Near-Zero Air Pollutant Emission Technologies and Applications for Clean Coal-Fired Power

Cen, 2015, Progress and prospects on clean coal technology for power generation, Chin J Eng Sci, 17, 49 National Bureau of Statistics. [China energy statistical yearbook 2018]. Beijing: China Statistics Press; 2019. Chinese. [Basic statistics of China electric power 2018] [Internet]. Beijing: China Electricity Council; 2019 Jan 19 [cited 2019 Jun 18]. Available from: http://www.stats.gov.cn/tjsj/ndsj/2018/indexch.htm. Chinese. National Standard of the People’s Republic of China. GB 13223–2011: Emission standard of air pollutants for thermal power plants. Chinese standard. Beijing: Ministry of Environmental Protection of the PRC; 2011. Chinese. Wang SM, Song C, Chen YB. Technology research and engineering applications of near-zero air pollutant emission coal-fired power plants. Res Envion Sci 2015;28(4):487–94. Chinese. [Notice on the issuance of the action plan for upgrading and retrofitting of coal-fired power plants for energy conservation and emission reduction (2014–2020)] [Internet]. Beijing: National Development and Reform Commission; 2014 Sep 12 [cited 2019 Jun 18]. Available from: http://www.gov.cn/gongbao/content/2015/content_2818468.htm. Chinese. Wang, 2019, Characteristics of particulate matter from four coal-fired power plants with low-low temperature electrostatic precipitator in China, Sci Total Environ, 662, 455, 10.1016/j.scitotenv.2019.01.080 An LS, Wang JP, Li JG, Yang HF, Liu WP, Liu HX, et al. Development and application overview of electrostatic precipitation technology for coal-fired power plant in China. Electr Power 2018;51(4):115–23. Chinese Wang SM, Zhang Y, Liu JZ. Integrated application of fine particulate matter control technologies and their “near-zero emission” characteristics in coal-fired power plants. Res Envion Sci 2016;29(9):1256–63. Chinese Zhong XP, Li FQ, Wu QR. Development status of high temperature dust removal technology in electric power industry. Energy Environ 2018;150(5):65–8. Chinese Zhang SJ, Zheng HA, Chen JS, Fan YJ, Li XQ. Status analysis and improvement measures of volatile dust removal technology in coal pyrolysis process. Clean Coal Technol 2014;20(3):79–82. Chinese. Fang MX, Liu JJ, Cen JM, Chen QL, Xia ZX. Research progress and application prospect of high temperature electrostatic precipitation technology. High Volt Eng 2019;45(4):1108–17. Chinese. Wang SM. Research on coal-fired power plants near-zero emission technologies and applications. [dissertation]. Beijing: North China Electric Power University; 2017. Chinese. Shi WZ, Yang MM, Zhang XH, Li SQ, Yao Q. Ultra-low emission technical route of coal-fired power plants and the cooperative removal. P CSEE 2016;36(16):4308–18. Chinese. El Sheikh, 2019, Advances in reduction of NOx and N2O emission formation in an oxy-fired fluidized bed boiler, Chin J Chem Eng, 27, 426, 10.1016/j.cjche.2018.06.033 Ke XW, Cai RX, Yang HR, Zhang M, Zhang H, Wu YX, et al. Formation and ultra-low emission of NOx for circulating fluidized bed combustion. P CSEE 2018;38(2):390–6. Chinese. Hao JM, Ma GD, Wang SX. Air pollution control engineering. 3rd ed. Beijing: Higer Education Press; 2010. Chinese. Chang, 2016, Clean coal technologies in China: current status and future perspectives, Engineering, 2, 447, 10.1016/J.ENG.2016.04.015 Cen KF. Research progress and outlook for efficient, clean and low-carbon coal utilization. Sci Technol Rev 2018;36(10):66–74. Chinese. Ozaki, 2008, Temperature programmed decomposition desorption of the mercury species over spent iron-based sorbents for mercury removal from coal derived fuel gas, Fuel, 87, 3610, 10.1016/j.fuel.2008.06.011 Srivastava, 2006, Control of mercury emissions from coal-fired electric utility boilers, Environ Sci Technol, 40, 1385, 10.1021/es062639u Zhao, 2017, Study on the mercury emission and transformation in an ultra-low emission coal-fired power plant, Fuel, 199, 653, 10.1016/j.fuel.2017.03.038 Fan, 2012, Hg0 removal from simulated flue gas over CeO2/HZSM-5, Energy Fuels, 26, 2082, 10.1021/ef201739p Li, 2011, CeO2–TiO2 catalysts for catalytic oxidation of elemental mercury in low-rank coal combustion flue gas, Environ Sci Technol, 45, 7394, 10.1021/es2007808 Diamantopoulou, 2010, Sorption of mercury by activated carbon in the presence of flue gas components, Fuel Process Technol, 91, 158, 10.1016/j.fuproc.2009.09.005 Khunphonoi, 2015, Enhancement of elemental mercury adsorption by silver supported material, J Environ Sci, 32, 207, 10.1016/j.jes.2015.01.008 Wang, 2016, Using modified fly ash for mercury emissions control for coal-fired power plant applications in China, Fuel, 181, 1230, 10.1016/j.fuel.2016.02.043 Gu, 2015, Evaluation of elemental mercury adsorption by fly ash modified with ammonium bromide, J Therm Anal Calorim, 119, 1663, 10.1007/s10973-014-4376-0 Wang, 2012, Experimental study on the characteristics of modified Ca-based sorbents and its mercury adsorption capability in the flue gas, Adv Mat Res, 424–425, 971 Yang, 2011, Gaseous elemental mercury capture from flue gas using magnetic nanosized (Fe3−xMnx)1−δO4, Environ Sci Technol, 45, 1540, 10.1021/es103391w Du W, Yin LB, Zhuo YQ, Xu QS, Zhang L, Chen CH. Experimental study on mercury capture using non-carbon sorbents in 100 MW coal-fired power plant. CIESC J 2014;65(11):4413–19. Chinese Glesmann S, Mimna R. The state of U.S. mercury control in response to MATS [Internet]. Power; 2015 Apr 1 [cited 2019 Jun 18]. Available from: http://www.powermag.com/the-state-of-u-s-mercury-control-in-response-to-mats/. Jones, 2007, DOE/NETL’s phase II mercury control technology field testing program: preliminary economic analysis of activated carbon injection, Environ Sci Technol, 41, 1365, 10.1021/es0617340 DB 13/2081–2014: Industrial fuel coal and civil fuel coal. Local standard of Hebei Province. Shijiazhuang: Quality and Technology Supervision Bureau of Hebei Province; 2014. Chinese. [Notice on the issuance of air pollution prevention and control implementation plan in Zhejiang Province 2017] [Internet]. Hangzhou: Department of Ecology and Environment of Zhejiang Province; 2017 May 19 [cited 2019 Jun 18]. Available from: http://www.zj.gov.cn/art/2017/5/22/art_12895_292947.html. Chinese. [Notice on the issuance of air pollution prevention and control action plan in Guangdong Province (2014–2017)] [Internet]. Guangdong: Department of Ecology and Environment of Guangzhou Province; 2014 Feb 7 [cited 2019 Jun 18]. Available from: http://www.gd.gov.cn/gkmlpt/content/0/142/post_142687.html#7. Chinese. Wang SX, Zhang L, Wu QR, Wang FY. Emission characteristics and environmental impacts of atmospheric mercury in China and control approaches. Beijing: Science Press; 2016. Chinese. Dai, 2012, Geochemistry of trace elements in Chinese coals: a review of abundances, genetic types, impacts on human health, and industrial utilization, Int J Coal Geol, 94, 3, 10.1016/j.coal.2011.02.003 Zhao, 2018, Emission controls of mercury and other trace elements during coal combustion in China a review, Int Geol Rev, 60, 638, 10.1080/00206814.2017.1362671 Zhang L, Wang SX, Hui LL, Hao JM. Strategic recommendations for the coal combustion sector in China on the implementation of minamata convention on mercury. Environ Prot 2016;44(22):38–42. Chinese. Yin LB, Zhuo YQ, Xu QS, Zhu ZW, Du W, An ZY. Mercury emission from coal-fired power plants in China. P CSEE. 2013;33(29):1–10. Chinese. Wang, 2010, Mercury emission and speciation of coal-fired power plants in China, Atmos Chem Phys, 10, 1183, 10.5194/acp-10-1183-2010 The first near-zero emission coal-fired power in the Jing–Jin–Ji region. Economic Information Daily. 2015 Nov 30; 6. Chinese. Wang, 2016, Investigation of near-zero air pollutant emission characteristics from coal-fired power plants, P CSEE, 36, 6140 Zhang, 2019, Benefits of current and future policies on emissions of China’s coal-fired power sector indicated by continuous emission monitoring, Environ Pollut, 251, 415, 10.1016/j.envpol.2019.05.021 UNEP, 2013 Zhang, 2017, Migration and emission characteristics of Hg in coal-fired power plant of China with ultra low emission air pollution control devices, Fuel Process Technol, 158, 272, 10.1016/j.fuproc.2017.01.020 Pudasainee, 2012, Oxidation, reemission and mass distribution of mercury in bituminous coal-fired power plants with SCR, CS-ESP and wet FGD, Fuel, 93, 312, 10.1016/j.fuel.2011.10.012 Zhang, 2019, In-situ capture of mercury in coal-fired power plants using high surface energy fly ash, Environ Sci Technol, 53, 7913, 10.1021/acs.est.9b01725 Williams J. America's best coal plants [Internet]. Power Engineering; 2014 Jul 17 [cited 2019 Jun 18]. Available from: http://www.power-eng.com/articles/print/volume-118/issue-7/features/america-s-best-coal-plants.html. Tian, 2013, A review of key hazardous trace elements in Chinese coals: abundance, occurrence, behavior during coal combustion and their environmental impacts, Energy Fuels, 27, 601, 10.1021/ef3017305 Wang SM, Yu XH, Gu YZ, Yuan J, Zhang Y, Chen YB, et al. Discussion of emission limits of air pollutants for near-zero emission coal-fired power plants. Res Environ Sci 2018;31(6):975–84. Chinese. Wang, 2016, Economic and environmental comparison of clean coal-fired power and gas turbine power, China Coal, 42, 5 [Environmental protection tax law of the PRC] [Internet]. Beijing: The National People's Congress of the PRC; 2016 Dec 25 [cited 2019 Jun 18]. Available from: http://www.npc.gov.cn/npc/c12435/201612/c305c6c912054177bbc3143628983e87.shtml. Chinese. Liu, 2017, Impact of “ultra low emission” technology of coal-fired power on PM 2.5 pollution in the Jing–Jin–Ji region, Front Energy, 1 Xu HH, Mo H, Wu JY, Zhu J, Huang R. Environmental benefits analysis under thermal power plant in Jing–Jin–Ji region in China under different pollution control scenarios. Environ Eng 2017;35(10):166–70. Chinese. [Notice on the issuance of air pollution prevention and control action plan] [Internet]. Beijing: The Central People's Government of the PRC; 2013 Sep 10 [cited 2019 Jun 18]. Available from: http://www.gov.cn/zwgk/2013-09/12/content_2486773.htm. Chinese. [Report on the state of the ecology and environment in China 2018]. Beijing: Ministry of Ecology and Environment of the PRC; 2019 May 29. Chinese. World Health Organization. WHO air quality guidelines for particulate matter, ozone, nitrogen dioxide and sulfur dioxide—global update 2005. Geneva: WHO Press; 2006.