Transient analysis of MTR research reactor during fast and slow loss of flow accident

IF 0.4 4区工程技术 Q4 NUCLEAR SCIENCE & TECHNOLOGY Kerntechnik Pub Date : 2022-08-10 DOI:10.1515/kern-2022-0052

H. Selim

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Abstract

Abstract The main objective for reactor safety is to keep the fuel in a safe condition with adequate safety margins during all operational modes (normal-abnormal and accidental states). To achieve this purpose an accident analysis of different design base accidents (DBAs), one of them is the loss of flow accident (LOFA), is required for assessing reactor safety. In this research, the safety aspects of 22 MW MTR research reactor under steady state and during loss of flow accident is studied. The flow transients considered include fast loss of flow accident (FLOFA) and slow loss of flow accident (SLOFA) modeled with exponential flow decay and time constants of 1 and 25 s, respectively. The analysis is done using PARET, a neutronics-hydrodynamics-heat transfer code. The transients were initiated from a full power with a flow trip point at 85% nominal. The calculated parameters are the temperatures of different components (fuel, clad and coolant) as a function of time for the hot channel. The results indicate that in both accidents the calculated maximum cladding surface temperature for the hottest channel of the reactor core does not exceed the allowable safety limit and the fuel integrity is maintained.

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MTR研究堆快、慢失流事故瞬态分析

反应堆安全的主要目标是在所有运行模式(正常-异常和意外状态)下保持燃料处于具有足够安全裕度的安全状态。为了达到这一目的，需要对不同的设计基础事故(dba)进行事故分析，其中包括流动损失事故(LOFA)，以评估反应堆的安全性。本文对22 MW MTR研究堆稳态和失流事故下的安全问题进行了研究。考虑的流动瞬态包括快速流动损失事故(FLOFA)和缓慢流动损失事故(SLOFA)模型，分别采用指数流动衰减和时间常数分别为1和25 s。分析是使用PARET，一个中子-流体力学-传热程序。瞬变是从满功率开始的，流量跳闸点为85%标称。计算的参数是不同部件(燃料、包层和冷却剂)的温度作为热通道时间的函数。结果表明，在这两起事故中，堆芯最高温通道包壳表面的计算最高温度均未超过允许的安全极限，燃料的完整性得到了保证。

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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来源期刊

Kerntechnik 工程技术-核科学技术

CiteScore

0.90

自引率

20.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Kerntechnik is an independent journal for nuclear engineering (including design, operation, safety and economics of nuclear power stations, research reactors and simulators), energy systems, radiation (ionizing radiation in industry, medicine and research) and radiological protection (biological effects of ionizing radiation, the system of protection for occupational, medical and public exposures, the assessment of doses, operational protection and safety programs, management of radioactive wastes, decommissioning and regulatory requirements).