交变电场粒子荷电凝并实验研究
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摘要
中国是以煤炭为主的能源生产大国和消费大国,是典型煤炭型污染国家,烟尘污染是制约中国可持续发展战略实施的重大问题之一。目前,电除尘技术的理论尚不完备,电除尘器还存在体积大、投资高、捕集微细烟尘的效率较低等问题。为提高除尘器的性能,实现预荷电装置的小型化,本课题结合国家自然科学基金重点资助项目国家自然科学基金资助项目“离子在高气压强电场中运动规律及其应用的基础研究”(60471036)和国家自然科学基金资助项目“电收尘器的交变强电场离子荷电凝聚研究”(50578020),采用直流高电压负电晕放电,进行了烟道中离子浓度变化规律实验,并利用电凝并方法在电除尘器烟道中增加预荷电装置,进行了交变电场荷电凝并实验研究。实验结果如下:
(1) 气流速度越大输运出的离子越多,烟道中气流速度是除尘电场中的10倍左右,将预荷电装置安装于烟道中,离子浓度比除尘电场中高约一个数量级,有利于提高粉尘的荷电量,增强带电粒子的凝并作用。
(2) 交变电场比直流电场更利于带电粒子凝并,电场频率为40Hz时效果最佳。
(3) 电凝并作用使粒子粒径增大21%左右,安装预荷电装置后,总除尘效率提高了2.6-3.5%。
这个结果说明在烟道中安装预荷电装置可以增大粉尘的粒径,提高电除尘器的除尘效率。同时烟道中的预荷电装置比普通的预荷电装置体积小,且不用额外增加电除尘器的体积,有利于进一步实现电除尘器的小型化。
At present, the theoretics of electrostatic precipitation is imperfect. There are some problems about the existing electrostatic precipitator, such as large volume, high cost and low efficiency of micro-size soot collecting. To improve the technical performance of electrostatic precipitator, achieve the miniaturization of pre-charge equipment, pre-charge equipment is installed in the soot channel of electrostatic precipitator, charge and conglomeration experiments in AC electric-field are conducted. The results of the experiments are as follow:
(1)Ionic concentration can be enhanced through increasing rate of gas flow. So adding a pre-charge facility in soot channel can increase ionic concentration to be about 1 order of magnitude greater than it is in the field of electrostatic precipitation. (2)The process of particle agglomeration is strengthened by a high voltage AC electric field after the pre-charge facility. Results show that the facility can has good effect on soot charge and agglomeration; best effect can be obtained when the frequency of AC electric field is 40Hz.
(3)The pre-charge facility is propitious to improve the technology performance of electrostatic precipitator. After the pre-charge facility is installed, the particle diameter and the efficiency of electrostatic precipitator have been increased 21%, 2.6-3.5%, respectively.
The results show that both particle diameter and efficiency of electrostatic precipitator can be enhanced by installing pre-charge facility in soot channel. At the same time, it is also beneficial to realize the miniaturization of electrostatic precipitator, for the volume of pre-charge facility in soot channel is small than that of normal one, it needn't additional extra increase the volume of the electrostatic precipitator.
(1) 气流速度越大输运出的离子越多,烟道中气流速度是除尘电场中的10倍左右,将预荷电装置安装于烟道中,离子浓度比除尘电场中高约一个数量级,有利于提高粉尘的荷电量,增强带电粒子的凝并作用。
(2) 交变电场比直流电场更利于带电粒子凝并,电场频率为40Hz时效果最佳。
(3) 电凝并作用使粒子粒径增大21%左右,安装预荷电装置后,总除尘效率提高了2.6-3.5%。
这个结果说明在烟道中安装预荷电装置可以增大粉尘的粒径,提高电除尘器的除尘效率。同时烟道中的预荷电装置比普通的预荷电装置体积小,且不用额外增加电除尘器的体积,有利于进一步实现电除尘器的小型化。
At present, the theoretics of electrostatic precipitation is imperfect. There are some problems about the existing electrostatic precipitator, such as large volume, high cost and low efficiency of micro-size soot collecting. To improve the technical performance of electrostatic precipitator, achieve the miniaturization of pre-charge equipment, pre-charge equipment is installed in the soot channel of electrostatic precipitator, charge and conglomeration experiments in AC electric-field are conducted. The results of the experiments are as follow:
(1)Ionic concentration can be enhanced through increasing rate of gas flow. So adding a pre-charge facility in soot channel can increase ionic concentration to be about 1 order of magnitude greater than it is in the field of electrostatic precipitation. (2)The process of particle agglomeration is strengthened by a high voltage AC electric field after the pre-charge facility. Results show that the facility can has good effect on soot charge and agglomeration; best effect can be obtained when the frequency of AC electric field is 40Hz.
(3)The pre-charge facility is propitious to improve the technology performance of electrostatic precipitator. After the pre-charge facility is installed, the particle diameter and the efficiency of electrostatic precipitator have been increased 21%, 2.6-3.5%, respectively.
The results show that both particle diameter and efficiency of electrostatic precipitator can be enhanced by installing pre-charge facility in soot channel. At the same time, it is also beneficial to realize the miniaturization of electrostatic precipitator, for the volume of pre-charge facility in soot channel is small than that of normal one, it needn't additional extra increase the volume of the electrostatic precipitator.
引文
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[32] 白希尧,张芝涛,白敏冬等.非平衡等离子体化学研究现状与展望.科学通报,2002,47(5):321-322.
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[43] 许德玄.静电除尘荷电的研究.环境工程,1997,15(6):25-27.
[44] 白希尧,朱克明.预荷电宽极距静电收尘器应用的研究.工业安全与防尘,1990,(6):6-11.
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[2] 原永涛,林国鑫,宣伟桥等.火力发电厂电除尘技术.北京:化学工业出版社,2004.
[3] 中国国家环境保护总局.火电厂大气污染排放标准 GB13223-2003,2003.
[4] 谭天佑,梁凤珍.工业通风除尘技术.北京:中国建筑工业出版社,1993.
[5] Kanazawa S, Ohkubo T. Submicron particle agglomeration and precipitation by using a bipolar charging method. Electrostatics, 1993,27:193-209.
[6] Watanabe T, Suda T. Submicron Size Carbonic Particle Agglomeration by An Electrostatic Agglomeration Apparatus. Proceedings of the Third International Aerosol Conference. Vol. 2, Kyoto, Japan, 1990:749-752.
[7] Laitinen A, Hautanen J, Keskinen J. Bipolar Charged Aerosol Agglomeration with Alternating Electric Field in Laminar Gasflow. Electrostatics, 1996,38:303-315.
[8] 向晓东.现代除尘理论与技术.北京:冶金工业出版社,2004.
[9] J. Kildeso, V.K. Bhatia, L. Lind, E. Johnson and A. Johansen, An experimental investigation for agglomeration of aerosols in alternating electric fields. Aerosol Science and Technology, 1995, 22: 422-430.
[10] 唐国山,唐复磊.水泥厂电除尘器应用技术.北京:化学工业出版社,2005.
[11] 中钢集团武汉安全环保研究所.泛比电阻电除尘器及除尘方法.中华人民共和国,B03C3/04,B03C 3/40,CN:200410013277,2005.
[12] 陈旺生,党太升,邹霖等.泛比电阻电除尘器伏安特性的理论及实验研究.环境科学与技术,2005,28(6):25-27.
[13] 陈旺生,郭俊一,向晓东,黄三明.泛比电阻电除尘器收尘性能实验研究.环境污染与防治,2006,28(12):899-900.
[14] Toshiaki Misaka, Akio Akasaka, Hiroaki Yabuta. Resent Applications of Moving Electrode Type Electrostatic Precipitator. Proceedings of The 7th international conference on Electrostatic Precipitation, 1998,9.
[15] 沈建勇.静电除尘器供电控制方式探讨.电站辅机,2003,(9):31-32.
[16] 贝子洪.电除尘器存在的问题及对策.湖北电力,2003,(10):39-40.
[17] 张干周.燃气轮机进气静电除尘系统.国际电力,2004,(1):38.
[18] 何立波,王显龙贾明生.影响静电除尘器效率的控制因素.中国电力,2004,37(1):74-76.
[19] 闫博.静电除尘高压供电设备控制器的开发.北京工业大学学报,2005,31(1):25-28.
[20] 阪本清等.净化烧结高比电阻烟尘电收尘器研究.环境工程,1992,9(3):16-20.
[21] 王海宁,阮金良,余汉民.电除尘器脉冲供电电源及其应用研究.电力环境保护,2001,17(1):13-15
[22] 张谷勋,蒋云峰.电除尘器电源的发展方向—高频化和数字化.电源世界,2007,(1):1-4.
[23] Victor Reyes, Carsten R. Lund. Full Scale Test with Switch Mode Power Supplies on Electrostatic Precipitation. Proceedings of the 8th international conference on Electrostatic Precipitation, 2001, 5.
[24] Huang Sarming. An Approach to the Precharge Technology Used for Electrostatic Precipitators. Proceedings of the 4th International Conference On Electrostatic Precipitator, Beijing, 1990, 9.
[25] 林宏.电—袋收尘器的开发和应用.中国水泥,2003,8:24-27
[26] 张晓朝等.电除尘技术研究与发展方向探讨.第10届全国电除尘会议/第2届全国脱硫学术会议论文集,广州,2003:158-163.
[27] 鲁景,李多松.声波清灰技术的原理及其应用.工业安全与环保,2007,33(1):14-15.
[28] 王显龙,何立波,贾明生,陈恩鉴.静电除尘器的新应用及其发展方向.工业安全与环保,2003,29(11):3-6.
[29] 白希尧,白敏冬,杨波等.强电场中离子运动规律及应用基础研究进展.中国基础科学,2004,6(4):23-27.
[30] 张芝涛,鲜于泽,许波等.强电离放电研究.东北大学学报,2002,23(5):507-510.
[31] 白敏药,谷建龙,张芝涛等.高气压强电场电离过程中的离子浓度分布规律,核聚变与等离子体物理,2005,25(3):218-222.
[32] 白希尧,张芝涛,白敏冬等.非平衡等离子体化学研究现状与展望.科学通报,2002,47(5):321-322.
[33] 白希尧,张芝涛,白敏冬.高气压强电场电离放电等离子体学科的形成与应用展望.自然杂志,2000,23(3):56-161.
[34] 胡传鼎.通风除尘设备设计手册.北京:化学工业出版社,2003
[35] E A Eilimonova, R H Amirov, H T kim, et al. Comparative modeling of NO_x and SO_2 removal from pollutant gases using pulsed-corona and silent discharges. J Phys D: App phys, 2000,33:1716-1727.
[36] 白敏药,杨波,周建纲等.大气压下电晕电离层离子运动规律实验研究.核聚变与等离子体物理,2005,25(4):311-314.
[37] Fuchs N A. Mechanics of Aerosol. New York: Pergamon Press, 1964.
[38] Eliasson B et al. Coagulation of bipolarly charged aerosols in a stack coagulator. J Aerosol Sci. 1987,18: 869-872
[39] Willams M M R, Loyalka S K. Aerosol science theory and practice. New York: Pergamon Press, 1991.
[40] Kauppinen E I et al. Electrical combustion aerosol agglomeration. J. Aerosol Sci. 1993, 24: 1-12.
[41] Masuda S, Nonogaki Y. Detection of Back Discharge in Electrostatic Precipitators. Conf. Record of IEE/IAS Annual Meeting, 1980: 912-917.
[42] 与川慎太郎,(?)岛忠,田中修.荷电电器集麈装置性能向上.静电气学会志.1990,14(6):459-466.
[43] 许德玄.静电除尘荷电的研究.环境工程,1997,15(6):25-27.
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