中试规模下微等离子体对甲苯的降解性能研究

Study on Degradation of Toluene by Micro-plasma in Pilot Scale

下载PDF

导出

摘要为了实现高效、低能耗降解大流量下低浓度的污染物,在中试规模常温常压下采用了微等离子体技术对大流量的甲苯废气进行处理。从废气气体流量、甲苯浓度、相对湿度、微等离子体反应器输入能量密度等方面,对甲苯降解性能进行评价;采用气相色谱、质谱和红外光谱仪对降解反应产物进行分析,探讨了微等离子体降解甲苯的机理及反应途径。结果表明:在废气气体流量为100 Nm^3·h^(-1)、甲苯浓度为50 ppm、相对湿度为1%~3%、输入能量密度为30 J·L^(-1)时,微等离子体对甲苯的降解率达到74.4%。甲苯分子在微等离子体中的降解主要是通过高能电子轰击和活性物种氧化,甲基C-H键易受到高能电子的轰击生成一系列含氧有机中间产物,醛类、酚类、醇类、羧酸类、以及带苯环的衍生物等。 In order to achieve high-efficiency and low-energy degradation of low-concentration pollutants at high flow rate, this study intends to use micro-plasma technology to treat large volume of toluene exhaust gas under normal temperature and atmospheric pressure in pilot scale. The toluene degradation performance was evaluated from toluene concentration, relative humidity, reactor input energy density, and exhaust gas flow rate. The degradation reaction products were analyzed by gas chromatography, mass spectrometry, and infrared spectroscopy. On the basis of the analytic results of GC-MS, the reaction pathway and mechanism of destruction of toluene in the micro-plasma system were discussed. The results showed that under the exhaust flow rate of 100 Nm 3·h -1 , the input energy of 30 J·L -1 , and the relative humidity of 1%~3%, the degradation rate of toluene by micro-plasma was up to 74.4% with the toluene concentration of 50 ppm. The degradation of toluene in micro-plasma is mainly through high-energy electron bombardment and active species oxidation. Methyl C-H bonds are easily bombarded by high-energy electrons to produce a series of organic oxygen-containing intermediates, such as aldehydes, phenols, alcohols, carboxylic acids, and derivatives with benzene rings.

作者黄竹刘东平牛金海牛春杰吕梦尧 HUANG Zhu 1,2 ,LIU Dong-ping 1,NIU Jin-hai 1,NIU Chun-jie 1,LV Meng-yao 1(1.School of Physics and Material Engineering, Dalian Minzu University, Dalian Liaoning 116605, China;2. School of Science, Dalian Maritime University, Dalian Liaoning 116026, Chin)

机构地区大连民族大学物理与材料工程学院大连海事大学理学院

出处《大连民族大学学报》 2018年第3期242-248,共7页 Journal of Dalian Minzu University

基金国家自然科学基金资助项目(11475042)

关键词微等离子体中试规模甲苯降解机理 micro-plasma pilot scale toluene degradation mechanism

分类号 X131.1 [环境科学与工程—环境科学]

引文网络
相关文献

参考文献4

1周学双,童莉,韩建华,郭森.工业VOCs精细化环境管理的对策建议[J].环境保护,2014,42(1):41-43. 被引量：12
2李璇,王雪松,刘中,吴梁,翁燕波,胡杰.宁波人为源VOC清单及重点工业行业贡献分析[J].环境科学,2014,35(7):2497-2502. 被引量：31
3葛文杰..介质阻挡放电微等离子体转化甲醇制氢[D].天津大学,2014:
4杨懿,张玮,吴军良,付名利,陈礼敏,黄碧纯,叶代启.等离子体催化降解甲苯途径的原位红外研究[J].环境科学学报,2013,33(11):3138-3145. 被引量：8

二级参考文献84

1沈旻嘉,郝吉明,王丽涛.中国加油站VOC排放污染现状及控制[J].环境科学,2006,27(8):1473-1478. 被引量：78
2Andrews L, Robert C, Spiker J. 1972. Argon matrix Raman and infrared spectra and vibrational analysis of ozone and the oxygen- 18 substituted ozone molecules[ J]. The Journal of physical Chemistry, 76 (22) :3208-3213. 被引量：1
3Budevska B O. 2000. Minimization of optical non-linearities in Fourier transform-infrared microspectroscopic imaging [ J ]. Vibrational Spectroscopy, 24 ( 1 ) :37-45. 被引量：1
4Chang J S. 2001. Recent development of plasma pollution control technology: a critical review [ J ]. Science and Technology of Advanced Materials,2(3/4) :571-576. 被引量：1
5Chen H L, Lee H M, Chen S H, et al. 2008. Review of packed-bed plasma reactor for ozone generation and air pollution control [ J ]. Industrial & Engineering Chemistry Research, 47:2122-2130. 被引量：1
6Choi J, Rubner M F. 2005. Influence of the Degree of Ionization on Weak Polyelectrolyte Multilayer Assembly [ J ]. Macromolecules, 38 (1) :116-124. 被引量：1
7Das D, Mukherjee A, Bhattacharya P, et al.2011. Finishing of silk by acrylic acid in the presence of sodium citrate and potassium per sulphate as catalysts under thermal treatment[J]. Journal of Applied Polymer Science, 121 (2) :770-776. 被引量：1
8Demidiouk V, Chae J O. 2005. Decomposition of volatile organic compounds in plasma-catalytic system [ J ]. IEEE Transactions on Plasma Science, 33 ( 1 ) : 157-161. 被引量：1
9Dozov I, Kirov N, Fontana M P. 1984. Determination of reofientational correlation functions in ordered fluids: IR absorption spectroscopy [J]. Journal of Chemical Physics,81(6) : 2585-2591. 被引量：1
10Eby T, Gundusharm U, Lo M, et al. 2012. Reverse engineering of polymeric multilayers using AFM-based narloscale IR spectroscopy and thermal analysis [ J ]. Spectroscopy Europe, 24 (3) : 18-18. 被引量：1

共引文献48

1姜洁,李丹丹,孟辰宇,陈英.C-N-S-TiO2吸附-光催化海洋溢油(甲苯)的研究[J].农村经济与科技,2020(13):45-47.
2张培智,范辰华.石化企业VOCs泄漏检测与修复设备动静密封点建档方式研究[J].科技经济导刊,2020(2):76-77. 被引量：1
3周学双,童莉,郭森,何少林.我国工业源挥发性有机物综合整治建议[J].环境保护,2014,42(13):36-37. 被引量：9
4郭森,周学双,童莉,崔积山,沙莎.完善我国工业源VOCs控制标准的对策建议[J].环境影响评价,2015,37(2):41-45. 被引量：10
5陈玉伟,牟桂芹,姜学艳.石化行业VOCs防控及对策研究[J].管理观察,2015(4):67-68. 被引量：1
6郑丹楠,王雪松,周军,应红梅,吴梁,胡杰.2013年1月宁波市PM2.5污染的形成过程与传输规律[J].环境科学学报,2015,35(8):2378-2386. 被引量：20
7刘巧,陈扬达,吴军良,叶代启.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. 被引量：3
8黄炯,叶代启,杨佘维.介质阻挡放电-催化降解甲苯的研究[J].华南师范大学学报（自然科学版）,2016,48(3):102-108. 被引量：2
9殷济海.我国石化行业大气污染特点及防治对策[J].中国储运,2016(10):123-125. 被引量：3
10陈文聪,侯艺文,吴建,王莉红.化纤行业PM_(2.5)和VOCs排放特性研究[J].浙江大学学报（工学版）,2017,51(1):145-152. 被引量：1

1肖建军,李亚龙,杨琦.寡养单胞菌降解石油污染土壤中的甲苯[J].环境工程,2018,36(4):186-189. 被引量：9
2赵同谦,李鹏,邰超,象豫,李虹妍,马永霞,齐永安,张国成.煤生物成气过程中溶解性有机物的光谱特征研究[J].煤炭学报,2017,42(S2):525-534. 被引量：7
3王红芳,胡江春.“互联网+”主题式教学模式的构建与应用[J].教育教学论坛,2018(23):205-206.
4陶爱峰,严玮文,倪春辉.制鞋行业接触粘胶剂作业对女工生殖健康的影响[J].江苏预防医学,2017,28(6):699-701. 被引量：2
5姚旭京,周拯晔.浙江核电的光荣与梦想[J].科学24小时,2018,0(7):27-29.
6林涛,万克柔,程杰,张炳亮,曾利辉,高武,曾永康,张之翔.低浓度甲苯催化燃烧蜂窝陶瓷催化剂的制备[J].山东化工,2018,47(5):55-57. 被引量：1
7徐秀璋,房月华.DABITC/PITC双偶合法在蛋白质手工固相顺序分析中的应用[J].生物化学与生物物理进展,1984,15(1):32-38.
8Wen Li,Hongqi Ye,Gonggang Liu,Hongchao Ji,Yonghua Zhou,Kai Han.The role of graphene coating on cordierite-supported Pd monolithic catalysts for low-temperature combustion of toluene[J].Chinese Journal of Catalysis,2018,39(5):946-954. 被引量：10
9吴建荣.HDP-CVD磷硅玻璃特殊磷掺杂分布的机理研究[J].微电子学,2018,48(3):411-415.
10杨志宇.高能量可修复材料[J].现代材料动态,2018,0(5):12-12.

大连民族大学学报

2018年第3期

浏览历史

内容加载中请稍等...

中试规模下微等离子体对甲苯的降解性能研究

参考文献4

二级参考文献84

共引文献48

相关作者

相关机构

相关主题

浏览历史