hot water containing dilute hydrochloric acid, dried and roasted in t h e air t o molybdenum trioxide. CHEXICAL LABOR4TORY UXIVCRSITY O F ~ I S C O \ S I X . MADISOX

NOTE: ORGANIC CHEMICAL REAGENTS FOR SCIENTIFIC AND TECHNICAL LABORATORIES By ROGERADAMS Received June 7, 1917

During t h e last three summers it has been the custom at t h e University of Illinois t o manufacture on a semicommercial scale ( I - t o a-lb. lots) certain organic chemicals; which h a d hitherto not been produced in this country a n d which were necessary for t h e researches in organic chemistry. Each year t h e number manufactured has been increased till at present satisfactory products have been developed for over forty of t h e common organic chemicals used primarily in theoretical organic research, b u t t o some extent in technical laboratories. T h u s it has been possible t o supply t h e Illinois laboratories with many of t h e materials formerly imported from Germany.

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The majority of these substances are not purchasable in t h e open market at t h e present time, so i t was thought it might be a great aid t o other laboratories if t h e y had t h e benefit of t h e experiences a t Illinois a n d t h e opportunity of purchasing such chemicals as might be desired at a price slightly above cost. I n nearly every case t h e substances produced have been compared with Kahlbaum’s products and in every instance t h e products have been found as pure, or purer. Below is given a list of chemicals which have been manufactured, many of which are on hand a t t h e present time. I n continuing t h e manufacture of chemicals this summer, only those chemicals mentioned below, which are out of stock, will be made, unless there may be a n outside demand for others. Processes for at least t e n substances not included in t h e list will be studied also in t h e next few months. Acetamide Acetoacetic ester (ethyl) Acetonitrile

Benzoyl acetone Benzoyl chloride Benzoyl cyanide Benzyl alcohol Benzvl bromide ,Benzyl cyanide Bromoacetyl bromide Bromobenzene Bromonaphthalene (alpha) Dibromo ( 0 ) benzene Dichloracetic acid Dimethyl glyoxime Diphenylmethane

Ethyl benzoate Ethylene bromide Ethyl oxalate r.ivcocoii - ~~~~~~_ Hippuric acid Magnesium (especially prepared for use in the Grignard reagent) Malonic ester (ethyl) Malonic ester (methyl) Mesitylene Methyl oxalate Methylene iodide Nitrobenzoic acid (0) Nitromethane . Oxalyl chloride Phenyl acetic acid Phenyl acetic ester (ethyl) Phenyl alanine Trimethylene bromide Trimethylene chlorhydrin Trimethylene cyanide Trimethylene glycol

If there is a reasonable demand for any particular chemical, which has not been prepared here a n d which cannot be purchased from any commercial concern, t h e laboratories at Illinois will be glad t o undertake such manufacturing a t their expense a n d sell t h e product a t a price slightly above t h e cost calculated from t h e past results. The Division of Organic Chemistry a t t h e University of Illinois has organized itself for this work, t h e preparation being carried out for t h e most part by t h e junior members of t h e staff a n d other graduate students in organic chemistry. These men receive from 2 5 t o 3 j cents per hour for their services. I n this way i t has been possible t o retain many men who might earn much larger salaries outside, b u t who are willing t o s t a y for this particular kind of experience. A number of other laboratories have offered t o assist in this work, if necessary, so as t o aid scientific and technical investigation as much as possible. Prof. P. A. Bond, of Cedar Falls, Iowa. has kindly offered t o prepare sodium nitroprusside for t h e benefit of any who might need this substance. I n addition t o t h e above work, in conjunction with Prof. h l . T. Bogert, information concerning t h e organic chemical reagents purchasable in this country is being collected. Quotations of prices on any of t h e substances above, or any information which i t has been possible t o obtain in regard t o organic chemicals will gladly be given on request. UNIVERSITYOF I L L I N O I S URBANA,ILLINOIS

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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 AN EVAPORATING BATH OF SEA SAND HEATED BY STEAM B Y P. P. I'BTFIRSON

neceivedi-.bruary 24. 1417

The apparatus herewith described has been found so convenient and useful in the laboratories of t h e Department of Soils a t the University of Idaho t h a t i t is thought worth while t o tell other chemists about it. It is made of coils of pipe in a bath of sea sand. The heat is supplied by superheated steam, the flow of which is controlled hy a Sarco steam trap. The t r a y ( A , Fig. I) is made of No. 24 galvanized iron. Of course, it may be a n y size. Ours is z it. square and 4 in. deep. B is a coil of iron pipe well fitted so t h a t i t can carry a pressure of 100 t o 1 5 0 lbs. per s q . in. A t t h e end of this pipe is a Sarco steam trap, C, which allows t h e escape of steain until a certain temperature is reached when i t closes automatically. The coil B is covered with sifted sea sand of about t h e size t h a t will pass a 20-mesh sieve and washed free from small adhering particles. It is found t h a t by t h e use of this bath a much more rapid evaporation can be obtained t h a n with a hot water or steam bath. Aside from this t h e escape of large amounts of steam into t h e room and t h e noise often accompanying t h e same is avoided. T o obtain t h e best results t h e sand should cover t h e coils t o the to z in. so t h a t t h e evaporating dish or depth of I > / ~ casserole may be pressed down into it. When t h e hot sand is allowed t o come u p on t h e side of t h e evaporating dish t h e evaporation is greatly accelerated. A temperature of 140' C. can be obtained in t h e sand be-

bowever, i t has been found t h a t t o avoid this contamination requires no more care than is necessary with t h e old style boiling water bath or t h e s t e a m

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PZO. IILTBS mrir COW ET,(

bath. Thorough washing of t h e sand t o remove all small particles makes t h e avoidance of contamination rather easy. Fig. I1 is a cut of t h e completed bath. Son, P s a r i ~ i r vLABORAIOKY UNIYQXJiIY

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AN IMPROVED FORM OF A FUMELESS DIGESTION APPARATUS By

3. S . MCHIROUE

Received Pcbruary 23, 1917

In a recent, investigation involving a relatively large nurnlier of nitrogen determinations, it became necessary, on account of t h e lack of flue facilities, to make use of a Sy Fumeless Nitrogen Digestion Apparatus. During t h e time t h e nitrogen digestions were being made, a number of objectionable features t o this particular apparatus were experienced. The writer has, therefore, enlarged and modified t h e Sy apparatus in such a n advantageous manner as t o consider t h e changes so made worthy of brief notice in t h c chemical Iiteraturc. The chief ooints in which t h e aooaratus shown in t h e accompanying photograph differs from t h e Sy apparatus and the advantages gained therehy a r e a s follows: r--Increased capacity. Since most ready-made nitrogcn distillation apparatus provides for 6 distillations t o be carried on a t the same time, there is a saving ol time by having a n equal number of digestions provided for. *--The lead pipe a n d t h e absorption bottle is a more pcrmanent and satisfactory arrangement for controlling and disposing of t h e acid fumes during digcstion. Practically all t h e fumes are absorbed in t h e bottle mhich can be easily emptied and t h e acid recovered by evaporation, thereby effecting a saving of acid and t h e corrosive action on t h e drain pipes as well. The pump used in drawing t h e fumes into t h e absorption bottle is t h e ordinary type in general use in Iaboratorics. S-Thc shelf E holds 6 beakers which are placed beneath t h e lower end of tlie condensing bulbs, a n d catch tlic acid t h a t drains f r o m t h e condensing tubes after t h e digestion flasks are removed. After t h e digestion is stopped and t h e flasks become cool, a

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tw-em the pipes. Over t h e hot plaie, whether lieatcd by a gas flame or electricity, this bath has t h e advantage t h a t there is almost no danger at all of spattering. With t h e hot plate it is almost impossible to avoid this trouble. The objection t h a t contamination from t h e sand is likely to take place may be raised and, of course, is t o be taken into account. I n this laboratory,

Vol. 9, No. 7