中国燃煤发电排放的放射性环境影响评价研究

Abstract

Abstract: Based on different installed capacities, four evaluation areas as in the north and south, coastal and inland of China, and some new survey data or parameters, the radiological environmental impact from coal power plants were assessed. Results showed that: (1) Average normalized collective effective dose to the public within 80 km from coal power plant was 2.2 man·Sv/GWa. (2) Normalized collective dose from small sized coal-fired unit (100 MW and below) was 6.0 man·Sv/GWa and 1.8 man·Sv/GWa from the large sized coal-fired unit (300 MW and above); the collective dose from the small units was about 3 times higher than that from the large ones. (3) The dominant radionuclides were ²¹⁰Po and ²¹⁰Pb, and ingestion and inhalation were primary exposure pathway. (4) Collective dose of coal power plants in different sites could vary in one order of magnitude due to the big difference of population density. Conclusions and discussion: compared with natural background level, the radiological impacts of coal power plants are very small; however, coal-fired power plant is 34 times higher than nuclear power plant. By elimination of small sized coal-fired unit and implementation of ultra-low emission technology reformation, the radiological environmental impact from coal power plants would be further reduced. At present, the ²¹⁰Po emission cannot be removed effectively by dust collectors, and this should be further studied.

Key words: coal power plant, natural radioactivity, radiation environmental impact, public exposure, dose assessment

CLC Number:

X822.7

JIANG Ziying, ZHANG Yanqi, CHEN Xiaoqiu, LIAO Haitao, PAN Ziqiang. Radiological impacts assessment of coal-fired power plants in China[J].RADIATION PROTECTION, 2018, 38(3): 177-184.

References

[1] Simopoulos S E,Angelopoulos M G. Natural radioactivity releasesfrom lignite power plants in Greece[J]. J Environ Radioactivity, 1987, 5:379-389.
[2] Hedvall R, Erlandsson B. Radioactivity concentrations in non-nuclear industries[J]. J Environ Radioact,1996, 32(1-2): 19-31.
[3] Zeevaert T, Sweeck L,Vanmarcke H. The radiological impact from airborne routine discharges of a modern coal-fired power plant[J]. J Environ Radioact,2006, 85(1): 1-22.
[4] Trotti F, Liziero F, Zampieri C, et al. Impact to public and environment of NORM industries in Italy[J]. Radiat Prot Dosim, 2009,137(3-4):310-313.
[5] NCRP. Ionizing radiation exposure of the population of the United States[R]. NCRP Report No.160. Bethesda, 2009.
[6] 符荣初,宋妙发. 苏州某燃煤电厂气载放射性排出物环境影响评价[J]. 辐射防护, 1990, 10(3): 198-205.
[7] 李瑞香,刘新华,姜希文,等. 我国燃煤电厂气载流出物的辐射影响[J]. 辐射防护, 1990, 10(1): 30-36.
[8] 文湘闽,杨克毅,刘树恺. 四川省燃煤电厂对人群所产生的附加辐射剂量[J].职业卫生与病伤,1993,8(4): 240-242.
[9] 吴锦海,王力,王凤仙,等.上海燃煤电厂释放飞灰对环境的辐射影响[J]. 辐射防护通讯, 2000, 20(1): 33-34.
[10] 姜子英,刘森林,程建平,等.燃煤电厂的气载放射性排放及其辐射影响[J].辐射防护, 2008, 28(5): 257-266.
[11] Asokan P, Mohini Saxena, Asolekar S R. Coal combustion residues-environmental implications and recycling potentials[J]. Resources, Conservation and Recycling, 2005, 43(3): 239-262.
[12] 杨松君, 陈怀珍. 动力煤利用技术[M]. 北京:中国标准出版社, 1999: 11-13.
[13] Mishra U C. Environmental impact of coal industry and thermal power plants in India[J]. J Environ Radioact,2004,72(1-2): 35-40.
[14] 中国电力企业联合会.中国电力行业年度发展报告2016[R/OL]. 2016-08-24. http://www.cec.org.cn/guihuayutongji/gongzuodongtai/2016-08-24/157409.html.
[15] 濮洪九. 中国煤炭可持续开发利用及环境对策研究[M].北京:中国矿业大学出版社, 2010.
[16] 潘荔. 电力行业节能减排分析[J]. 中国电力企业管理,2014,(4): 52-55.
[17] 中国电力企业联合会.中国电力工业现状与展望[R/OL]. 2015-03-10. http://www.cec.org.cn/yaowenkuaidi/2015-03-10/134972.html.
[18] 王新雷, 周云, 徐彤. 促进我国火电能效持续提升政策研究[J].节能技术,2016,34(1):48-51.
[19] 唐文生. 规范企业自备电厂管理促进电力市场健康发展[EB/OL]. http://www.ndrc.gov.cn/xwzx/xwfb/201512/t20151230_769752.html.
[20] 魏昭峰.2014中国电力年鉴[M].北京:中国电力出版社,2014.
[21] 陈晓秋. CAIRDOS的模式与参数[R]. 北京:环境保护部核与辐射安全中心, 2004.
[22] Moore R E, Baes III C F, McDowell-Boyer L M, et al. AIRDOS-EPA: A computerized methodology for estimating environmental concentra-tions and dose to man from airborne releases of radionuclides[R]. Washington D.C.: U S Environmental Protection Agency, 1979.
[23] 姜希文,刘秋生,刘瑞香,等.我国煤中天然放射性核素水平[J].辐射防护,1989,9(3): 181-188.
[24] 吴锦海,李金全,周天豹.我国原煤及煤渣、粉煤灰的放射性水平调查[J].上海环境科学, 1989, 8(1): 28-29.
[25] 黄文辉,唐修义.中国煤中的铀、钍和放射性核素[J]. 中国煤田地质, 2002, 14(7): 55-63.
[26] 刘福东,潘自强,刘森林,等.全国煤矿中煤、矸石天然放射性核素含量调查分析[J].辐射防护,2007,27(3): 171-180.
[27] 中国工程院. 核电链和煤电链排放的放射性影响评价研究报告[R].2017.
[28] 李凤翔,金光宇,张建洲,等.61个电厂燃煤和灰分中的天然放射性水平及其对环境的辐射影响[J].辐射防护,1987,7(4):260-272.
[29] 张卫,郝玉怀,刘普灵,等.粉煤灰和煤矸石再资源化利用中天然放射性及其对环境的影响[J].中国环境监测,1987,6:35-42.
[30] 顾洪坤,郑汝宽,章文英,等.北京市燃煤电厂燃煤和粉煤灰及其建材制品中的天然放射性水平[J]. 辐射防护, 1996, 16(4): 309-316.
[31] 林丹,陈文瑛,赵时敏,等.燃煤电厂放射性水平与评价[J].中国辐射卫生,2001, 10(4): 218-219.
[32] 雷鸣,王成琼,彭元贵.贵州省含煤渣建材的放射性污染调查[J].华东地质学院学报,2001, 24(2): 123-126.
[33] 贾晓丹,卢新卫.宝鸡燃煤电厂原煤及粉煤灰中天然放射性水平[J].辐射防护,2006,26(5): 310-313.
[34] 谢贵英,涂传火,艾尔肯·阿布列木.火电厂燃煤和粉煤灰及炉渣中天然放射性水平分析[J].新疆大学学报(自然科学版), 2011, 28(2):209-212.
[35] 中国原子能科学研究院. 湖南、湖北和江西燃煤电厂辐射环境影响研究专题报告[R].2016.
[36] 潘自强. 燃煤排放物中有害物质的测定与分析[M]. 北京: 原子能出版社, 1993.
[37] 潘自强,马忠海, 李旭彤, 等. 我国煤电链和核电链对健康、环境和气候影响的比较[J]. 辐射防护, 2001,21(3):129-145.
[38] UNSCEAR. Sources, effects and risks of ionizing radiation[R]. UNSCEAR 1988 Report. United Nations Scientific Committee on the Effects of Atomic Radiation, 1988 Report to the General Assembly, with Annexes. United Nations sales publication E.88.IX.7. United Nations, New York, 1988.
[39] UNSCEAR. Sources, effectsand risks of ionizing radiation[R].UNSCEAR 2016 Report. United Nations Scientific Committee on the Effects of Atomic Radiation, Report to the General Assembly, with Annexes. United Nations, New York, 2016.
[40] WANG Chuangao, LIU Ruirui, Li Jinfeng, et al. ²¹⁰Po distribution after high temperature processes in coal-fired power plants [J]. Journal of Environmental Radioactivity,2017,(171):132-137.
[41] 翟凤英,杨晓光. 中国居民营养与健康状况调查报告之二2002膳食与营养素摄入状况[M].北京:人民卫生出版社,2006.
[42] 环境保护部核与辐射安全中心. 核设施评价区居民食物消费量参考值的推荐[R]. 2014.
[43] U.S. EPA. External exposureto radionuclidesin air, water,and soil[R].Federal Guidance Report No.12, EPA-402-R-93-081. 1993.
[44] 核工业标准化研究所. 电离辐射防护与辐射源安全基本标准:GB 18871—2002[S].北京:中国标准出版社,2003.
[45] 潘自强. 中国核工业三十年辐射环境质量评价[M]. 北京:中国原子能出版社,2013.
[46] IAEA. Handbook of parameter values for the prediction of radionuclide transfer in terrestrial and freshwater environments[R].IAEA TRS No. 472. 2010.
[47] 李建国. 核电与煤电放射性评价使用的转移参数推荐值[R].2016.
[48] UNSCEAR. Sources and effects of ionizing radiation. Volume I: Sources[R]. UNSCEAR 2000 Report. United Nations Scientific Committee on the Effects of Atomic Radiation, 2000 Report to the General Assembly, with Scientific Annexes. United Nations sales publication E.00.IX.3. United Nations, New York, 2000.
[49] 潘自强, 刘森林. 中国辐射水平[M]. 北京:原子能出版社, 2010.
[50] 杨端节, 李冰, 徐乐昌,等. 我国核电链排放的辐射环境影响[C]//21世纪初辐射防护论坛第十五次会议中国的辐射水平及影响. 成都,2017.
[51] 张燕齐, 姜子英, 潘自强. 我国大气气溶胶²¹⁰Pb、²¹⁰Po水平[C]//21世纪初辐射防护论坛第十四次会议第四次全国天然辐射照射与控制研讨会.南京,2016.

Radiological impacts assessment of coal-fired power plants in China

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