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Kinetics of high-temperature water-gas shift reaction over two iron-based commercial catalysts using simulated coal-derived syngases

journal contribution
posted on 2020-04-15, 00:00 authored by SS Hla, D Park, GJ Duffy, JH Edwards, DG Roberts, A Ilyushechkin, LD Morpeth, T Nguyen
The kinetics of the water-gas shift (WGS) reaction over two iron-chromium based commercial catalysts has been studied. The experiments were performed in a differential reactor at a constant temperature of 450 °C and a space velocity of 1.9 m3 gcat-1 h-1 at approximately atmospheric pressure. The effects of CO, CO2, H2O and H2 concentration on WGS reaction rate were determined over both catalysts using selected gas compositions that might be encountered in coal based gasification system of the dry-feed and slurry-feed types and at the backend of conventional fixed-bed and catalytic membrane reactors. It was found that the rates of the WGS reaction (in mol gcat-1 s-1) over two commercial catalysts (referred to as HTC1 and HTC2) at a reaction temperature of 450 °C can be expressed by the following power-law rate models:. For HTC1R = 102.845 ± 0.03 exp fenced(frac(- 111 ± 2.63, R′ T)) PCO1.0 ± 0.031 PC O2- 0.36 ± 0.043 PH2- 0.09 ± 0.007 fenced(1 - frac(1, K) frac(PC O2 PH2, PCO PH2 O)). For HTC2R = 100.659 ± 0.0125 exp fenced(frac(- 88 ± 2.18, R′ T)) PCO0.9 ± 0.041 PH2 O0.31 ± 0.056 PC O2- 0.156 ± 0.078 PH2- 0.05 ± 0.006 fenced(1 - frac(1, K) frac(PC O2 PH2, PCO PH2 O)) . It was observed that HTC1 promotes the rate of WGS reaction when the inlet gas consists of higher CO concentration, and lower CO2 and H2 concentration. Due to the less-negative reaction order with respect to CO2, HTC2 was found to be more applicable to the gas streams with higher CO2 levels, which are likely to be found on the retentate side at the backend of a catalytic membrane reactor. Crown Copyright © 2008.

Funding

Category 3 - Industry and Other Research Income

History

Volume

146

Issue

1

Start Page

148

End Page

154

Number of Pages

7

eISSN

1873-3212

ISSN

1385-8947

Publisher

Elsevier, Netherlands

Peer Reviewed

  • Yes

Open Access

  • No

Acceptance Date

2008-09-17

External Author Affiliations

CSIRO

Era Eligible

  • Yes

Journal

Chemical Engineering Journal

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