Ethanol is considered to be a promising candidate for hydrogen source. Hydrogen-rich gas with less impurity level of carbon monoxide and carbon dioxide is required for fuel cell applications. In a conventional ethanol processor, CO can be removed by water gas-shift reactors, followed by a preferential oxidation unit. Since a high content of CO 2 may degrade the efficiency of fuel cell systems, the removal of CO 2 should be included in the ethanol processor to separate CO 2 from the synthesis gas. In this study, the thermodynamic analysis of hydrogen production from the integration of ethanol reforming process and CO 2 absorption unit is performed. The purity of H 2 , efficiency of CO 2 removal and heat consumption are key factors to be analyzed with regard to different key parameters. The result indicates that the H 2 purity of 97 mol.% can be reached when the CO 2 absorption unit is included in the ethanol steam reforming. In addition, it is found that the CO 2 removal can be improved with increases of amine concentration, number of absorber and stripper stages, whereas increase of inlet gas temperature show the opposite trend. However, high energy demand is unavoidable when a number of absorber and stripper stages increase.