Energy Saving and Carbon Reduction Analysis of Electrostatic Precipitator Under Double Carbon Background

doi:10.12096/j.2096-4528.pgt.21063

Abstract

Abstract:

Energy conservation and efficiency improvement under the dual carbon background is the first choice for coal-fired power plants to reduce carbon. The energy efficiency parameters of dry electrostatic precipitator (ESP), wet electrostatic precipitator (WESP), auxiliary equipment and dust removal technology route before and after ultra-low emission transformation were analyzed and evaluated, which could excavate their energy saving and carbon reduction space. Before the transformation of ultra-low emission, the annual CO₂ emissions corresponding to the high voltage power consumption of 300 MW, 600 MW and 1000 MW units supporting dry ESP are about 6 000 t, 9 000 t and 14 000 t respectively. In addition, the better the performance of ESP, the higher the corresponding energy consumption and CO₂ emission. After the ultra-low emission transformation, the annual CO₂ emission corresponding to the high-voltage power supply power consumption of the 1000 MW unit supporting the ESP is about 18 000 t, which increases by about 20% compared with that before the transformation, but could be reduced by about 60% through the energy saving optimization. The annual CO₂ emissions corresponding to the high-voltage power supply power consumption of the 300 MW, 600 MW and 1000 MW units supporting the WESP are about 2 000 t, 2500 t and 3400 t, respectively. The low temperature economizer of 630 MW unit could reduce the annual CO₂ emission by about 19000 t, and the phase change condenser of 280 t/h furnace could reduce the annual CO₂ emission by about 8 000 t. Compared with the WESP removal technology route, the flue gas cooperative treatment technology route of 660 MW unit with low-low temperature ESP removal technology as the core could reduce the annual CO₂ emission by about 3 000 t. This paper could provide technical ideas for the carbon emission reduction of subsequent coal-fired power plants.

Key words: coal-fired power, ultra-low emission, power consumption, CO₂ emission reduction, carbon peak, carbon neutral

CLC Number:

TK 09

Hanxiao LIU. Energy Saving and Carbon Reduction Analysis of Electrostatic Precipitator Under Double Carbon Background[J]. Power Generation Technology, 2023, 44(5): 738-744.

Figures/Tables 9

Fig. 1 Calorific value and CO2 emission coefficient of different kinds of coal

Fig. 2 Power consumption of high-voltage power supply of ESP before ultra-low emission renovation

Fig. 3 CO2 emission data of ESP before ultra-low emission renovation

Fig. 4 Energy efficiency parameters of an electric precipitator for a 300 MW unit

Fig. 5 Power consumption of high-voltage power supply and the corresponding CO2 emission data of ESP after ultra-low emission renovation

Fig. 6 Power consumption of high-voltage power supply and the corresponding CO2 emission data of ESP under different electric control modes

Fig. 7 High-voltage power supply power consumption of WESP

Fig. 8 Corresponding CO2 emission data of WESP

Fig. 9 Energy efficiency data of low temperature economizer

References 21

1	United Nations Climate Change ．What is the United Nations framework convention on climate change？[EB/OL]．(2012-06-18)[2022-10-18]．． doi:10.4324/9780203888469-65
2	JOUZEL J， MASSON D， VCATTANI V O，et al ．Orbital and millennial antarctic climate variability over the past 800 000 years[J]．Science，2007，317：793-796． doi:10.1126/science.1141038
3	LU T D， FLOCH L E， BEREITER M B，et al ．High resolution carbon dioxide concentration record 650 000-800 000 years before present[J]．Nature，2008，453：379-382． doi:10.1038/nature06949
4	IPCC ．Special report on global warming of 1.5 ℃[M]．UK：Cambridge University Press，2018．
5	LIU Q， ZHENG X Q， ZHAO X C，et al ．Carbon emission scenarios of China’s power sector：impact of controlling measures and carbon pricing mechanism[J]．Advances in Climate Change Research，2018，9(1)：27-33． doi:10.1016/j.accre.2018.01.002
6	蔡博峰，李琦，林千果，等．中国二氧化碳捕集、利用与封存(CCUS)报告(2019)[R]．北京：生态环境部环境规划院气候变化与环境政策研究中心，2020．
	CAI B F， LI Q， LIN Q G，et al ．China carbon dioxide capture， utilization and storage (CCUS) report (2019)[R]．Beijing：Research Center for Climate Change and Environmental Policy，Institute of Environmental Planning，Ministry of Ecology and Environment，2020．
7	谢克昌．节能提效才是减碳第一优选[N]．中国能源报，2021-05-17(1)． doi:10.1002/fes3.324
	XIE K C ．Energy saving and efficiency is the first choice for carbon reduction[N]．China Energy News，2021-05-17(1)． doi:10.1002/fes3.324
8	朱法华，许月阳，孙尊强，等．中国燃煤电厂超低排放和节能改造的实践与启示[J]．中国电力，2021，54(4)：1-8．
	ZHU F H， XU Y Y， SUN Z Q，et al ． Practice and enlightenment of ultra-low emission and energy-saving retrofit of coal-fired power plants in China[J]．Electric Power，2021，54(4)：1-8．
9	王赵国，张超，李东阳，等．燃煤电厂超低排放除尘系统节能优化试验[J]．热力发电，2018，47(3)： 109-114． doi:10.19666/j.rlfd.201709099
	WANG Z G， ZHANG C， LI D Y，et al ． Experiment of energy saving and optimization on electrostatic precipitator system in ultra-low emission coal-fired power plants[J]．Thermal Power Generation，2018， 47(3)：109-114． doi:10.19666/j.rlfd.201709099
10	彭宇泉．浅谈电除尘节能技术的应用[J]．再生资源与循环经济，2016，9(4)：42-44． doi:10.3969/j.issn.1674-0912.2016.04.014
	PENG Y Q ．Application of energy-saving technology in electro-static precipitator[J]．Recyclable Resources and Circular Economy，2016，9(4)：42-44． doi:10.3969/j.issn.1674-0912.2016.04.014
11	刘含笑，郦建国，姚宇平，等．低低温电除尘系统对SO₃脱除性能研究[J]．发电技术，2022，43(1)：147-154． doi:10.12096/j.2096-4528.pgt.19115
	LIU H X， LI J G， YAO Y P，et al ．Study on SO₃ removal performance of low-low temperature electrostatic precipitator system[J]．Power Generation Technology，2022，43(1)：147-154． doi:10.12096/j.2096-4528.pgt.19115
12	刘含笑，郦建国，姚宇平，等．燃煤电厂电除尘器能效评测[J]．中国电力，2017，50(11)：22-27． doi:10.11930/j.issn.1004-9649.201703014
	LIU H X， LI J G， YAO Y P，et al ．The energy efficiency evaluation of electrostatic precipitator in coal-fired power plant[J]．Electric Power，2017，50(11)：22-27． doi:10.11930/j.issn.1004-9649.201703014
13	李文华，白亮，虞上长．电除尘器流场、颗粒场及电场的数值模拟研究[J]．发电技术，2021，42(3)：336-342． doi:10.12096/j.2096-4528.pgt.19083
	LI W H， BAI L， YU S C ．Numerical simulation of flow field， particle field and electric field for ESP[J]．Power Generation Technology，2021，42(3)：336-342． doi:10.12096/j.2096-4528.pgt.19083
14	侯贵光，吴舜泽，徐毅，等．能源结构与CO₂排放的定量关联机制研究[J]．环境污染与防治，2015，37(3)：16-21． doi:10.15985/j.cnki.1001-3865.2015.03.005
	HOU G G， WU S Z， XU Y，et al ．Quantitative investigation on correlative mechanism between energy structure and CO₂ emission[J]．Environmental Pollution and Prevention，2015，37(3)：16-21． doi:10.15985/j.cnki.1001-3865.2015.03.005
15	中华人民共和国国家质量监督检验检疫总局．电除尘器性能测试方法： [S]．北京：中国标准出版社，2017．
	General Administration of Quality Supervision， Inspection and Quarantine of the People’s Republic of China ． Test method for performance of electrostatic precipitator： [S]．Beijing：China Standard Press，2017．
16	刘玺璞，李启永，李东阳，等．330 MW燃煤发电机组除尘系统节能优化[J]. 中国电力， 2019，52(5)：164-175．
	LIU X P， LI Q Y， LI D Y，et al ．Energy-saving optimization on the dust collection system of a 330 MW power plant[J]．Electric Power，2019，52(5)：164-175．
17	寿志毅，刘含笑，陈招妹，等. 湿式电除尘器排放特征及高效能指标研究[J]．广东电力，2019，32(3)：17-24． doi:10.3969/j.issn.1007-290X.2019.003.003
	SHOU Z Y， LIU H X， CHEN Z M，et al ．Study investigation on emission characteristics of WESP and evaluation of high efficiency WESP[J]．Guangdong Electric Power，2019，32(3)：17-24． doi:10.3969/j.issn.1007-290X.2019.003.003
18	TAN H Z， XIONG Y Y， WANG Y B，et al ．Study on synergistic removal of multi-pollutants by WPTA[J]. Electric Power，2017，50(2)：128-134．
19	TAN H， WANG Y， CAO R，et al ．Development of wet phase transition agglomerator for multi-pollutant synergistic removal[J]．Applied Thermal Engineering，2017，130：1208-1214． doi:10.1016/j.applthermaleng.2017.11.112
20	中国环境保护产业协会电除尘委员会．燃煤电厂烟气超低排放技术[M]．北京：中国电力出版社，2015．
	Electric Precipitator Committee of China Environmental Protection Industry Association ．Technology of flue gas ultra-low emission for coal-fired power plant[M]．Beijing：China Electric Power Press，2015．
21	郦建国，郦祝海，李卫东，等．燃煤电厂烟气协同治理技术路线研究[J] ．中国环保产业，2015(5)：52-56． doi:10.3969/j.issn.1006-5377.2015.05.014
	LI J G， LI Z H， LI W D，et al ．Research on flue gas co-benefit control technical route in coal-fired power plants[J]．China Environmental Protection Industry，2015(5)：52-56． doi:10.3969/j.issn.1006-5377.2015.05.014

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