SCI和EI收录∣中国化工学会会刊

Chin.J.Chem.Eng. ›› 2014, Vol. 22 ›› Issue (5): 503-508.DOI: 10.1016/S1004-9541(14)60069-0

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Analysis of H2S Tolerance of Pd-Cu Alloy Hydrogen Separation Membranes

GAO Huiyuan, WANG Ling   

  1. College of Chemical Engineering, Hebei United University, Tangshan 063009, China
  • Received:2012-07-17 Revised:2012-10-05 Online:2014-05-06 Published:2014-05-28
  • Supported by:

    Supported by the National Natural Science Foundation of China (50972038), the National Natural Science Foundation of Hebei Province (B2009000739, B2014209258), Science and Technology Support Program of Hebei Province (09215142D).

Analysis of H2S Tolerance of Pd-Cu Alloy Hydrogen Separation Membranes

高会元, 王岭   

  1. College of Chemical Engineering, Hebei United University, Tangshan 063009, China
  • 通讯作者: GAO Huiyuan,E-mail: hygao@heuu.edu.cn
  • 基金资助:

    Supported by the National Natural Science Foundation of China (50972038), the National Natural Science Foundation of Hebei Province (B2009000739, B2014209258), Science and Technology Support Program of Hebei Province (09215142D).

Abstract: The presence of a limited amount of H2S in H2-rich feed adversely affects the Pd-Cu membrane permeation performance due to the sulphidization of the membrane surface. A theoretical model was proposed to predict the S-tolerant performance of the Pd-Cu membranes in presence of H2S under the industrial water-gas-shift (WGS) reaction conditions. The ideas of surface coverage and competitive adsorption thermodynamics of H2S and H2 on Pd-Cu surface were introduced in the model. The surface sulphidization of the Pd-Cu membranes mainly depended on the pressure ratio of H2S to H2, temperature and S-adsorbed surface coverage, i.e., the occurrence of sulphidization on the surface was not directly related with the bulk compositions and structures [body centered cubic and face centered cubic (bcc or fcc)] of Pd-Cu alloy membranes because of the surface segregation phenomena. The resulting equilibrium equations for the H2S adsorption/sulphidization reactions were solved to calculate the pressure ratio of H2S to H2 over a wide range of temperatures. A validation of the model was performed through a comparison between lots of literature data and the model calculations over a rather broad range of operating conditions. An extremely good agreement was obtained in the different cases, and thus, the model can serve to guide the development of S-resistant Pd alloy membrane materials for hydrogen separation.

Key words: surface coverage, Pd-Cu alloy membranes, H2S tolerance, theoretical model, hydrogen separation

摘要: The presence of a limited amount of H2S in H2-rich feed adversely affects the Pd-Cu membrane permeation performance due to the sulphidization of the membrane surface. A theoretical model was proposed to predict the S-tolerant performance of the Pd-Cu membranes in presence of H2S under the industrial water-gas-shift (WGS) reaction conditions. The ideas of surface coverage and competitive adsorption thermodynamics of H2S and H2 on Pd-Cu surface were introduced in the model. The surface sulphidization of the Pd-Cu membranes mainly depended on the pressure ratio of H2S to H2, temperature and S-adsorbed surface coverage, i.e., the occurrence of sulphidization on the surface was not directly related with the bulk compositions and structures [body centered cubic and face centered cubic (bcc or fcc)] of Pd-Cu alloy membranes because of the surface segregation phenomena. The resulting equilibrium equations for the H2S adsorption/sulphidization reactions were solved to calculate the pressure ratio of H2S to H2 over a wide range of temperatures. A validation of the model was performed through a comparison between lots of literature data and the model calculations over a rather broad range of operating conditions. An extremely good agreement was obtained in the different cases, and thus, the model can serve to guide the development of S-resistant Pd alloy membrane materials for hydrogen separation.

关键词: surface coverage, Pd-Cu alloy membranes, H2S tolerance, theoretical model, hydrogen separation