Low temperature hydrogen transport using a palladium/copper membrane

Results are presented from low temperature hydrogen permeation experiments using a palladium/copper membrane. Inlet pressure was varied from 5 psig to 180 psig, while temperature was varied from 25°C to 275°C. The palladium/copper membranes exhibited flow stability problems at low temperatures and p...

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Bibliographic Details
Published in:Journal of materials science 2003-06, Vol.38 (11), p.2401-2408
Main Authors: LESSING, P. A, WOOD, H. C, ZUCK, L. D
Format: Article
Language:English
Subjects:
Applied sciences
ARGON
ATOMS
Copper
DISSOLUTION
Exact sciences and technology
Flow stability
GENERAL AND MISCELLANEOUS//MATHEMATICS, COMPUTING, AND INFORMATION SCIENCE
HELIUM
HYDROGEN
Hydrogen atoms
Hydrogen permeation
Inlet pressure
Low temperature
Materials science
membrane
MEMBRANES
Metals. Metallurgy
Palladium
palladium/copper
Penetration
Phase transitions
Preconditioning
Rare gases
STABILITY
TRANSPORT
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Summary:Results are presented from low temperature hydrogen permeation experiments using a palladium/copper membrane. Inlet pressure was varied from 5 psig to 180 psig, while temperature was varied from 25°C to 275°C. The palladium/copper membranes exhibited flow stability problems at low temperatures and pressures when using ultra high purity hydrogen. A preconditioning step of high temperatures and inlet pressures of pure hydrogen was necessary to stimulate any substantial permeate flows. After pre-conditioning, results showed zero hydrogen flow when using 3–4% hydrogen mixed with helium or argon. It is thought that the inert gas atoms were adsorbed into the membrane surface and thus blocked the hydrogen atom dissolution. When using pure hydrogen at low to moderate temperatures and low pressures, no measurable permeate flow was observed. Also, zero permeate flow was observed at relatively high temperatures (e.g., 150°C) and a low inlet pressure (5 psig). The cause of the zero permeate flow, when using pure hydrogen, was attributed to interface control of the permeation process. Interface control could be due to: (a) insufficient energy to split the hydrogen molecule into hydrogen atoms, or (b) a reversible phase change from beta to alpha of crystals at the near surface.
ISSN:0022-2461
1573-4803
DOI:10.1023/A:1023996800277