Chemical Industry and Engineering Progress ›› 2017, Vol. 36 ›› Issue (11): 4232-4242.DOI: 10.16085/j.issn.1000-6613.2017-0382
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WANG Bo, MA Rui, XUE Guocheng, ZHANG Long
Received:
2017-03-08
Revised:
2017-04-24
Online:
2017-11-05
Published:
2017-11-05
王波, 马睿, 薛国程, 张龙
通讯作者:
王波(1981-),男,副教授,主要从事锅炉技术和废弃物热处置技术研究。
作者简介:
王波(1981-),男,副教授,主要从事锅炉技术和废弃物热处置技术研究。E-mail:wangbo@usst.edu.cn。
CLC Number:
WANG Bo, MA Rui, XUE Guocheng, ZHANG Long. Research progress on thermal oxidation technology for industrial organic waste gas[J]. Chemical Industry and Engineering Progress, 2017, 36(11): 4232-4242.
王波, 马睿, 薛国程, 张龙. 工业有机废气热氧化技术研究进展[J]. 化工进展, 2017, 36(11): 4232-4242.
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[1] 童喜润,党杰,杨明德,等. 蓄热催化氧化法处理挥发性有机物的研究进展[J]. 安徽化工,2004,30(1):40-43. TONG X R,DANG J,YANG M D,et al. Research development on the volatile organic compounds by the regenerative & catalytic oxidation[J]. Anhui Chemical Industry,2004,30(1):40-43. [2] MILLS B. Abatement of VOCs[J]. Surface Coatings International,1998,81(5):223-229. [3] 郭昊. 活性炭吸附回收VOCs的过程研究与工程设计[D]. 北京:中国林业科学研究院,2014. GUO H. Process study and engineering design of activated carbon adsorption and recovery of VOCs[D]. Beijing:Chinese Academy of Forestry Sciences,2014. [4] 肖潇. 液体吸收法资源化处理工业甲苯废气的研究[D]. 北京:中国科学院大学,2015. XIAO X. Study on the treatment of toluene waste gas by liquid absorption[D]. Beijing:University of Chinese Academy of Sciences,2015. [5] GUPTA V K,VERMA N. Removal of volatile organic compounds by cryogenic condensation followed by adsorption[J]. Chemical Engineering Science,2002,57(14):2679-2696. [6] DEHGHANZADEH R,TORKIAN A,BINA B,et al. Biodegradation of styrene laden waste gas stream using a compost-based biofilter[J]. Chemosphere,2005,60(3):434-9. [7] YAMAMOTO T. VOC decomposition by nonthermal plasma processing-a new approach[J]. Journal of Electrostatics,1997,42(1/2):227-238. [8] 胡辉,李胜利,杨长河,等. 放电等离子体处理挥发性有机物的研究进展[J]. 高电压技术,2002,28(3):43-45. HU H,LI S L,YANG C H,et al. The progress on study of treatment of volatile organic compounds by discharge plasma[J]. High Voltage Engineering,2002,28(3):43-45. [9] NAIR S A,PEMEN A J M,YAN K,et al. Tar removal from biomass-derived fuel gas by pulsed corona discharges[J]. Fuel Processing Technology,2003,84(1/2/3):161-173. [10] 杨培法. 热氧化工艺在有机废气及废液处理中的应用[J]. 能源环境保护,2016,30(1):21-25. YANH P F. Application of thermal oxidation process in organic waste gas and waste liquid treatment[J]. Energy Environmental Protection,2016,30(1):21-25. [11] 杨振华,马晓驰,蔡鹏山,等. 蓄热式热氧化器转化效率的研究[J]. 化工机械,2015(1):42-44. YANG Z H,MA X C,CAI P S,et al. Study of conversion rate of regenerative thermal oxidizer[J]. Chemical & Machinery,2015(1):42-44. [12] 张建萍,项菲. 浅析蓄热式热力氧化技术处理挥发性有机废气[J].浙江化工,2014(3):36-39. ZHANG J P,XIANG F. The treatment of the volatile organic compound gas by the regenerative thermal oxidation technology[J]. Zhejiang Chemical Industry,2014(3):36-39. [13] ZHANG J,ZHANG C,HE H. Remarkable promotion effect of trace sulfation on OMS-2 nanorod catalysts for the catalytic combustion of ethanol[J]. Journal of Environmental Sciences,2015,35(9):69-75. [14] 陈华栋,张翠亚,曹冠宇,等. 活性炭吸附器+蓄热式热氧化器集成设备的开发研究[J]. 化工机械,2016,43(1):55-58. CHEN H D,ZHANG C Y,CAO G Y,et al. Developmental research of device integrating activated carbon adsorber with regenerative thermal oxidizer[J]. Chemical Machinery,2016,43(1):55-58. [15] 罗晓,杜玮,谢安国. 蓄热体结构分析及其内部气体流动特性的数值研究[J]. 节能技术,2012,30(3):239-244. LUO X,DU W,XIE A G. Numerical research of structural analysis and innerflow characteristics in honeycomb regenerator of different shapes[J]. Energy Conservation Technology,2012(3):239-244. [16] 范蕾,马青波. 高温燃烧技术中蓄热体研究[J]. 河南机电高等专科学校学报,2010,18(3):31-33. FAN L,MA Q B. Study of regenerator in high temperature air combustion[J]. Journal of Henan Mechanical and Electrical Engineering College,2010,18(3):31-33. [17] 张振兴,刘永启,高振强,等. 陶瓷蓄热体的流动与传热特性模拟研究[J]. 内燃机与动力装置,2010(2):18-22. ZHANG Z X,LIU Y Q,GAO Z Q,et al. Simulation study on flow and heat transfer in ceramic regenerator[J]. Internal Combustion Engine & Powerplant,2010(2):18-22. [18] 中国建筑材料联合会. 蜂窝陶瓷蓄热体:JC/T 2135-2012[S]. 北京:中国建材工业出版社,2013. China Building Materials Federation. Honeycomb ceramic regenerator:JC/T 2135-2012[S]. Beijing:China Building Materials Industry Press,2013. [19] 宋婧,曾令可,刘艳春,等. 陶瓷蓄热体的研究现状及应用[J]. 中国陶瓷,2007,43(6):7-10. SONG J,ZENG L K,LIU Y C,et al. Research and application of ceramic heat storage materials[J]. China Ceramics,2007,43(6):7-10. [20] 牟宝杰. 蜂窝陶瓷蓄热体阻力特性和传热特性实验研究[D]. 淄博:山东理工大学,2011. MOU B J. Experimental research on honeycomb ceramic regenerator fluid dynamic and thermal performance[D]. Zibo:Shandong University of Technology,2011. [21] 张志诚. 蜂窝陶瓷蓄热体综合性能实验台监控系统开发与研究[D]. 淄博:山东理工大学,2011. ZHANG Z C. Research and development of monitoring and control system on honeycomb ceramic performance test[D]. Zibo:Shandong University of Technology,2011. [22] 郑志伟,仇性启,祁风雷,等. 蜂窝陶瓷蓄热体传热和阻力特性实验研究[J]. 石油化工设备,2013,42(1):9-13. ZHENG Z W,QIU X Q,QI F L,et al. Experimental study of heat transfer and resistance characteristics on honeycomb ceramic regenerator[J]. Petro-Chemical Equipment,2013,42(1):9-13. [23] 高阳,雍海泉,徐志鹏,等. 蜂窝陶瓷蓄热体传热与阻力特性的热态实验研究[J]. 冶金能源,2008,27(5):25-27. GAO Y,YONG H Q,XU Z P,et al. Thermal state experiment research on the heat transfer and resistance characters of honeycomb ceramic regenerator[J]. Energy for Metallurgical Industry,2008,27(5):25-27. [24] 欧阳德刚,肖坤伟,周明石,等. 蜂窝陶瓷辐射体非稳态传热特性研究[J]. 钢铁研究,1997(2):44-49. OUYANG D G,XIAO K W,ZHOU M S,et al. Study on unsteady heat transfer characteristics honeycomb ceramic heat radiator[J]. Research on Iron & Steel,1997(2):44-49. [25] KLEIN H,EIGENBERGERB G. Approximate solutions for metallic regenerative heat exchangers[J]. International Journal of Heat & Mass Transfer,2001,44(18):3553-3563. [26] 艾元方,梅炽,黄国栋,等. 薄壁蓄热器最大相对温度和最佳切换时间[J]. 热能动力工程,2006,21(4):362-365. AI Y F,MEI Z,HUANG G D,et al. Maximal relative temperature and optimum switching-over time for a thin-wall heat accumulator[J]. Journal of Engineering for Thermal Energy and Power,2006,21(4):362-365. [27] 陈新进,王庆顺,孙伟. 基于Fluent的蓄热体传热过程的数值模拟[J]. 机械工程师,2015(4):71-73. CHEN X J. WANG Q S,SUN W. Numerical simulation of heat transfer process regenerator based on Fluent[J]. Mechanical Engineer,2015(4):71-73. [28] 刘光临,诸葛伟林,王玺堂,等. 蓄热式燃烧系统动态运行特性研究[J]. 武汉科技大学学报(自然科学版),2004,27(2):145-147. LIU G L,ZHUGE W L,WANG X T,et al. Research on dynamic operation characteristics of the regenerative combustion system[J]. Journal of Wuhan University of Science and Technology(Natural Science Edition),2004,27(2):145-147. [29] 张振兴. 基于均匀多孔介质模型的氧化床阻力特性数值研究[D]. 淄博:山东理工大学,2010. ZHANG Z X. Resistance investigation of the oxidation bed based on homogeneous porous media mode[D]. Zibo:Shandong University of Technology,2010. [30] SPIVEY J J. Complete catalytic oxidation of volatile organics[J]. Ind. Eng. Chem. Res,1989,26(11):2165-2180. [31] TIAN Z Y,NGAMOU P H T,VANNIER V,et al. Catalytic oxidation of VOCs over mixed Co-Mn oxides[J]. Applied Catalysis B:Environmental,2012,117(3):125-134. [32] BECKER L,FORSTER H. Oxidative decomposition of benzene and its methyl derivatives catalyzed by copper and palladium ion-exchanged Y-type zeolites[J]. Applied Catalysis B:Environmental,1998,17(1/2):43-49. [33] ZAITAN H,MANERO M H,VALDES H. Application of high silica zeolite ZSM-5 in a hybrid treatment process based on sequential adsorption and ozonation for VOCs elimination[J]. Journal of Environmental Sciences,2016,41(3):59-68. [34] 张鹏. CuO-CeO2/Al2O3催化剂的制备及催化氧化甲苯和二甲苯的研究[D]. 哈尔滨:哈尔滨工业大学,2008. ZHANG P. Study on preparation and property of CuO-CeO2/Al2O3 catalyst in the catalytic oxidation of toluene and xylene[D]. Harbin:Harbin Institute of Technology,2008. [35] CASTAÑO M H,MOLINA R,MORENO S. Cooperative effect of the Co-Mn mixed oxides for the catalytic oxidation of VOCs:Influence of the synthesis method[J]. Applied Catalysis A:General,2015,492(29):48-59. [36] 孙敬方,葛成艳,姚小江,等. 固相浸渍法制备NiO/CeO2催化剂及其在CO氧化反应中的应用[J]. 物理化学学报,2013,29(11):2451-2458. SUN J F,GE C Y,YAO X J,et al. Preparation of NiO/CeO2 catalysts by solid state impregnation and their application in CO oxidation[J]. Journal of Physical Chemistry,2013,29(11):2451-2458. [37] YUAN G,MENG F,JI K,et al. Slurry phase methanation of carbon monoxide over nanosized Ni-Al2O3 catalysts prepared by microwave-assisted solution combustion[J]. Applied Catalysis A:General,2016,510:74-83. [38] 李朝晖,戴伟,傅吉全. 微乳液法制备纳米催化剂的应用研究进展[J]. 化工进展,2008,27(4):499-502. LI C H,DAI W,FU J Q. Advances in preparation of nano-catalyst by micro-emulsification[J]. Chemical Industry and Engineering Progress,2008,27(4):499-502. [39] JUNG S C,PARK Y K,JUNG H Y,et al. Effects of calcination and support on supported manganese catalysts for the catalytic oxidation of toluene as a model of VOCs[J]. Research on Chemical Intermediates,2015,42(1):1-15. [40] 赵志军. 延长蜂窝式催化剂的使用寿命[C]//全国电厂燃煤节能减排升级改造解决方案经验交流会,浙江,2015:181-186. ZHAO Z J. Extend the life of the honeycomb catalyst[C]//Experience of exchanging and improving the solution of energy-saving and emission-reduction of coal-fired power plant in China,Zhejiang,2015:181-186. [41] 李艳芳,刘夏丹,于宏. 旋转式四通换向阀在蓄热式燃烧系统中的应用[J]. 工业加热,2001(3):52-53. LI Y F,LIU X D,YU H. Application of revolving four-direction-connected valve in regenerative combustion system[J]. Industrial Heating,2001(3):52-53. [42] PENNINGTON R L,LISZEWSKI M. Get more from your regenerative thermal oxidizer[J]. Chemical Engineering,1999,106(5):137-142. [43] 萧琦,姜泽毅,张欣欣. 多室蓄热式有机废气焚烧炉工程应用研究[J]. 环境工程,2011,29(2):69-72. XIAO Q,JIANG Z Y,ZHANG X X. Engineering application research of multiple-chamber RTO[J]. Environmental Engineering,2011,29(2):69-72. [44] SALOMONS S,HAYES R E,POIRIER M,et al. Flow reversal reactor for the catalytic combustion of lean methane mixtures[J]. Catalysis Today,2003,83(1/2/3/4):59-69. [45] 刘慧,李亚冰,陈文仲. 蓄热式燃烧最佳换向时间的计算[J]. 东北大学学报(自然科学版),2012,33(2):243-246. LIU H,LI Y B,CHEN W Z. Calculation of best switching time of heat accumulating combustion[J]. Journal of Northeastern University(Natural Science),2012,33(2):243-246. [46] 张先珍,戴德彦. 换向时间对蓄热式燃烧的影响[J]. 冶金能源,2005,24(4):30-32. ZHANG X Z,DAI D Y. The switching time's effects on the regenerative combustion[J]. Energy for Metallurgical Industry,2005,24(4):30-32. [47] 张欣茹,姜泽毅,张欣欣,等. 新型档位蓄热器的开发与研究[J]. 工业加热,2005,34(5):26-28. ZHANG X R,JIANG Z Y,ZHANG X X,et al. Development and investigation on a new rotary-switching regenerator[J]. Industrial Heating,2005,34(5):26-28. [48] RAFIDI N,BLASIAK W. Heat transfer characteristics of HiTAC heating furnace using regenerative burners[J]. Applied Thermal Engineering,2006,26(16):2027-2034. [49] 张建军,冯自平,宋文吉,等. 连续式蓄热燃烧技术的研究[J]. 四川冶金,2010,32(6):19-24. ZHANG J J,FENG Z P,SONG W J,et al. Investigation of high temperature air combustion of self-regenerator[J]. Sichuan Metallurgy,2010,32(6):19-24. [50] 胡志伦,臧占稳. 煤矿乏风氧化装置加热启动系统的研究[J]. 科技与企业,2014(19):181-182. HU Z L,ZANG Z W. Research on heat-starting system for VAM oxidation equipment[J]. Science & Technology and Enterprises,2014(19):181-182. [51] 李冬梅,任伟娜,李圣强,等. 立式乏风氧化装置的开发与应用[J].能源与节能,2013(10):5-6. LI D M,REN W N,LI S Q,et al. Development and application of vertical vam oxidation device[J]. Energy and Energy Conservation,2013(10):5-6. [52] 李勇. 基于PLC的低浓度瓦斯预掺混输送监控系统的设计[J]. 山东工业技术,2015(9):58-58. LI Y. Design of monitoring and control system for low concentration gas pre mixing transportation based on PLC[J]. Shandong Industrial Technology,2015(9):58-58. [53] BARRESI A A,GIANCARLO BALDI A,FISSORE D. Forced unsteady-state reactors as efficient devices for integrated processes:case histories and new perspectives[J]. Industrial & Engineering Chemistry Research,2007,46(25):8693-8700. [54] 滕富华,顾震宇,项敏,等. 蓄热式热氧化炉处理医化废气[J]. 中国环保产业,2015(4):4-7. TENG F H,GU Z Y,XIANG M,et al. Medical and chemical exhaust gas treated by heat oxidation oven with heat-storage type[J]. China Environmental Protection Industry,2015(4):4-7. [55] 喻昌军. 蓄热式热氧化炉(RTO)处理医化废气的运行管理与优化[J]. 现代制造,2013(23):54-57. YU C J. Operation management and optimization of regenerative thermal oxidizer for treatment of medical waste gas[J]. Maschinen Markt,2013(23):54-57. [56] 简力,孙昆. 蓄热式氧化炉在处理SBS生产废气中的应用[J]. 节能技术,2014,32(2):185-189. JIAN L,SUN K. The application of regenerative thermal oxidizer in dealing with the waste gas in SBS production[J]. Energy Conservation Technology,2014,32(2):185-189. [57] 李海柱,贡祥磊,甘霖. 蓄热式氧化焚烧炉(RTO)在羧基丁苯胶乳生产线上的应用[J]. 山东化工,2013,42(9):90-92. LI H Z,GONG X L,GAN L. Application of regenerative thermal oxidizer in XSBRL production line[J]. Shandong Chemical Industry,2013,42(9):90-92. [58] 蔡鹏山,马晓驰,杨振华,等. 顺酐行业中蓄热式热氧化器的应用[J]. 化工机械,2013,40(5):676-678. CAI P S,MA X C,YANG Z H,et al. Application of regenerative thermal oxidizer in the maleic anhydride industry[J]. Chemical Engineering & Machinery,2013,40(5):676-678. [59] 王钢强. 蓄热催化氧化法在涂装烘房废气处理中的应用[J]. 中国环保产业,2015(8):16-18. WANG G Q. Application of regenerative catalytic oxidation in exhaust gas treatment of besmearing-baking house[J]. China Environmental Protection Industry,2015(8):16-18. [60] 陈义良,李汶冬,李继文,等. 蓄热催化氧化技术在处理丁苯橡胶尾气中的应用[J]. 化工科技,2015(1):59-62. CHEN Y L,LI W D,LI J W,et al. The application of catalytic oxidation in treating the exhaust gas for SBR production[J]. Science and Technology in Chemical Industry,2015(1):59-62. |
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