Thermodynamic analysis of sorption‐enhanced water–gas shift reaction using syngases

Sorption‐enhanced water–gas shift (SEWGS) reaction performance using syngas as the feedstock is investigated in this study based on thermodynamic equilibrium analysis. It was found that the capability of CO₂ sorbent in CO₂ removal was independent of the dry syngas composition. Regardless of the dry gas composition, CO₂ sorbent loses its adsorption capability as the reaction temperature increases higher than a temperature limit. This CO₂ adsorption temperature limit was found to depend on the steam to carbon (SC) ratio and reaction pressure. With the decrease in SC and increase in pressure the CO₂ adsorption temperature limit can be raised to a higher value. However, the initial CO₂ content in the syngas composition affects the carbon and CH₄ formations in SEWGS. For syngas with low CO₂ concentration, carbon formation can be completely eliminated and CH₄ formation can be reduced by CO₂ removal. For syngas with high CO₂ concentration, no carbon and CH₄ suppression can be found. It was also found that the temperature at which no carbon and CH₄ formations was increased to a higher value as the initial CO₂ concentration was increased. Copyright © 2016 John Wiley & Sons, Ltd.