Mercury Slug Flowmeter - American Chemical Society

(1) Ampt, G. A., Australian Chem. Inst. J. Proc., 2, 10 (1935). (2) Brewster and Rieman, Ind. Eng. Chem., Anal. Ed., 14, 820. (1942). (3) Gibson, D. T...
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ANALYTICAL CHEMISTRY

86 The method was used for two years on several hundred compounds. Table I gives typical results on subtances of known purity. LlTERATURE CITED

(1) Ampt, G. A , , Australian Chem. Inst. J . Proc., 2, 10 (1935). (2) Brewster and Rieman, IND.ENG.CHEM.,.ISAL. ED., 14, 820 (1942). --, (3) Gibson, D. T., and Caulfield, T. H . , Anal& 60,522 (1935). (4) Hallett, L. T., and Kuipers, J. W., IXD.ENG.CHEM.,A X I L . ED., 12,360 (1940). (5) Ingrani, G., Analyst, 69,265 (1944). \

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Mercury Slug Flowmeter K. L. YUDOWITCB Gniversity of Missouri, Columbia, .llo.

C I D E X T A L t o other researches for the l I a n h a t t a n Pioject, I Sthe author developed \vith J. F. Bacon and othei associates a

(6) Manov, G. G., and Kirk, P. L., ISD. ENG.CHEM.,ASAL. ED.,9,

198 (1937).

( 7 ) Niederl, J. B., and Niederl, V., “Organic Quantitative Microanalysis,” 2nd ed., pp. 190-6, New York, John Wiley & Sons,

1942. ( 8 ) Ogg, C. L., Willits, C. O., and Cooper, F. J., A s a L CHEM.,20.,

83 (1948). (9) Sundberg, 0. E., and Royer, G. L., IKD.ENG.CHEM.,ASAL. ED.,18, 719 (1946). RECEIVEDJune 9, 1947. Presented before the Division of Analytical and Micro Chemistry a t the 111th Meeting of the AMERICASCHLYICAL SOCIETY, Atlantic City, N. J.

of a relay activated by the paasiage of the slug past the contacts shown in the illustration. This type of meter operates over a broad pressure range (2 t o 76 em. of mercury) and on a low pressure drop (2 t o 3 mm. of mercury). Its operation is independent of the physical properties of the gas being measured. It gives a n integrated or average flow rate rather than a n instantaneous rate. The advantages of this specific design are compactness, ruggedness, and higher flow rate attainable. More than a dozen of these meters have been used satisfactorily at SA11 Laboratories. They have held their calibrations t o ri-ithin from 1 t o lo%, over several months of regular use. AIost variations were probably due t o contamination of the mercury.

meter t o measure small gas f l o w a t various pressures. The iequirements of a n operating pressure drop of less than 3 mm of mercury and independence from t h e physical properties of the gas made capillary flowmeters, rotameters, and circuit-terminating flowmeters undesirable. Various designs of absolute displacement meters were investigated. Marsh’s ( 2 ) original design based on the displacement of a LITERATURE CITED bubble of amyl phthalate between scratches on a straight capillary (1) Appleby, IT. G., and Aver>-,W.H., IND.ESG. CHEY.,A s a ~ ED., . tube appeared unsatisfactory for several reasons. The range 15, 349 (1943). quoted was 0.25 t o 1 cc. per minute, much below requirements. (2) Marsh, ALE . L.. Trans. Faraday Soc., 36, 626 (1940). T h e accuracy of a straight tube meter varies as the distance beRECEIVED June 11, 1947. Based on v o r k performed under contract No. t w x n scratches, requiring a tube several feet long for reasonable. K-7405-eng-26 for the Manhattan Project. T h e information will appear in accuracy. Division VI11 of the Manhattan Project Technical Series a s p a r t of the Appleby and Avery ( 1 ) substituted mercury for amyl phthalate, contribution of the S;iM Laboratorieu, Carbide and Carbon Chemicals permitting the use of larger tubing and consequently higher flow Corp , New York, N. Y. rates. The range (up t o 25 cc. per minute) was still low and the delicacy of design incompatible with the need for portability a n d ruggedness. I n operation the mercury slug continuously ,--BYPASS traverses the spiral path as indicated. The spiral is made by winding 6-mm. Pyrex tubing in a plane, and allowing it t o set on a slightly convex carbon block. This fixes t h e spiral outlet 1 t o 2 mm. above the inlet. Sufficient mercury must be used in the meter, so t h a t a new slug will close the spiral entrance before the original slug completely leaves the spiral. The length of t h e slug and therefore t h e volume swept out per cycle were found t o vary somewhat with flow rate. This necessitates calibration over the range of flow rates t o be encountered. Below rates of about 25 cc. per minute, the volume swept out increases anomalously. I t is suggested t h a t the spiral be made of smaller tubing if it is desired t o measure rates below 25 cc. per minute. With the simple precautions of cleanliness and careful l e v e h g , rates of over 250 cc. per minute Tvere attained before the slug broke into several sections. It is not feasible t o use tubing much MERCURY SLUGlarger t h a n 6 mm., as the mercury will not then MERCURY WELLI ’ form a slug. The cycles may be counted by means

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