模拟核电厂 VVER 事故过程中气溶胶粒径分布对裂变产物行为的影响分析

IF 0.9 Q4 ENERGY & FUELS Thermal Engineering Pub Date : 2024-08-23 DOI:10.1134/S0040601524700198
S. S. Savekin, Yu. B. Shmelkov
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引用次数: 0

摘要

摘要由于接触气溶胶粒子对人体有潜在危险,现行法规文件限制了有害物质的最大允许浓度。在核电站发生超出设计基础的事故时,可能会形成气溶胶粒子。核电厂事故期间形成的放射性气溶胶粒子对人体造成的放射性影响要比此类粒子的机械影响严重得多。放射性气溶胶粒子的一个重要特征是多分散性(大小不均),因为在核电厂事故中,不同大小的粒子从核电厂安全壳大气中清除的速度不同。因此,在考虑安全壳中颗粒的移动和气溶胶颗粒向环境的释放时,必须正确模拟气溶胶颗粒的大小分布。本文介绍了在 TOSQAN 和 Phebus-FP 实验中按大小计算气溶胶粒子的数量和质量分布的结果。文中给出了描述多分散系统(使用粒度分布或 "平均 "粒度表征整个分布)的方法及其对安全壳中气溶胶颗粒转移相关过程的影响,并给出了使用粒度分布的实用建议。比较了气溶胶粒子的平均粒度分布特征和对数正态分布的使用情况,以估算在使用 VVER 的核电厂发生假想事故时的释放量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Analysis of the Influence of Aerosol Particle Size Distribution on the Behavior of Fission Products during Simulation of an Accident at an NPP with VVER

Due to the potential danger of exposure to aerosol particles on the human body, maximum permissible concentrations of harmful substances are limited by current regulatory documentation. The formation of aerosol particles is possible during beyond design basis accidents at nuclear power plants. The consequences of the radioactive impact of radioactive aerosol particles formed during an accident at a nuclear power plant on the human body are significantly more severe than from the mechanical impact of such particles. An important characteristic of radioactive aerosol particles is their polydispersity (unevenness in size) since particles of different sizes during an accident at a nuclear power plant have different rates of removal from the atmosphere of the nuclear power plant’s containment. Thus, when considering the movement of particles in the containment and the release of aerosol particles into the environment, it is important to correctly model the size distribution of aerosol particles. This paper presents the results of calculating the count and mass distributions of aerosol particles by size in the TOSQAN and Phebus-FP experiments. Methods are given for describing polydisperse systems (using particle size distribution or “average” sizes characterizing the entire distribution) and their influence on processes associated with the transfer of aerosol particles in a containment, and practical recommendations for working with particle size distributions are given. A comparison is made of the use of average size distribution characteristics and the lognormal distribution of aerosol particles to estimate the release during a hypothetical accident at a nuclear power plant with VVER.

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来源期刊
CiteScore
1.30
自引率
20.00%
发文量
94
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