Study on the arrangement of CO2 sorbent and catalyst for integrated CO2 capture and methanation
Zongze Lv, Junqiang Han, Tao Deng, Chang Gao, Jianan Li, Changlei Qin
Abstract
Integrated CO 2 capture and utilization (ICCU) is an emerging technology to reduce CO 2 emissions by greatly simplifying the processes of conventional CO 2 capture and utilization. In particular, ICCU-methanation could directly convert the low-concentration CO 2 into CH 4 using hydrogen from new energy electricity, representing an efficient Power-to-Gas route. CO 2 adsorption/catalytic materials play a crucial role for the operation of ICCU-methanation, and it is more feasible to scale up material production and avoid components interference by directly combining the sorbent and catalyst. However, it is necessary to reveal the effect of different arrangements of sorbent and catalyst on reaction characteristics of ICCU-methanation. In the work, the matching of K 2 CO 3 -doped Li 4 SiO 4 sorbent with various supported Ni-based catalyst was tested and four arrangements of sorbent and catalyst particles in a fixed-bed were investigated to understand the influences on ICCU-methanation. Results show that the presence of catalyst accelerates CO 2 supply by sorbent and achieves quicker methanation, and the promotion effect becomes more obvious with a closer contact between the sorbent and catalyst. Under optimized conditions, ICCU-methanation of uniformly mixed K-Li 4 SiO 4 and Ni/Al 2 O 3 shows an excellent performance with very stable CO 2 conversion of 95.58% and CH 4 selectivity of 93.29% during cyclic reactions.