| Issue |
Korean Journal of Chemical Engineering,
Vol.21, No.4, 782-792, 2004
Vol.21, No.4, 782-792, 2004
A Hybrid Adsorbent-Membrane Reactor (HAMR) System for Hydrogen Production
Design characteristics and performance of a novel reactor system, termed a hybrid adsorbent-membrane reactor (HAMR), have been investigated for hydrogen production. The recently proposed HAMR concept couples reactions and membrane separation steps with adsorption on the membrane feed-side or permeate-side. Performance of conventional reactors has been significantly improved by this integrated system. In this paper, an HAMR system has been studied involving a hybrid-type packed-bed catalytic membrane reactor undergoing methane steam reforming through a porous ceramic membrane with a CO2 adsorption system. This HAMR system is of potential interest to pure hydrogen production for fuel cells for various mobile and stationary applications. Reactor behaviors have been investigated for a range of temperature and pressure conditions. The HAMR system shows enhanced methane conversion, hydrogen yield, and product purity, and provides good promise for reducing the hostile operating conditions of conventional reformers, and for meeting the product purity requirements.
Keywords:
Membrane; Membrane Reactor; Methane-Steam Reforming; Hydrogen Production; Equilibrium-Shift
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[Cited By]
- Jang HT, Cha WS, Korean Journal of Chemical Engineering, 24(2), 374, 2007
- Seo JG, Youn MH, Cho KM, Park S, Lee SH, Lee J, Song IK, Korean Journal of Chemical Engineering, 25(1), 41, 2008
- Seo JG, Youn MH, Park S, Lee J, Lee SH, Lee H, Song IK, Korean Journal of Chemical Engineering, 25(1), 95, 2008
- Hwang JW, Yoon DY, Choi KH, Kim Y, Kim LH, Korean Journal of Chemical Engineering, 25(2), 217, 2008
- Jeong H, Kim TH, Choo KY, Song IK, Korean Journal of Chemical Engineering, 25(2), 268, 2008
- Lee JH, Lee DG, Park JI, Kim JY, Korean Journal of Chemical Engineering, 27(1), 187, 2010
- Seo JG, Youn MH, Chung JS, Song IK, Journal of Industrial and Engineering Chemistry, 16(5), 795, 2010
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