Application of zirconium modified Cu-based oxygen carrier in chemical looping reforming

Abstract

The modification of alumina support of copper-based oxygen carrier using zirconium oxide is investigated in this study. The CO2 modified chemical looping reforming (CO2-CLR) process is applied to evaluate the synthesized oxygen carriers at different reduction temperatures (550–750°C). The presence of ZrO2 in the support structure of oxygen carrier inhibited the deposition of coke on the samples. The results revealed that the addition of 20% zirconium oxide could effectively improve the efficiency of oxygen carrier at different reduction temperatures. In addition, the effect of CH4/CO2 ratio in feed (0.5–3) and copper loading percentage (10, 15, 20, 25, 30) are investigated on methane and carbon dioxide conversion, hydrogen production yield and CO/CO2 ratio. The synthesized oxygen carriers were characterized by X-ray powder diffraction (XRD), field emission scanning electron microscopy (FESEM), BET and energy dispersive X-ray spectroscopy (EDX) techniques. The 15Cu/20Zr-Al as optimized oxygen carrier exposed a mesoporous structure with a high surface area of 315.9m2g−1. The redox results revealed that 15Cu/20Zr-Al oxygen carrier exhibited the highest activity and showed about 99.2% CH4 conversion at a low temperature of 650°C. This oxygen carrier revealed high stability for CH4 and CO2 conversion, hydrogen production yield and CO/CO2 ratio during 16 redox cycles at 650°C.