Sintered Pyrex Glass Aeration Tubes Gas-Absorption Bulb for Use

ing fritted glass filters. --. 1 Present address, University of Akron, Akron, Ohio. REICEIVBID. July 20, 1934. Gas-Absorption Bulb for Use with Small ...
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Sintered Pyrex Glass Aeration Tubes R.D. COOL^ AND J. D. GRAHAM,Laboratory of

Pharmacology, University of Pennsylvania, Philadelphia, Pa.

H E applications of sin- packed by tapping the mold. The mold and glass were placed an electric muffle furnace maintained at white heat (l20Ooto tered Jena glass d i s k s in 1400' C.) for 30 to 40 seconds, until a distinct red color had have become w e l l k n o w n crept completely over the outside of the mold cup, C. The through their wide use in fil- mold was then removed from the furnace and the inner carbon tration and in gas a b s o r p - plug, P, withdrawn. By this initial heating the glass had sintered just enough so that the plug could be removed without tion apparatus (3). Recogni- destroying the form of the glass thimble. If the sintering was tion of the desirability of con- completed without removing the inner plug, so much shrinking structing similar devices from of the glass took place that it was practically impossible to Pyrex brand glass has re- remove it. As soon as plug P had been removed, the outer cup, C, of the mold and the powdered glass, G, were replaced in the sulted in several articles (1, furnace until the color of the mold just approached that of the 2) dealing with this subject. oven. This usually required an additional 30 seconds. The I n some cases shapes other mold and sintered glass thimble were then removed from the thanthewell-knowndisk seem furnace. On cooling, enou h shrinkage of the glass had occurred so that it readily dropped from the inverted mold. desirable. F o r d i s p e r s i n g gases into fine bubbles in Because the mold, glass, and oven undergo unequal cooling liquids, for ready saturation effects during various parts of the procedure, more uniform of the liquids, or for rapid and results could be obtained by using the appearance of the mold FIGURE 3.. SECTION THROUGH quantitative a b s o r p t i o n of and of the glass rather than a definite period of heating as MOLDFOR SINTERING Pow- constituents of the gases, the the criterion for completion of the sintering. The whole DERED GLASS thimble-shaped alundum gas sintering process, including packing of the mold and removal C Cup bored from 15-mm. graphabsorption s p r e a d e r s h a v e of the finished thimble, requires about 5 minutes, and by using ite god; G, powdered Pyrex glass; P,plug made from 6-mm. arc lamp proved very effective when several molds, so that no waiting is required for cooling, a oarbon. atmlicable. I n the course of number of thimbles can be made in a reasonably short time. If the thimble is wrapped to within 3 mm. of the open end work in this laboratory it becaze desirable to devise an apparatus for the quantitative absorption in strong alkali of with asbestos paper tape, it can be sealed to Pyrex glass a vapor mixed with steam, and the authors succeeded in pre- tubing in the usual manner. paring a highly satisfactory gas disperser from Pyrex brand LITHRATURE CITED glass which, under such conditions, seemed to offer marked (1) Bruce, W. F., and Bent, H. E., J. Am. Chem. Soc., 53, 990 (1931). advantages over one made from alundum. (2) Kirk, P. L., Craig, R., and Rosenfels, R. S., IND.ENG.CHBM., Pyrex glass tubing was crushed in a porcelain mortar and Anal. Ed., 6, 154 (1934). separated into portions by screening. Powdered glass of the (3) Prausnitz, P. H., Ibid., 4, 430 (1932); Bee bibliography of thia paper and Ibid., 6, 291 (1934) for references to patents coverdesired size (80 to 100 mesh was used in the particular case mentioned) was placed in a mold of graphite (Figure 1) and ing fritted glass filters.

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REICEIVBID July 20, 1934.

Present address, University of Akron, Akron, Ohio.

Gas-Absorption Bulb for Use with Small Amounts of Reagent

TOP MAY SE OPEN AN FLARED TOR WBBF STOPPER OR G W h U WAS STOPPER

J. A. SHAW The Koppers Research Corporation, Pittsburgh, Pa.

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ECENTLY the writer had occasion to make a quantitative study of the oxidation of minute amounts of nitric oxide in coke-oven gas and gum formation resulting therefrom. The investigation included a critical examination of the analytical method described by Schuftan.1 Testing such a method naturally involved making synthetic samples by adding small amounts of nitric oxide (< 1 p. p. m.) to cokeoven gas free from nitric oxide. As in all ultrasensitive work, it was desirable to use as little reagent as possible. It was also necessary to keep backpressure in the system to a minimum, and to accomplish this under conditions requiring unusually thorough scrubbing combined with considerable capacity. Since no absorber on the market would fulfil all these demands, a special bulb (shown in the illustration) was designed. (The glass-blowing required in developing this absorber was done by F. PierceNoble, 110 Benham Ave., New Haven, Conn.) 1

Sohuftan, Paul, Brennslof-Chem., 13, 104-8 (1932).

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200

TIP O 5 Y M BORE

480

ANALYTICAL EDITION

The scrubbing is done by the bead column wetted with the scrubbing solution which is umped over the beads in closed cycle. By the arrangement oAhe tubing in the apparatus the as sample is caused to do the pumping. The gas enters througi a 6-mm. tube bent in the form of a trap, in which there is a carefully made orifice (0.5 mm. in diameter) situated below the liquid level. Through this orifice the scrubbing solution seeps into the trap, is quickly driven to the top where it is sprayed upon the bead column, and slowly finds its way down to the reservoir whence it came. The bulb may be sealed at the top or closed by a stopper of glass, rubber, etc. For gravimetric work, glass wool may be used instead of beads. The bulb can most readily be washed with a solution from a gravity reservoir fitted with a rubber tube and pinchclamp. After the solution has been let in, and before disconnecting, the tube is pinched between the bulb and the clamp to collapse it. This will prevent an annoying drip from the tube upon disconnecting. The bulb could doubtless be used for extremely low rates of gas flow by reducing the internal diameter of the 6-mm. inlet tube. For any given assembly, the height of the scrubbing solution above the orifice modifies within narrow limits the rate of pumping the solution. In most cases the rate should be such as to spray the solution over the beads, since flowing results in flooding which in turn causes loss of effective surface and efficiency.

Vol. 6 , No. 6

Gas passed through this bulb at a rate of 1.0 to 1.5 cubic feet per hour (approximately 30 to 45 liters per hour) develops a back-pressure equivalent to less than 0.5 inch (13 mm.) of water. It can be designed to use less than 5 ml. of scrubbing solution. The scrubbing efficiency and capacity have proved t o be entirely satisfactory. In two tests made upon the absorption efficiency of these bulbs, the rate of gas flow was between 1and 2 cubic feet per hour. In one case a bulb charged with 20 per cent sulfuric acid was subjected to a gas flow carrying a fairly high concentration of ammonia (similar to raw coke-oven gas). On the outlet of the bulb a trap was placed containing 0.1 ml. of 0.1 N sulfuric acid, in a little water colored with methyl orange. After 0.5 hour when the test was stopped, the solution in the tra had not changed color. Upon titrating the solution in the fulb it was found that the acid had become so nearly spent that only 0.2 ml. of 1 N sodium hydroxide was required to neutralize it. The second test was a series of determinations of nitrogen tetroxide in gas. Nitric oxide was added in fractional parts per million to the gas which was then treated as in the Schuftan procedure. Two bulbs charged with m-phenylene diamine solution were placed in the outlet in series arrangement. More than 95 per cent of the nitric oxide was accounted for in the fist scrubber. RE~CE~IVBID August 18, 1934.

A Salt Bridge for Use in Electrometric Measurements GEORGEW. IRVING,JR., AND N. R. SMITH,Bureau of Chemistry and Soils, Washington, D. C.

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N MAKING a large number of routine p H determinations

on soils and other materials by means of the quinhydrone electrode, the faults of the commonly used agar bridge became so troublesome that the authors searched for a more suitable bridge. The bridge finally adopted has proved very satisfactory for their work and is offered with the hope that it may prove useful to others who employ electrometric methods. The bridge shown in the figure is a modification of that described by LaMer and Raker (4, 6),and is based upon ideas presented by Crowther (I), Cu r (2), Kohn (S), a n i S c h o l l e n b e r g e r (6). It is made of heavy-walled Pyrex glass tubing of about 1cm. diameter. The lugs are of Pyrex &ass rod and are ground into the tap e r e d e n d s of t h e bridge. The bulb is about 4 cm. in diameter and has a capacity of about 25 cc. For use the bridge is tilled to the groundg l a s s stopper w i t h saturated potassium chloride solution; the plugs are loosened momentarily t o insure a film of potas9 cm.sium chloride in the 1 ground-glass j o i n t s, and then are seated firmly. The tips are washed thoroughly with distilled water and dried with filt,er paper to avoid dilution of the reference half-cell. Between determinations the washing and drying of the tips are re eated but it is not necessary to renew the potassium chloride in t6e ground-glass joints.

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LaMer and Baker (4)have presented proof that the groundglass form of junction gives a strictly reproducible potential and effectively prevents interdiffusion of saturated potassium chloride and quinone substances. The authors have compared the ground-glass with the agar bridge and have found them t o give identical results in buffer solutions, soils, and culture media. The new type of bridge has been used successfully and conveniently in several thousand pH determinations. Several advantages are apparent in this form of bridge: Preparation of the bridge for the day’s work involves only filling with saturated potassium chloride solution; one filling of the bridge is sufficient for a n unlimited number of determinations; between samples the bridge is easily and thoroughly cleaned by a stream of distilled water from a wash bottle and easily dried with a small piece of filter paper; and no special arrangements are necessary for keeping the bridge when i t is not in use, the potassium chloride being simply removed and the bridge filled with distilled water. The only caution to be observed in the use of this bridge is to avoid allowing the tips to d r y out, else they may stick. If this happens, the joints may be loosened by soaking in warm water and by tapping gently on a solid surface. After loosening, they should always be well seated before proceeding; once seated, they are not easily loosened even if struck accidently against any part of the apparatus. While a determination is being made, the weight of the bridge is supported at the shoulders so that the tips are held several millimeters from t h e bottom of t h e vessel. In this position, the contents of the electrode vessel may be stirred without dislodging the plugs.

LITERATURE CITED (1) (2) (3) (4) (5) (6)

Crowther, J . Znst. Brewing, 33, 459-63 (1927). Cupr, Pub. facult4 sci. univ. Masaryk, No. 133, 1-50 (1931). Kohn, 2.angew. chem., 39, 1073-4 (1926). LaMer and Baker, J . A m . Chem. Soc., 44, 1954-64 (1922). LaMer and Parsons, 1.B i d . Chem., 57, 613-31 (1923). Schollenberger, IND.ENG.CHEM.,17, 649 (1925).

RE~CE~IVH~D July 27, 1934.