燃煤电厂电除尘PM10和PM2.5的排放控制I:电除尘选型及工业应用

王仕龙; 陈英; 韩平; 张国庆; 郑钦臻; 沈欣军; 李树然; 闫克平

doi:10.3981/j.issn.1000-7857.2014.33.002

科技导报 >

2014 , Vol. 32 >Issue 33: 23 - 33

DOI: https://doi.org/10.3981/j.issn.1000-7857.2014.33.002

专题论文

燃煤电厂电除尘PM₁₀和PM_2.5的排放控制I:电除尘选型及工业应用

王仕龙 ,
陈英 ,
韩平 ,
张国庆 ,
郑钦臻 ,
沈欣军 ,
李树然 ,
闫克平

展开

1. 神华国能集团有限公司, 北京 100033;
2. 天津大港发电厂, 天津 300272;
3. 浙江大学生物质化工教育部重点实验室, 杭州 310027

王仕龙, 高级工程师, 研究方向为燃煤电厂复合污染控制和管理, 电子信箱: wangshilong@shenhua.cc

收稿日期: 2014-07-17

修回日期: 2014-10-27

网络出版日期: 2014-12-05

基金资助

国家高技术研究发展计划(863计划)项目(2013AA065000);浙江省重点科技创新团队计划项目(2013TD07)

收起

PM₁₀ and PM_2.5 Emission Control by Electrostatic Precipitator (ESP) for Coal-fired Power Plants I: ESP Sizing and Applications

WANG Shilong ,
CHEN Ying ,
HAN Ping ,
ZHANG Guoqing ,
ZHENG Qinzhen ,
SHEN Xinjun ,
LI Shuran ,
YAN Keping

Expand

1. Shenhua Guoneng Energy Group Corporation Limited, Beijing 100033, China;
2. Tianjin Dagang Power Plant, Tianjin 300272, China;
3. Key Laboratory of Biomass Chemical Engineering of Ministry of Education, Zhejiang University, Hangzhou 310027, China

Received date: 2014-07-17

Revised date: 2014-10-27

Online published: 2014-12-05

Fold

摘要

针对电除尘细颗粒物(PM_2.5)排放控制,提出利用电除尘指数指导电除尘本体和电源设计选型技术的原理和方法,并介绍电除尘改造的应用案例.通过优化电除尘指数、采用三相高压电源开展电除尘改造和选型.通过电除尘和脱硫塔除雾器的同步改造,可以实现烟囱出口颗粒物排放浓度低于5 mg/m³,同时,PM_2.5 (直径2.5 μm 以下的颗粒物)排放浓度低于2.5 mg/m³.示范工程还表明当电除尘器出口PM₁₀(直径10 μm 以下的颗粒物)排放在6~30 mg/m³时,PM_2.5占PM₁₀比例为6%至20%;当PM₁₀排放在5~15 mg/m³时,PM_2.5排放可低于2.5 mg/m³.

关键词： 电除尘; 细颗粒物; 电除尘指数; 三相电源

本文引用格式

王仕龙 , 陈英 , 韩平 , 张国庆 , 郑钦臻 , 沈欣军 , 李树然 , 闫克平 . 燃煤电厂电除尘PM₁₀和PM_2.5的排放控制I:电除尘选型及工业应用[J]. 科技导报, 2014 , 32(33) : 23 -33 . DOI: 10.3981/j.issn.1000-7857.2014.33.002

Abstract

This paper discusses electrostatic precipitation for fine particle emission control. According to the so-called electrostatic precipitator (ESP) index, a novel ESP sizing method is presented for both mechanical and electrical specifications. By using threephase rectifier transformer power sources, ESPs give very high collection for fine particle emission control. The ratio of PM_2.5 over PM₁₀ is between 6% and 20%. When PM₁₀ emission is around 5-15 mg/m³, PM_2.5 is below 2.5 mg/m³. By upgrading ESP and flue gas desulfurization (FGD), particle emissions can be reduced to below 5 mg/m³, and PM_2.5 below 2.5 mg/m³.

Key words： electrostatic precipitation; PM_2.5; electrostatic precipitator index; three-phase T/R power source

参考文献

[1] 郝吉明, 段雷, 易红宏, 等. 燃烧源可吸入颗粒物的物理化学特征[M].北京: 科学出版社, 2008.Hao Jiming, Duan Lei, Yi Honghong, et al. Physical and chemicalcharacteristics of particulate matter from combustion source[M]. Beijing:Science Press, 2008.
[2] 徐明厚, 于敦喜, 刘小伟. 燃煤可吸入颗粒物的形成与排放[M]. 北京:科学出版社, 2009.Xu Minghou, Yu Dunxi, Liu Xiaowei. Formation and emission ofparticulate matter from coal combustion[M]. Beijing: Science Press,2009.
[3] White H J. Industrial electrostatic precipitation[M]. Boston: AddisonWesley, 1963.
[4] Oglesby S. Electrostatic precipitation[M]. New York: Marcel DekkerINC Press, 1978.
[5] Parker K R. Applied electrostatic precipitation[M]. London: BlackieAcademic & Professional, 1997.
[6] 陈国榘. 适应新排放标准的火电厂除尘技术[J]. 科技导报, 2010, 28(3): 90-95.Chen Guoqu. Dust control technologies under the new emissionstandard for thermal power plants[J]. Science & Technology Review,2010, 28(3): 90-95.
[7] 郦建国, 刘云. 中国煤种成分对电除尘器性能影响及电除尘器适应性评价[J]. 科技导报, 2010, 28(7): 104-109.Li Jianguo, Liu Yun. The effect of compositions of domestic coal on theperformance of ESP and an evaluation of ESP adaptability[J]. Science& Technology Review, 2010, 28(7): 104-109.
[8] 中国环境保护产业协会电除尘委员会. 电除尘器选型设计指导书[M].北京: 中国电力出版社, 2013.Committee of Electrical Dust Removal, CAEPI. Guide book of ESPdesign[M]. Beijing: China Electric Power Press, 2013.
[9] 易红宏, 郝吉明, 段雷, 等. 电厂除尘设施对PM₁₀排放特征影响研究[J]. 环境科学, 2006, 27(10): 1921-1927.Yi Honghong, Hao Jiming, Duan Lei, et al. Influence of dust catcherson PM₁₀ emission characteristics of power plants[J]. EnvironmentalScience, 2006, 27(10): 1921-1927.
[10] Mizuno A. Electrostatic precipitation[J]. Dielectrics and ElectricalInsulation, IEEE Transactions on, 2000, 7(5): 615-624.
[11] Nielsen M T, Livbjerg H, Fogh C L, et al. Formation and emission offine particles from two coal-fired power plants[J]. Combustion Scienceand Technology, 2002, 174(2): 79-113.
[12] PorleK, Francis S L, Bradburn K M. Electrostatic precipitators forindustrial applications[C]. Brussels-Belgium: REHVA, COSTG3, 2006
[13] Meij R, TeWinkel B H. The emissions and environmental impact ofPM₁₀ and trace elements from a modern coal- fired power plantequipped with ESP and wetFGD[J]. Fuel Processing Technology, 2004,85(6/7): 643-658.
[14] Lighty J A S, Veranth J M, Sarofim A F. Combustion aerosols: Factorsgoverning their size and composition and implications to human health[J]. Journal of the Air & Waste Management Association, 2000, 50(9):1565-1618.
[15] Adgate J L, Mongin S J, Pratt G C, et al. Relationships between personal,indoor, and outdoor exposures to trace elements in PM_2.5[J]. Science ofthe Total Environment, 2007, 386(1): 21-32.
[16] Niewulis A, Podliński J, Mizeraczyk J. Electrohydrodynamic flow patternsin a narrow electrostatic precipitator with longitudinal or transversewire electrode[J]. Journal of Electrostatics, 2009, 67(2): 123-127.
[17] 曾宇翾, 沈欣军, 章旭明, 等. 电除尘器中离子风的实验研究[J]. 浙江大学学报: 工学版, 2013, 47(12): 2208-2211.Zeng Yuxuan, Shen Xinjun, Zhang Xuming, et al. Experimental studyof ionic wind in an electrostatic precipitator[J]. Journal of ZhejiangUniversity: Engineering Science, 2013, 47(12): 2208-2211.
[18] Crynack R, Truce R, Harrison W. Indigo particle agglomerators reducemass and visible emission on coal fired boilers in the US[C]. 10thInternational Conference for Electrostatic Precipitation, Cairns,Australia, June 25-29, 2006.
[19] 唐敏康, 周跃. 电除尘器中粉尘粒子的凝并[J]. 科技导报, 2007, 25(19): 23-25.Tang Minkang, Zhou Yue. Agglomeration of dust particle inelectrostatic precipitator[J]. Science & Technology Review, 2007, 25(19): 23-25.
[20] Zhu J, Zhang X, Chen W, et al. Electrostatic precipitation of fine particleswith a bipolar pre-charger[J]. Journal of Electrostatics, 2010, 68(2):174-178.
[21] Bayless D J, Alam M K, Radcliff R, et al. Membrane- based wetelectrostatic precipitation[J]. Fuel Processing Technology, 2004, 85(6):781-798.
[22] Poulsen K S, Lund C R. Reduction of fine particulate emission fromESPs[C]. 10th International Conference for Electrostatic Precipitation,Cairns, Australia, June 25-29, 2006.
[23] 党小庆, 任燕, 马广大, 等. 电除尘器电场数值计算与性能预测的实验研究[J]. 科技导报, 2007, 20(7): 36-42.Dang Xiaoqing, Ren Yan, Ma Guangda, et al. Experimental study andnumerical calculation on the performance of electrostatic precipitators[J]. Science & Technology Review, 2007, 20(7): 36-42.
[24] Misaka T, Mochizuki Y. Recent application and running cost ofmoving electrode type electrostatic precipitator[M]. Springer BerlinHeidelberg: Electrostatic Precipitation, 2009: 518-522.
[25] Zhu J, Zhao Q, Yao Y, et al. Effects of high-voltage power sources onfine particle collection efficiency with an industrial electrostaticprecipitator[J]. Journal of Electrostatics, 2012, 70(3): 285-291.
[26] Zhang B, Wang R, Yan K. Industrial applications of three-phase T/Rfor upgrading ESP performance[C]//Electrostatic Precipitation, 11thInternational Conference on Electrostatic Precipitation. Hangzhou:Jointly Published with Zhejiang University Press, 2009.
[27] 马晋辉, 王荣华, 闫克平. 燃煤电厂电除尘器的节能和提效[J]. 电力环境保护, 2008, 24(6): 33-35.Ma Jinhui, Wang Ronghua, Yan Keping. Energy-saving measures ofelectrostatic precipitator in coal-fired power plants[J]. Electric PowerEnvironmental Protection, 2008, 24(6): 33-35.
[28] Zukeran A, Looy P C, Chakrabarti A, et al. Collection efficiency ofultrafine particles by an electrostatic precipitator under DC and pulseoperating modes[J]. Industry Applications, IEEE Transactions on,1999, 35(5): 1184-1191.
[29] Du C, Yang Y, Wang J, et al. Evaluation of ESP performance via itsindexvalue[J]. International Journal of Plasma Environment Scienceand Technology, 2014. (in Press)
[30] Marquard A, Meyer J, Kasper G. Characterization of unipolar electricalaerosol chargers—Part I: A review of charger performance criteria[J].Journal of Aerosol Science, 2006, 37(9): 1052-1068.
[31] 朱继保, 章旭明, 胡行伟, 等. 电除尘器电极结构与灰堆积特性相关性研究[J]. 科技导报, 2008, 26(9): 30-33.Zhu Jibao, Zhang Xuming, Hu Hangwei, et al. Characteristics ofcollected dust layer in a laboratory electrostatic precipitator[J].Science & Technology Review, 2008, 26(9): 30-33.
[32] 杨勇, 张瑞英, 孙喜娟, 等. 影响电除尘器总体设计主要因素的分析研究[J]. 科技导报, 2007, 19(7): 29-35.Yang Yong, Zhang Ruiying, Sun Xijuan, et al. Study on the mainfactors related to integrated design of electrostatic precipitator[J].Science & Technology Review, 2007, 19(7): 29-35.
[33] Podliński J, Dekowski J, Mizeraczyk J, et al. Electro-hydrodynamicgas flow in a positive polarity wire-plate electrostatic precipitator andthe related dust particle collection efficiency[J]. Journal of Electrostatics,2006, 64: 259-262.
[34] Grass N, Hartmann W, Klockner M. Application of different types ofhigh- voltage supplies on industrial electrostatic precipitators[J].Industry Applications, IEEE Transactions on, 2004, 40(6): 1513-1520.
[35] Li X, Zhang X, Zhu J, et al. Sensitivity analysis on the maximum ashresistivity in terms of its compositions and gaseous water concentration[J]. Journal of Electrostatics, 2012, 70(1): 83-90.
[36] Zhuang Y, Jin Kim Y, Gyu Lee T, et al. Experimental and theoreticalstudies of ultra-fine particle behavior in electrostatic precipitators[J].Journal of Electrostatics, 2000, 48(3): 245-260.
[37] Huang S H, Chen C C. Ultrafine aerosol penetration through electrostaticprecipitators[J]. Environmental Science & Technology, 2002, 36(21):4625-4632.
[38] 金华市中荷环保科技有限公司. 中荷环保简介[EB/OL]. (2014-07-05). http://www.zhhb.cn/.Jinhua Zhonghe Elec Co, Ltd. Brief mtroduction of Zhonghe Elec Co,Ltd. [EB/OL]. (2014-07-05). http://www.zhhb.cn/.
[39] 西安热工研究院有限公司. 电除尘器可行性研究报告[R]. 西安: 西安热工研究院有限公司, 2013.Xi'an Thermal Power Research Institute Co, Ltd. Report of ESPfeasibility[R]. Xi'an: Xi'an Thermal Power Research Institute Co, Ltd,2013.

Options

文章导航

摘要

本文引用格式

Abstract

参考文献

联系我们

访问统计

模态框（Modal）标题

摘要

本文引用格式

Abstract

参考文献

联系我们

访问统计