Performance of CO purification from sintering flue gas by copper - manganese - based monolithic catalyst
LI Zi-yi1, BIAN Wen-bo1, HOU Huan-yu2, ZHANG Xuan1, JIANG Li-jun1, SUN Fang-zhou2, LIU Ying-shu1
1. School of Energy and Environmental Engineering, University of Science and Technology Beijing, Beijing 100083, China; 2. Strategic Research Institute of HBIS Group, Shijiazhuang 050023, China
Abstract:In this paper, the catalyst powder, the monolithic catalyst based on modified copper manganese oxides supported by foam metals and cordierite were prepared. The CO conversion efficiency and stability of the three samples were compared under the gas condition prepared in the laboratory. The monolithic catalyst supported by cordierite was selected, and its CO conversion efficiency, stability, and catalytic characteristics after degradation at different loading amounts, space velocities, and temperatures were tested under the actual condition of iron-ore sintering flue gas in a steel plant. 2m3 volume of optimized monolithic catalyst was prepared in batches and a pilot test of CO purification from 6000m3/h sintering flue gas was carried out. The results show that the high-concentration water vapor in the flue gas significantly inhibited the CO catalytic oxidation reaction, resulting in T90 increased by 38℃ after reaction for 240h. The higher loading amount of the catalysts, the lower the T90, the shorter the duration for efficiency decay, and the higher the stabilized efficiency. However, this advantage decreases with increasing space velocity. In the pilot test for 1440h (2months) at the inlet feed temperature of 185~195℃, the CO conversion efficiency was constantly greater than 85% (averaged at 90%), and the CO concentration downstream was lower than 1000×10-6 with temperature reaching 220℃, which obtained benefit of both energy saving and emission reduction.
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LI Zi-yi, BIAN Wen-bo, HOU Huan-yu, ZHANG Xuan, JIANG Li-jun, SUN Fang-zhou, LIU Ying-shu. Performance of CO purification from sintering flue gas by copper - manganese - based monolithic catalyst. CHINA ENVIRONMENTAL SCIENCECE, 2022, 42(9): 4052-4058.
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