Title: Chemical Engineering Research and DesignImported from Authenticus Search for Journal Publications

Vol. 82 No. A2

Pages: 192-202

ISSN: 0263-8762

Publisher: Institute of Chemical Engineers

ISI Web of Knowledge - 16 Citations

Scopus - 18 Citations

Authenticus ID: P-000-BPA

DOI: 10.1205/026387604772992765

Abstract (EN): The subsection-controlling strategy was applied to the design of the adsorptive reactor to improve the sorption-enhanced steam-methane reforming (SMR), by using subsection-packing ratio of adsorbent and catalyst, and sub section-controlling wall temperature. In the case of the subsection-controlling wall temperature, there is a lower operating temperature zone at the outlet of the adsorptive reactor, where the remaining CO and CO2 concentrations in gas stream can be decreased further by the principle of temperature-induced equilibrium shift. The feasibility and effectiveness of the subsection-controlling strategy for improving the sorption-enhanced steam-methane reforming process is analysed by numerical simulation based on literature data. At low operating pressure, in the range 222-445.7 kPa, combined with subsection-controlling strategy [higher temperature, 450-490degreesC, for subsections I (inlet zone of the adsorptive reactor) and II (middle zone of the adsorptive reactor) and lower temperature, 400-450degreesC, for subsection III (outlet zone of the adsorptive reactor); lower packing ratio of adsorbent and catalyst for subsections I and III and higher ratio for subsection II] a product gas with hydrogen purity above 85% and traces of CO2 (less than 300 ppm) and CO (less than 30 ppm) can be continuously produced with higher hydrogen productivity by a four-step one-bed (a 6 m long adsorptive reactor) pressure swing sorption-enhanced steam-methane reforming cyclic process, and may be directly used in fuel cell applications.

Language: English

Type (Professor's evaluation): Scientific

No. of pages: 11