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复合载体负载型催化剂制备及其微波辅助催化氧化甲苯性能试验()

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西安建筑科技大学学报:自然科学版[ISSN:1006-7930/CN:61-1295/TU]

卷:: 46
期数:: 2014年01期

页码:: 131-136

栏目:

出版日期:: 2014-02-28

文章信息/Info

Title:: Preparation of composite carrier loaded catalyst and microwave assisted catalytic oxidation of gaseous toluene

文章编号:: 1006-7930(2014)01-0131-06

作者:: 杨全; 张浩; 卜龙利; (西安建筑科技大学环境与市政工程学院,陕西西安 710055)

Author(s):: YANG QuanZHANG HaoBO Longli; (School of Envir. And Muni. Eng. ,Xian Univ. of Arch. & Tech. Xian 710055,China)

关键词:: 复合载体负载铜-锰-铈催化剂; 微波加热; 催化氧化; 甲苯

Keywords:: composite carrier loaded Cu-Mn-Ce catalyst; microwave heating; catalytic oxidation; toluene

分类号:: X 703.1

DOI:: 10.15986/j.1006-7930.2014.01.023

文献标志码:: A

摘要:: 将吸附材料分子筛粉末、吸波材料碳化硅粉末以及催化活性组分铜（Cu）、锰(Mn)、铈(Ce)盐溶液完全混合，通过制粒、煅烧后制得复合载体负载型催化剂；微波辐照条件下，应用该催化剂进行了甲苯废气的催化氧化性能试验研究．研究表明，复合载体负载型催化剂的优化制备条件为：高岭土为粘合剂，掺入3%的碳化硅，铜锰质量比为1︰1（各5 %负载量），铈的掺杂量为1.67 %，焙烧温度为500 ℃，焙烧时间为8h. 反应温度210 ℃下，优化制备的复合载体催化剂催化氧化甲苯的转化率达95 %，表现出良好的低温活性和催化氧化性能．

Abstract:: Molecular sieve powder, silicon carbide powder and copper (Cu), manganese (Mn) and cerium (Ce) saline solutions were mixed completely, and then pelletized and calcined to prepare composite carrier loaded Cu- Mn-Ce catalyst. The catalyst prepared was applied to oxidize gaseous toluene under microwave irradiation and continuous flow mode, and catalytic performance was mainly checked. The research showed that optimization preparation conditions of the catalyst were kaolin as the binder, 3% silicon carbide doping amount, 1:1 mass ratio for Cu and Mn and 5% loaded amount respectively, 1.67% cerium doping amount, 500 ℃ calcination temperature and 8 h roasting time. Under the reaction temperature of 210 ℃, the removal efficiency of toluene reached 95% by microwave assisted catalytic oxidation using optimized catalyst. It indicated that the prepared catalyst owned good catalytic activity and performance under low temperature.

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备注/Memo

备注/Memo:: 基金项目：西安市产业技术创新计划-技术转移促进工程项目(CX12176-4)
收稿日期：2013-05-20 修改稿日期：2014-02-17
作者简介：杨全(1968-)，男，工程师，硕士，主要大气污染控制方向研究为.E-mail：yangquan@xauat.edu.cn

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