Transfer and Reaction Performances of Selective Catalytic Reduction of NzO with CO over Monolith Catalysts 被引量：3

Transfer and Reaction Performances of Selective Catalytic Reduction of N2O with CO over Monolith Catalysts

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摘要 This work tries to identify the relationship between geometric configuration of monolith catalysts, and transfer and reaction performances for selective catalytic reduction of N2O with CO. Monolith catalysts with five different channel shapes (circle, regular triangle, rectangle, square and hexagon), was investigated to make a comprehensive comparison of their pressure drop, heat transfer Nu number, mass transfer Sh number and N2O conversion. It was found that monolith catalysts have a much lower pressure drop than that of traditional packed bed, and for monolith catalysts with different channel shapes, pressure drop decreases in the order of regular triangle > rectangle > square > hexagon > circle. The order of Nu is in regular triangle > rectangle ≈ square > hexagon > circle, similar to that of Sh. N2O conversion follows the order of regular triangle > rectangular ≈ square ≈ circle > hexagon. The results indicate that chemical reaction including internal diffusion is the controlling step in the selective catalytic reduction of N2O removal with CO. In addition, channel size and gas velocity also have influence on N2O conversion and pressure drop. This work tries to identify the relationship between geometric configuration of monolith catalysts, and transfer and reaction performances for selective catalytic reduction of N2O with CO. Monolith catalysts with five different channel shapes （circle, regular triangle, rectangle, square and hexagon）, was investigated to make a comprehensive comparison of their pressure drop, heat transfer Nu number, mass transfer Sh number and N2O conversion. It was found that monolith catalysts have a much lower pressure drop than that of traditional packed bed, and for monolith catalysts with different channel shapes, pressure drop decreases in the order of regular triangle 〉 rectangle 〉 square 〉 hexagon 〉 circle. The order of Nu is in regular triangle 〉 rectangle ≈ square 〉 hexagon 〉 circle, similar to that of Sh. N2O conversion follows the order of regular triangle 〉 rectangular ≈ square ≈ circle 〉 hexagon. The results indicate that chemical reaction including internal diffusion is the controlling step in the selective catalytic reduction of N2O removal with CO. In addition, channel size and gas velocity also have influence on N2O conversion and pressure drop.

作者代成娜雷志刚王玉丽张润铎陈标华

机构地区 State Key Laboratory of Chemical Resource Engineering

出处《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2013年第8期835-843,共9页 中国化学工程学报（英文版）

基金 Supported by the National Natural Science Foundation of China （21121064, 21076008） the Projects in the National Science ＆ Technology Pillar Program During the 12th Five-Year Plan Period （2011BAC06B04）

关键词 selective catalytic reduction N2O conversion momentum transfer heat transfer mass transfer monolith catalysts mathematical modeling 选择性催化还原还原催化剂反应性能 CO 整体式催化剂正三角形传递 N2O

分类号 O613.71 [理学—无机化学] X701 [环境科学与工程—环境工程]

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