Gas Diffusion in Bi-disperse Porous Catalyst Pellets

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Gas Diffusion in Bi-disperse Porous Catalyst Pellets

LIU Xiufeng^a; ZHANG Baoquan^a; LIN Y.S.^a,b

^aSchool of Chemical Engineering and Technology, Tianjin University, Tianjin 30007＂2, China
^b Department of Chemical and Materials Engineering, Arizona State University, Tempe AZ 85287, USA

Received:1900-01-01 Revised:1900-01-01 Online:2005-08-28 Published:2005-08-28
Contact: 刘秀凤

双分散多孔催化剂颗粒中的气体扩散

刘秀凤^a; 张宝泉^a; LIN Y.S.^a,b

^a School of Chemical Engineering and Technology, Tianjin University, Tianjin 30007＂2, China
^b Department of Chemical and Materials Engineering, Arizona State University, Tempe AZ 85287, USA

通讯作者: LIU Xiufeng

Abstract

Abstract: A flux equation of diffusion for bi-disperse porous catalyst pellets was proposed by modifying the previously developed model equation over fractal trajectories. The proposed fractal model equation considered the same tortuous degree for both micro- and macro-pores. The experimental data of diffusion over a bi-disperse Ni/gamma-alumina pellet were obtained with a standard Wicke-Kallenbach diffusion cell for both carbon monoxideethylene and carbon dioxide-ethylene binary mixtures. The fitting between experimental results and the fractal model equation leads to a fractal dimension of 1.11. The prediction of diffusion flux over the bi-disperse Ni/gammaalumina pellet by the proposed fractal model equation is much better than the traditional tortuosity-based model equation by comparison with the measured flux through the pellet.

Key words: fractal, diffusion, porous media, catalyst

摘要： A flux equation of diffusion for bi-disperse porous catalyst pellets was proposed by modifying the previously developed model equation over fractal trajectories. The proposed fractal model equation considered the same tortuous degree for both micro- and macro-pores. The experimental data of diffusion over a bi-disperse Ni/gamma-alumina pellet were obtained with a standard Wicke-Kallenbach diffusion cell for both carbon monoxideethylene and carbon dioxide-ethylene binary mixtures. The fitting between experimental results and the fractal model equation leads to a fractal dimension of 1.11. The prediction of diffusion flux over the bi-disperse Ni/gammaalumina pellet by the proposed fractal model equation is much better than the traditional tortuosity-based model equation by comparison with the measured flux through the pellet.

关键词: 双分散多孔催化剂;气体扩散;孔隙率;有效扩散;孔结构

LIUXiufeng, ZHANGBaoquan, LINY.S.. Gas Diffusion in Bi-disperse Porous Catalyst Pellets [J]. .

刘秀凤, 张宝泉, LINY.S.. 双分散多孔催化剂颗粒中的气体扩散[J]. CIESC Journal.

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