Kinetics of Ultrahigh Temperature Water-Gas Shift Reaction Catalysts Using Simulated Coal-Derived Syngas

Abstract

H₂ is currently being widely recognized as a possible energy carrier because of its high energy content and environmental compatibility. H₂ production from coal gasification has gained renewed interest because it is recognized as the most abundant fossil fuel. The coal-derived syngas consists mainly of CO and H₂. The CO can be further reacted with steam via the water-gas shift reaction (WGSR) to increase the H₂ concentration in the syngas. Development of catalyst that can be used at temperature higher than the traditional WGSR operating temperatures is an alternative way to enhance the overall coal-to-H₂ thermal efficiency and cost-effective design. With this high temperature catalyst two-stage shift reactors can be reduced to a single reactor and connected at the gasifier exit without the need for syngas cooling. In this study, catalyst performance of WGSR operated in ultrahigh temperature region (750 - 850 °C) was examined experimentally. Using syngas with various compositions and S/C ratios as feedstock, the chemical reaction kinetics of WGSR using 2.5 wt%Pt - 2.5 wt%Ni/5 wt%CeO₂/Al₂O₃ as catalyst can be established based on the experimental data and simple power law. It was found that the prepared catalyst promotes the rate of WGSR when the syngas consists of higher CO concentration and lower CO₂ concentration for the operation temperature range studied.