核设施气态放射性氙在线监测系统研制

doi:10.13491/j.issn.1004-714X.2024.01.010

中国辐射卫生

2024, Vol. 33

Issue (1): 56-60 DOI: 10.13491/j.issn.1004-714X.2024.01.010

论著

本期目录 | 过刊浏览 | 高级检索

核设施气态放射性氙在线监测系统研制

郭庐阵, 庞洪超, 汪传高, 张彦彪, 王莹, 邬蒙蒙, 董信芳, 陈凌

中国原子能科学研究院, 北京 102413

Development of an online radioactive xenon gas monitoring system for nuclear facilities

GUO Luzhen, PANG Hongchao, WANG Chuangao, ZHANG Yanbiao, WANG Ying, WU Mengmeng, DONG Xinfang, CHEN Ling

China Institute of Atomic Energy, Beijing 102413 China

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (1255 KB) HTML ( )
输出: BibTeX | EndNote (RIS)

摘要目的当前，大气环境中的放射性氙^131mXe、^133mXe、¹³³Xe和¹³⁵Xe等同位素主要来源于各种反应堆的运行活动及反应堆重特大事故泄露，为提升核设施场所及其流出物中放射氙在线监测能力，研制高灵敏氙在线监测系统用于核设施场所及气态流出物中放射性氙活度浓度监测、预警和报警。方法采用氙膜分离浓缩技术，氙高效选择吸附技术和低本底特征伽马能谱分析方法建立了一套核设施气态放射性氙在线监测系统。结果放射性氙在线监测系统在取样1 h，测量1h的运行模式下，对¹³³Xe的最小可探测活度浓度约为（1.43 ±0.03） Bq/m³。结论该系统可较好地用于核动力厂和同位素生产堆等核设施场所及气态流出物中氙活度浓度的在线监测，有助于提升人员、环境及核设施安全水平。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	郭庐阵
	庞洪超
	汪传高
	张彦彪
	王莹
	邬蒙蒙
	董信芳
	陈凌

关键词 ：膜分离, 选择吸附, 低本底测量, 氙在线监测

收稿日期: 2023-07-25

PACS:

TL75

作者简介: 郭庐阵(1985-),男,河南永城人,副研究员,从事辐射防护与核仪器研发工作。E-mail:glzsdhr@163.com

引用本文:

郭庐阵, 庞洪超, 汪传高, 张彦彪, 王莹, 邬蒙蒙, 董信芳, 陈凌. 核设施气态放射性氙在线监测系统研制[J]. 中国辐射卫生, 2024, 33(1): 56-60.
GUO Luzhen, PANG Hongchao, WANG Chuangao, ZHANG Yanbiao, WANG Ying, WU Mengmeng, DONG Xinfang, CHEN Ling. Development of an online radioactive xenon gas monitoring system for nuclear facilities. Chinese Journal of Radiological Health, 2024, 33(1): 56-60.

链接本文:

http://www.zgfsws.com/CN/10.13491/j.issn.1004-714X.2024.01.010 或 http://www.zgfsws.com/CN/Y2024/V33/I1/56

[1] Bowyer TW, Kephart R, Eslinger PW, et al. Maximum reasonable radioxenon releases from medical isotope production facilities and their effect on monitoring nuclear explosions[J]. J Environ Radioact, 2013, 115: 192-200. DOI: 10.1016/j.jenvrad.2012.07.018
[2] Saey PRJ. The influence of radiopharmaceutical isotope production on the global radioxenon background[J]. J Environ Radioact, 2009, 100(5): 396-406. DOI: 10.1016/j.jenvrad.2009.01.004
[3] Galan M, Kalinowski M, Gheddou A, et al. New evaluated radioxenon decay data and its implications in nuclear explosion monitoring[J]. J Environ Radioact, 2018, 192: 628-634. DOI: 10.1016/j.jenvrad.2018.02.015
[4] Bowyer TW, Biegalski SR, Cooper M, et al. Elevated radioxenon detected remotely following the Fukushima nuclear accident[J]. J Environ Radioact, 2011, 102(7): 681-687. DOI: 10.1016/j.jenvrad.2011.04.009
[5] Saey PRJ, Bowyer TW, Ringbom A. Isotopic noble gas signatures released from medical isotope production facilities—Simulations and measurements[J]. Appl Radiat Isot, 2010, 68(9): 1846-1854. DOI: 10.1016/j.apradiso.2010.04.014
[6] Wotawa G, Becker A, Kalinowski M, et al. Computation and analysis of the global distribution of the radioxenon isotope ¹³³Xe based on Emissions from nuclear power plants and radioisotope production facilities and its relevance for the verification of the Nuclear-Test-ban treaty[J]. Pure Appl Geophys, 2010, 167(4): 541-557. DOI: 10.1007/s00024-009-0033-0
[7] Kalinowski MB, Pistner C. Isotopic signature of atmospheric xenon released from light water reactors[J]. Environ Radioact, 2006, 88(3): 215-235. DOI: 10.1016/j.jenvrad.2006.02.003
[8] MATTHIAS A. Characterization of the radioxenon back-ground: noble gas monitoring in the IMS[R]. ECS-PRES-16-1-18-2, 2016.
[9] 郑金阁, 程卫亚, 王晨潇, 等. 应用CFD方法研究结构对管道内气体混合均匀性影响[J]. 中国辐射卫生,2022,31(2):172-180. DOI: 10.13491/j.issn.1004-714X.2022.02.008
Zheng JG, Cheng WY, Wang CX, et al. Computational fluid dynamics analysis of influence of different pipe structures on gas mixing uniformity[J]. Chin J Radiol Health, 2022, 31(2): 172-180. DOI: 10.13491/j.issn.1004-714X.2022.02.008
[10] Kalinowski MB, Liao YY, Pistner C. Discrimination of nuclear explosions against civilian sources based on atmospheric radioiodine isotopic activity ratios[J]. Pure Appl Geophys, 2014, 171(3): 669-676. DOI: 10.1007/s00024-012-0564-7
[11] Le Petit G, Armand P, Brachet G, et al. Contribution to the development of atmospheric radioxenon monitoring[J]. J Radioanal Nucl Chem, 2008, 276(2): 391-398. DOI: 10.1007/s10967-008-0517-x
[12] Ringbom A, Elmgren K, Lindh K. Analysis of radioxenon in ground level air sampled in the Republic of South Korea on October 11-14[R]. [S. l. ]: FOI, 2007.
[13] Kalinowski MB, Liao YY. Isotopic characterization of radioiodine and radioxenon in releases from underground nuclear explosions with various degrees of fractionation[J]. Pure Appl Geophys, 2014, 171(3): 677-692. DOI: 10.1007/s00024-012-0580-7
[14] Ringbom A, Elmgren K, Lindh K, et al. Measurements of radioxenon in ground level air in South Korea following the claimed nuclear test in North Korea on October 9, 2006[J]. J Radioanal Nucl Chem, 2009, 282(3): 773-779. DOI: 10.1007/s10967-009-0271-8
[15] Thakur P, Ballard S, Nelson R. An overview of Fukushima radionuclides measured in the northern hemisphere[J]. Sci Total Environ, 2013, 458-460: 577-613. DOI: 10.1016/j.scitotenv.2013.03.105
[16] Kalinowski MB, Tuma MP. Global radioxenon emission inventory based on nuclear power reactor reports[J]. Environ Radioact, 2009, 100(1): 58-70. DOI: 10.1016/j.jenvrad.2008.10.015
[17] Saey PRJ, Wotawa G, De Geer LE, et al. Radioxenon background at high northern latitudes[J]. J Geophys Res, 2006, 111(D17): D17306. DOI: 10.1029/2005JD007038
[18] Saey PRJ, Auer M, Becker A, et al. The influence on the radioxenon background during the temporary suspension of operations of three major medical isotope production facilities in the Northern Hemisphere and during the start-up of another facility in the Southern Hemisphere[J]. J Environ Radioact, 2010, 101(9): 730-738. DOI: 10.1016/j.jenvrad.2010.04.016