Palladium-related metallic membranes for hydrogen separation and purification: A review

被引：0

作者：

Jiang, Peng ^{[1
]}

Feng, Zequn ^{[1
]}

Wang, Xianlong ^{[1
]}

机构：

[1] Changzhou Univ, Sch Mech Engn & Rail Transit, Changzhou 213164, Peoples R China

来源：

FUEL | 2025年 / 386卷

基金：

中国国家自然科学基金;

关键词：

Metallic membrane; Palladium alloy; Hydrogen separation and purification; Porous support composite membrane; Non-Pd-based membrane; WATER-GAS SHIFT; ALLOY COMPOSITE MEMBRANES; POROUS STAINLESS-STEEL; HIGH-PURITY HYDROGEN; PD-CU MEMBRANES; THIN PD; AG ALLOY; PERMEATION CHARACTERISTICS; NI ALLOY; AMORPHOUS ALLOY;

D O I：

10.1016/j.fuel.2024.134192

中图分类号：

TE [石油、天然气工业]; TK [能源与动力工程];

学科分类号：

0807 ; 0820 ;

摘要：

Hydrogen is regarded as an excellent carrier for sustainable energy due to its high efficiency, environmental friendliness, and abundance, which can promote sustainable social and economic development. Membrane technology for hydrogen purification can effectively separate high-purity H2 from mixed gases produced through processes such as water gas shift conversion or natural gas reforming, for use in the fuel cell, petrochemical, metallurgical, and semiconductor industries. If membrane technology for hydrogen purification can be applied on a large scale, it can make the hydrogen transported through natural gas pipelines useful. Metallic membranes are particularly promising in these applications due to their excellent selectivity. Metal Palladium (Pd), with its extremely high hydrogen selectivity, thermal stability, and catalytic performance, has always been a research hotspot for membrane materials used in hydrogen separation and purification processes. This review summarizes the research progress of Pd related metallic membranes for hydrogen separation from three aspects: unsupported Pd alloy membranes, Pd-coated composite membranes with porous supports, and Pd- coated non-Pd-based alloy membranes. Finally, it briefly outlines the development trend of Pd-related metallic membranes in the field of hydrogen separation and purification.

引用

页数：13

共 183 条

[51] Paglieri S.N., Way J.D., Innovations in palladium membrane research, Sep Purif Methods, 31, 1, pp. 1-169, (2002)
[52] Peters T.A., Stange M., Klette H., Et al., High pressure performance of thin Pd-23% Ag/stainless steel composite membranes in water gas shift gas mixtures
[53] influence of dilution, mass transfer and surface effects on the hydrogen flux, J Membr Sci, 316, 1-2, pp. 119-127, (2008)
[54] Mejdell A.L., Jondahl M., Peters T.A., Et al., Effects of CO and CO2 on hydrogen permeation through a ∼3 μm Pd/Ag 23 wt.% membrane employed in a microchannel membrane configuration, Sep Purif Technol, 68, 2, pp. 178-184, (2009)
[55] Nguyen T.H., Mori S., Suzuki M., Hydrogen permeance and the effect of H2O and CO on the permeability of Pd0.75Ag0.25 membranes under gas-driven permeation and plasma-driven permeation, Chem Eng J, 155, 1-2, pp. 55-61, (2009)
[56] Catalano J., Baschetti M.G., Sarti G.C., Hydrogen permeation in palladium-based membranes in the presence of carbon monoxide, J Membr Sci, 362, 1-2, pp. 221-233, (2010)
[57] Unemoto A., Kaimai A., Sato K., Et al., Surface reaction of hydrogen on a palladium alloy membrane under co-existence of H2O, CO, CO2 or CH4, Int J Hydrogen Energy, 32, 16, pp. 4023-4029, (2007)
[58] Unemoto A., Kaimai A., Sato K., Et al., The effect of co-existing gases from the process of steam reforming reaction on hydrogen permeability of palladium alloy membrane at high temperatures, Int J Hydrogen Energy, 32, 14, pp. 2881-2887, (2007)
[59] Gallucci F., Chiaravalloti F., Tosti S., Et al., The effect of mixture gas on hydrogen permeation through a palladium membrane: experimental study and theoretical approach, Int J Hydrogen Energy, 32, 12, pp. 1837-1845, (2007)
[60] Mundschau M.V., Xie X., Evenson C.R., Et al., Dense inorganic membranes for production of hydrogen from methane and coal with carbon dioxide sequestration, Catal Today, 118, 1-2, pp. 12-23, (2006)

← 1 2 3 4 5 6 7 8 9 10 →