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Membrane Gas Separation Principles

Published online by Cambridge University Press:  29 November 2013

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Some industrial processes require the separation of gas or vapor mixtures. Methods for separating the mixtures vary from separation by diffusion to separation by distillation. Many of the methods, such as distillation, are energy intensive. Membranes can reduce the energy required to produce a desired separation. Because of their corrosion resistance and high temperature applications, engineered inorganic membranes can significantly increase the efficiency of many of these processes. The magnitude of the separation factor, available operating conditions, enrichment, yield, and cost of the membranes play a large role in determining whether membranes can be more economical than other methods of separation. These factors have to be evaluated on a case-by-case basis.

Martin Marietta Energy Systems' Office of Technology Transfer conducted a preliminary market survey with the assistance of the University of Tennessee and commercial marketing experts in inorganic membranes. The survey assumed that membranes could be made with permeabilities a factor of 3 larger and with cost per unit area a factor of 3 smaller than is currently available. The results indicated that active implementation of such technology could expect to achieve the following results:

• $2 billion dollar per year sales market,

• $16.6 billion increase in the national GDP,

• $2 billion improvement in the balance of trade, and

• 6 quads per year decrease in energy use.

Type
Engineered Porous Materials
Copyright
Copyright © Materials Research Society 1994

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References

1.Palmer, J.R. and Kaczenski, M.E., Economic Benefits from Alternate Applications of DOE Inorganic Membrane Technology (Martin Marietta Energy Systems, Inc., internal document, November 1992).Google Scholar
2.Fain, D.E. and Brown, W.K., Neon Isotope Separation by Gaseous Diffusion Transport in the Transition Flow Regime with Regular Geometries (K-1863) (Union Carbide Corporation, Nuclear Division, Oak Ridge Gaseous Diffusion Plant, September 1974).CrossRefGoogle Scholar
3.Present, R.D., Kinetic Theory of Gases, (McGraw-Hill, New York, 1958).Google Scholar
4.Kennard, E.H., Kinetic Theory of Gases, (McGraw-Hill, New York, 1938) p. 294.Google Scholar
5.Fain, D.E., Rarified Gas Dynamics, 74 Pt. 1, (American Institute of Aeronautics and Astronautics, 1980, New York) p. 218.Google Scholar
6.Thomson, W., Philos. Mag. 4 (42) (1891) p. 448.Google Scholar