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SACTI 模型在预测和评估核电厂大型自然通风冷却塔环境影响中的应用。

SACTI model in prediction and assessment of large scale natural draft cooling tower environmental impact of nuclear power plant.

机构信息

School of Energy and Power Engineering, Xi'an Jiaotong University, Xi'an, 710049, China.

Faculty of Architecture, Civil and Transportation Engineering, Beijing University of Technology, Beijing, 100081, China.

出版信息

Sci Rep. 2023 Jul 10;13(1):11171. doi: 10.1038/s41598-023-38283-7.

DOI:10.1038/s41598-023-38283-7
PMID:37430100
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10333337/
Abstract

Large Scale Natural Draft Cooling Tower has become a hot topic in China because it is an important part of the nuclear power plant, and its environmental impacts include shading, solar energy loss, water deposition and salt deposition. In China, there is no built large-scale natural draft cooling tower of nuclear power plant. Therefore, model prediction becomes an effective way to solve this problem. This paper introduces the basic principles and structure of SACTI (Seasonal and Annual Cooling Tower Impact) model. SACTI is a cooling tower assessment model developed by Argonne National Laboratory, USA. A comparative case study between China's Pengze Nuclear Power Plant and the US Amos Power Plant is also presented. Calculations were carried out for the Pengze and Amos power plants, and the results showed that the maximum value of salt deposition at the Pengze plant was about 166.5 kg/(km-month) at a distance of 800 m from the cooling tower. The maximum value of salt deposition at the Amos plant was about 92.85 kg/(km-month) at a distance of 600 m from the cooling tower. Conclusions show that the research work can provide a useful solution in future work, the simulation results of the SACTI model have a potential mean in the absence of monitoring data. This research provides a way to generate simulation data through SACTI program in the design process of nuclear power plant cooling tower, and designers can use these data to determine how the cooling tower will affect the natural environment and manage within an appropriate range to reduce the impact on the environment.

摘要

大型自然通风冷却塔在中国已成为热门话题,因为它是核电站的重要组成部分,其环境影响包括遮荫、太阳能损失、水沉积和盐沉积。在中国,还没有建成的大型核动力自然通风冷却塔。因此,模型预测成为解决这个问题的有效方法。本文介绍了 SACTI(季节性和年度冷却塔影响)模型的基本原理和结构。SACTI 是美国阿贡国家实验室开发的一种冷却塔评估模型。还介绍了中国彭泽核电站和美国阿莫斯核电站的对比案例研究。对彭泽和阿莫斯电厂进行了计算,结果表明,在距离冷却塔 800 米处,彭泽电厂盐沉积的最大值约为 166.5kg/(km·月)。在距离冷却塔 600 米处,阿莫斯电厂盐沉积的最大值约为 92.85kg/(km·月)。结论表明,该研究工作可以为未来的工作提供有益的解决方案,SACTI 模型的模拟结果在缺乏监测数据的情况下具有潜在的意义。本研究通过 SACTI 程序在核电厂冷却塔的设计过程中生成模拟数据,为设计师提供了一种方法,以便确定冷却塔将如何影响自然环境,并在适当的范围内进行管理,以减少对环境的影响。

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