燃煤电厂除尘设备超低排放改造性能评价
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摘要
新的环保政策要求燃煤电厂烟尘排放浓度低于5 mg/Nm~3以达到超低排放标准,为达到标准要求,黑龙江某燃煤电厂对其2、3号机组采用不同路线进行超低排放改造,对不同改造路线进行系统研究,分析各改造路线技术原理及特点,并对改造后设备进行性能试验,试验结果表明,2号机组改造烟尘排放浓度为3.46 mg/Nm~3,3号机组改造后烟尘排放浓度为3.85 mg/Nm~3,两种改造路线均可达到5 mg/Nm~3的排放限值要求,且设备运行可靠稳定。
The new environmental policy requires emission concentrations below 5 mg/Nm~3 to meet ultra-low emission standards. In order to reach the new standards, a coal-fired power plant in Heilongjiang province conducted the ultra low emission retrofit on its unit 2 and unit 3 in separate ways. The principle and characteristics of main retrofit technology are studied and analyzed in this paper, and the retrofited equipment performance test is conducted. The test results show that the dust emission concentration of unit 2 is 3.46 mg/Nm~3, while the dust emission concentration of unit 3 is 3.85 mg/Nm~3. Both of the retrofit routes can meet the emission limit of 5 mg/Nm~3, and the equipment runs stably and reliably.
The new environmental policy requires emission concentrations below 5 mg/Nm~3 to meet ultra-low emission standards. In order to reach the new standards, a coal-fired power plant in Heilongjiang province conducted the ultra low emission retrofit on its unit 2 and unit 3 in separate ways. The principle and characteristics of main retrofit technology are studied and analyzed in this paper, and the retrofited equipment performance test is conducted. The test results show that the dust emission concentration of unit 2 is 3.46 mg/Nm~3, while the dust emission concentration of unit 3 is 3.85 mg/Nm~3. Both of the retrofit routes can meet the emission limit of 5 mg/Nm~3, and the equipment runs stably and reliably.
引文
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[2]中国电力企业联合会.中国电力行业年度发展报告[M].北京:中国电力出版社,2014.
[3]胡永锋.燃煤电厂烟尘超低排放改造方案对比分析[J].华电技术,2015,37(12):55-58.
[4]章志昕,叶青,来佳磊.高频电源在静电除尘器上的应用[J].浙江电力,2016,35(1):57-60.
[5]孙虹,华伟,祁建民,等.火电厂电除尘用高频高压电源的研究[J].现代电子技术,2015,38(2):149-151.
[6]王健新.电除尘用直流叠加脉冲电源设计[D].大连:大连理工大学,2016.
[7]夏力伟,张学锁,梁会友,等.脱硫协同除尘技术在大型火电机组中的应用研究[J].中国高新技术企业,2016(12):83-85.
[8]鲍天恩.脱硫除尘一体化超低排放改造方案研究[D].保定:华北电力大学,2016.
[9]曹宾.高效除雾器使用研究[J].科技与创新,2014(18):14.
[10]王东歌.燃煤电厂湿式电除尘器研究与工程实践[D].南京:南京信息工程大学,2016.
[11]陈馨.径流湿式静电除尘器在大型供热机组中的应用[J].中国标准导报,2016(1):74-78.
[12]华建平.燃煤电厂湿式电除尘器应用情况介绍及建议[J].中国环保产业,2014(9):27-30.
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