Study on Airborne Radionuclide Dispersion in Floating Nuclear Power Plant under the Loss-of-Coolant Accident

Zou, Shuliang; Liu, Na; Huang, Binhai

doi:10.1155/2021/1299821

Cited by 3 publications

(3 citation statements)

References 12 publications

(8 reference statements)

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“…The paper [5] concerns a floating nuclear power plant. Therefore, the main way to reduce the consequences of the accident is to rotate the station platform.…”

Section: Analysis Of Recent Research and Publicationsmentioning

confidence: 99%

Methodology for Modeling the Spread of Radioactive Substances in Case of an Emergency Release at a Nuclear Power Plant

Levchenko,

Biliaiev,

Biliaieva

et al. 2023

A.I.S.

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The methodology for modeling the propagation of accidental releases of radionuclides from a power unit of a nuclear power plant has been developed. The calculation method takes into account the most critical factors propagation cloud - wind direction and speed, the intensity of the release radionuclides change: semi-continuous release, long-term release, instantaneous release. Diffuse processes and the presence of interference in the form of buildings were also taken into account. To solve the modeling equation of the aerodynamic model, the velocity potential equation is solved. The use of this equation instead of the traditional Novier-Stokes equation makes it possible to rationalize the calculation process in terms of the speed obtaining simulated data. To build a numerical model, a rectangular difference grid is used. The velocity potential and the quantities values of volumetric activity are determined at the centers of difference cells. The value of the airflow velocity vector component is determined on the sides of the difference cells. A finite-difference splitting scheme is used for numerical integration of the equation convective-diffusion transfer radionuclides. A computer code was developed on the basis of the constructed numerical model, the programming language Fortran was used. The approach used makes it possible to reduce the time for obtaining one scenario of an accident development. The cloud propagation dynamics determining is carried out almost in real time. This allows you to quickly respond to changing situations and make adequate decisions.

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“…The paper [5] concerns a floating nuclear power plant. Therefore, the main way to reduce the consequences of the accident is to rotate the station platform.…”

Section: Analysis Of Recent Research and Publicationsmentioning

confidence: 99%

Methodology for Modeling the Spread of Radioactive Substances in Case of an Emergency Release at a Nuclear Power Plant

Levchenko,

Biliaiev,

Biliaieva

et al. 2023

A.I.S.

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“…These semi-empirical models operate on the data on the pollution of the territory from the point of view the prevailing factors of the influence (the wind, the temperature, precipitation) in a specific territory. In the work [6], CFD modeling of the possible development of the accident is used, which is very effective, but a moving object is considered, which is not relevant for most active power plants. In the study [7], a model of changes in territory pollution after sedimentation of emission products was developed.…”

Section: Introductionmentioning

confidence: 99%

Modeling the Distribution of Emergency Release Products at a Nuclear Power Plant Unit

Biliaieva,

Levchenko,

Myshchenko

et al. 2024

A.I.S.

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Despite the fact that much attention is paid to the safe operation of nuclear power plants, there is a possibility of an accident with the release of radionuclides. This is especially true in Ukraine, where there is a threat of the damage to nuclear reactors as a result of military operations. It is impossible to research the distribution of products emergency releases radioactive substances in laboratory conditions. Therefore, the only tool for the development predicting of an accident is the modeling the spread of a radionuclides cloud. The purpose of the research is a modeling the distribution of emergency release products in a nuclear power plant unit, suitable for the operative assessment of a development an accident. Results of the research: The mathematical model of the distribution emission products of a nuclear power plant has been developed, which takes into account the value of the initial activity of emission products, the rate of the settling radioactive particles, the wind speed components, the intensity changes radionuclide emission over time. The technique for solving the boundary value problem of modeling in conditions of a complex shape of the computational domain, taking into account the presence of obstacles to the spread of emission products has been developed. The use of the velocity potential equation in evolutionary form allows us to speed up the calculation process. The chosen splitting scheme of an alternating-triangular method allows to find the speed potential according to the explicit form at each splitting step. This allowed software implementation of the CFD model. The visualized models of the emission cloud distribution allow to determine the radiation situation in any place of the emission product distribution zone. The developed model makes it possible to quickly predict the development of an accident in space and time, which makes it possible to take measures to protect people from exposure in the shortest possible time. Conclusions: The obtained emission cloud propagation models and their visualization make it possible to determine the state of environmental pollution under various initial conditions during the development of the accident.

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“…Domestic and foreign scholars have carried out some studies on the migration patterns of radionuclides in severe accidents of ship's reactors, focusing on the close-range or closed environments, respectively. Zou et al [6] used computational fluid dynamics to simulate the diffusion of airborne radionuclides under the combined conditions of platform position, wind direction, and breach direction (north-south-west-east) within two kilometers after a breach accident in a floating nuclear power plant. Zhao et al [7] used computational fluid dynamics to study the diffusion of radionuclides in the cabin after a severe accident of a large breach in the marine reactor, and obtained the time node for the leakage of radionuclides to adjacent cabins and containment.…”

Section: Introductionmentioning

confidence: 99%

Study on the Atmospheric Diffusion of Airborne Radionuclide under LOCA of Offshore Floating Nuclear Power Plants Based on CALPUFF

et al. 2023

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Studying the migration and diffusion of radionuclides plays an important role in emergency decision making and accident mitigation of floating nuclear power plants. Based on the CALPUFF model, this paper simulates the spatial distribution and concentration distribution of airborne radionuclides 131I diffusion under the conditions of sailing and power supply under LOCA (Loss-of-Coolant Accident) of the floating nuclear power plant, and the influence of four meteorological parameters, namely wind speed, cloudiness, temperature and air pressure, on the migration was analyzed using sensitivity analysis. The results show that the wind direction affects the diffusion direction of 131I, and the concentration of 131I decreases with the increase in the diffusion distance; under the same conditions, the radionuclides diffuses farther and the affected area is larger under the sailing condition. Wind speed is the dominant factor affecting the diffusion of radionuclides, followed by the cloud amount parameter, temperature parameter, and air pressure parameter. The research results can provide theoretical support for emergency responses to nuclear accidents in offshore floating nuclear power plants.

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Study on Airborne Radionuclide Dispersion in Floating Nuclear Power Plant under the Loss-of-Coolant Accident

Cited by 3 publications

References 12 publications

Methodology for Modeling the Spread of Radioactive Substances in Case of an Emergency Release at a Nuclear Power Plant

Methodology for Modeling the Spread of Radioactive Substances in Case of an Emergency Release at a Nuclear Power Plant

Modeling the Distribution of Emergency Release Products at a Nuclear Power Plant Unit

Study on the Atmospheric Diffusion of Airborne Radionuclide under LOCA of Offshore Floating Nuclear Power Plants Based on CALPUFF

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