流向变换等离子体催化系统去除甲苯

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摘要

将低温等离子体、催化和流向变换技术相结合，以反应系统参数（接地极方式、反应管壁厚）和电源参数（电压、频率）为影响因素，探究了上述因素对系统温度升高（△T）、放电能量密度（SED）和能量效率（EE）的影响，考察了不同条件对甲苯的去除效果（η）和反应产物的影响.结果表明：流向变换低温等离子体协同催化系统中，甲苯去除效果最好，能量利用率最高，为3.76g/（kW·h）.连续升压时，3种接地条件下的温度升高△T差距不明显；铝箔接地时，O₃浓度最高、甲苯去除率η、SED和EE最高；增加反应管壁厚，系统△T、η、SED和EE减小.3种技术结合时，NO₂生成浓度低、有机副产物生成种类较少，CO₂选择性高，甲苯矿化率最高.固定频率，改变电压时，△T、η、SED与电压值呈正比，EE则相反，铝箔接地时，17kV时△T达到110.7℃，η达到74.05%；副产物O₃浓度先上升后下降，最终趋于0mg/m³；固定电压，改变频率时，变化规律一致.

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	梁文俊
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	李坚

关键词 ：低温等离子体, 流向变换, 催化, 甲苯

Abstract：

Combined with NTP, catalysis and reverse-flow technology, the effects on the temperature rise (△T), specific energy density (SED) and energy efficiency (EE) of the system were investigated under the influence of different reaction system (grounding mode, wall thickness) and power supply (voltage and frequency). The effects of toluene removal (η) and products were also analyzed. The results showed that the reverse flow non-thermal plasma-catalytic reaction system had the best η and EE, which was 3.76g/(kW·h). The differences in △T under three grounding conditions were not significant when voltage was increased continuously. The concentrations of O₃, η, SED and EE were the highest when the aluminum foil was grounded. The △T, η, SED and EE decreased with the increase of wall thickness. When three technologies were combined, NO₂ was less generated, fewer types of organic by-products were produced, the CO₂ selectivity was high and the toluene mineralization rate were highest. When the frequency was fixed, the △T, η, SED were positively proportional to the voltage as voltage increased, while the EE showed the opposite correlation with voltage. When aluminum foil was grounded, the △T achieved 110.7℃ and the η was 74.05%. The concentration of the byproduct (O³) increased in the beginning, then decreased, and finally became 0mg/m³. When the frequency changed while the voltage was fixed, the change rules were the same.

Key words： non-thermal plasma reverse flow catalytic toluene

收稿日期: 2019-05-05

PACS:

X511

基金资助:

国家重点研发计划（2016YFC0204300）；北京市自然科学基金资助项目（8162009）

通讯作者: 梁文俊,教授,liangwenj@bjut.edu.cn E-mail: liangwenj@bjut.edu.cn

作者简介: 梁文俊(1978-),男,山西太原人,教授,博士,主要从事大气污染控制研究.发表论文50余篇.

引用本文:

梁文俊, 孙慧频, 朱玉雪, 李坚. 流向变换等离子体催化系统去除甲苯[J]. 中国环境科学, 2019, 39(12): 4974-4981. LIANG Wen-jun, SUN Hui-pin, ZHU Yu-xue, LI Jian. Removal of toluene with a reverse flow non-thermal plasma-catalytic reaction system. CHINA ENVIRONMENTAL SCIENCECE, 2019, 39(12): 4974-4981.

链接本文:

http://www.zghjkx.com.cn/CN/ 或 http://www.zghjkx.com.cn/CN/Y2019/V39/I12/4974

[1]	ODA T. Non-thermal plasma processing for environmental protection:decomposition of dilute VOCs in air[J]. Journal of Electrostatics, 2003,57(3):293-311.
[2]	Urashima K, Chang J S. Removal of Volatile organic compounds from air streams and industrial flue gases by non-thermal plasma technology[J]. IEEE Transactions on Dielectrics & Electrical Insulation, 2000,7(5):602-614.
[3]	杨茜,易红宏,唐晓龙,等.低温等离子体处理工业废气中甲苯的研究进展[J]. 安全与环境工程, 2017,24(1):77-83. Yang Q, Yi H H, Tang X L, et al. Research progress in treatment of toluene in industrial waste gas by non-thermal plasma technology[J]. Safety and Environmental Engineering, 2017,24(1):77-83.
[4]	Li Y, Fan Z, Shi J, et al. Removal of volatile organic compounds (VOCs) at room temperature using dielectric barrier discharge and plasma-catalysis[J]. Plasma Chemistry & Plasma Processing, 2014, 34(4):801-810.
[5]	姚伟卿.低温等离子体结合催化去除VOCs的研究进展[J]. 广东化工, 2008,35(11):99-102. Yao W Q. Research development on removal of VOCs by a method of non-thermal plasma combined catalysis[J]. Guangdong Chemical Industry, 2008,35(11):99-102.
[6]	梁文俊,郭书清,武红梅,等.非热等离子体协同Mn-Ce/La/γ-Al2O3催化剂去除甲苯[J]. 化工学报, 2017,68(7):2755-2762. Liang W J, Guo S Q, Wu H M, et al. Removal of toluene using non-thermal plasma coupled with Mn-Ce/La/γ-Al2O3 catalysts[J]. CIESC Journal, 2017,68(7):2755-2762.
[7]	Mei D, Zhu X, Wu C, et al. Plasma-photocatalytic conversion of CO2, at low temperatures:Understanding the synergistic effect of plasma-catalysis[J]. Applied Catalysis B Environmental, 2016,182(24):525-532.
[8]	陈耿.处理低浓度有机废气的流向变换催化燃烧反应技术研究[D]. 杭州:浙江大学, 2011. Chen G. Study on reverse flow reactor for decontaminating lean volatile organic compounds in waste gas[D]. Hangzhou:Zhejiang University, 2011.
[9]	梁文俊,李玉泽,郑川,等.用于低浓度一氧化碳去除的流向变换系统[J]. 北京工业大学学报, 2016,42(9):1428-1434. Liang W J, Li Y Z, Zheng C, et al. Reverse-flow reactor in removal of lean carbon monoxide[J]. Journal of Beijing University of Technology, 2016,42(9):1428-1434.
[10]	梁文俊,武红梅,李坚,等.流向变换-低温等离子体反应系统用于VOCs去除及热量分布研究[J]. 环境工程技术学报, 2018,8(4):373-380. Liang W J, Wu H M, Li J, et al. Removal of VOCs and heat distribution in a flow reversal plasma reaction system[J]. Journal of Environmental Engineering Technology, 2018,8(4):373-380.
[11]	梁文俊,武红梅,任思达,等.流向变换-等离子体-催化反应系统降解甲苯[J]. 工业催化, 2018,26(12):79-82. Liang W J, Wu H M, Ren S D, et al. Decomposition of toluene in reverse-flow plasma catalytic system[J]. Industrial catalysis, 2018, 26(12):79-82.
[12]	梁文俊,武红梅,李坚,等.流向变换等离子体反应系统降解甲苯性能[J]. 工业催化, 2018,26(4):72-76. Liang W J, Wu H M, Li J, et al. Degradation of toluene in flow reversal plasma reaction system[J]. Industrial Catalysis, 2018,26(4):72-76.
[13]	竹涛,李坚,何绪文,等.低温等离子体协同催化技术降解甲苯的研究[J]. 北京工业大学学报, 2011,37(10):1536-1542. ZHU T, LI J, HE X W, et al. VOCs removal using nonthermal plasma coupled with catalysis[J]. Journal of Beijing Polytechnic University, 2011,37(10):1536-1542.
[14]	梁文俊,马琳,李坚,等.低温等离子体-催化联合技术去除甲苯的实验研究[J]. 北京工业大学学报, 2014,40(2):315-320. Liang W J, Ma L, Li J, et al. Removal of toluene by non-thermal plasma coupled with catalyst[J]. Journal of Beijing Polytechnic University, 2014,40(2):315-320.
[15]	武红梅.流向变换-等离子体反应系统降解甲苯研究[D]. 北京:北京工业大学, 2018. Wu H M. Degradation of toluene by flow reversal plasma reaction system[D]. Beijing:Beijing University of Technology, 2018.
[16]	区瑞锟.介质阻挡放电等离子体中的活性粒子及其降解甲醛的研究[D]. 广州:华南理工大学, 2011. Qu R K. Active species produced by dielectric barrier discharge and their application to formaldehyde degradation[D]. Guangzhou:South China University of Technology, 2011.
[17]	那刚.线筒式脉冲电晕放电对混合VOCs降解的研究[D]. 大连:大连理工大学, 2010. NA G. Study of the decomposition of mixed VOCs by wire tube pulsed corona discharge[D]. Dalian:Dalian University of Technology, 2010.
[18]	李健,周军,黄瑞平,等.沿绝缘表面空气间隙击穿特性的试验研究[J]. 高压电器, 2017,53(5):6-11. Li J, Zhou J, Huang R P, et al. Experimental study of the breakdown characteristic of the air gap along dielectric surface[J]. High Voltage Apparatus, 2017,53(5):6-11.
[19]	竹涛,梁文俊,李坚,等.等离子体联合纳米技术降解甲苯废气的研究[J]. 中国环境科学, 2008,28(8):699-703. Zhu T, Liang W J, Li J, et al. Degradation of toluene in exhaust gas with plasma and nano-materials[J]. China Environmental Science, 2008,28(8):699-703.
[20]	赵琼.低温等离子体降解VOCs的DBD反应器优化探索和产物分析[D]. 上海:东华大学, 2017. Zhao Q. Study of the VOCs degradation by optimization of DBD plasma reactor[D]. Shanghai:Donghua University, 2017.
[21]	鲁美娟,杨文亭,喻成龙,等.等离子体协同催化降解VOCs过程中O3的作用机理[J]. 化工进展, 2018,37(7):2649-2654. Lu M J, Yang W T, Yu C L, et al. Role of O3 during the plasma-catalytic oxidation of VOCs[J]. Chemical Industry and Engineering Progress, 2018,37(7):2649-2654.
[22]	刘巧,陈扬达,吴军良,等.两种放电模式降解甲苯的原位红外研究[J]. 中国环境科学, 2015,35(12):3612-3619. Liu Q, Chen Y D, Wu J L, et al. In situ infrared spectroscopic studies of catalytic degradation of toluene by continuous discharge and adsorptive storage-discharge[J]. China Environmental Science, 2015, 35(12):3612-3619.
[23]	梁文俊,王爱华,樊星,等.低温等离子体协同钒钛催化剂降解甲苯试验[J]. 北京工业大学学报, 2015,41(4):628-635. Liang W J, Wang A H, Fan x, et al. Removal of toluene by non-thermal plasma coupled with V-Ti catalysis[J]. Journal of Beijing University of Technology, 2015,41(4):628-635.
[24]	杜长明,黄娅妮,巩向杰.等离子体净化苯系物[J]. 中国环境科学, 2018,38(3):871-892. Du C M, Huang Y N, Gong X J. Decomposition of benzene series by plasma technology[J]. China Environmental Science, 2018,38(3):871-892.