基于空气冷却的熔盐堆非能动余热排出系统优化设计  

作　　者：张卓华[1] 付瑶 孙微 冉旭[1] 李峰[1] 鲜麟 苏东川[1] 何晓强[1] Zhang Zhuohua;Fu Yao;Sun Wei;Ran Xu;Li Feng;Xian Lin;Su Dongchuan;He Xiaoqiang(Science and Technology on Reactor System Design Technology,NPIC,Chengdu,610213,China;Shanghai Institute of Applied Physics,CAS,Shanghai,201800,China;Nuclear and Radiation Safety Center,MEE,Beijing,100082,China)

机构地区：[1]中国核动力研究设计院核反应堆系统设计技术重点实验室,成都610213 [2]中国科学院上海应用物理研究所,上海201800 [3]中国生态环境部核与辐射安全中心,北京100082

出　　处：《核动力工程》2022年第1期226-231,共6页Nuclear Power Engineering

摘　　要：上海应用物理研究所基于TRISO包覆球形颗粒燃料与液态氟盐提出了基于钍基熔盐固态试验堆(TMSR-SF1)技术方案,其中一个重要的工作是非能动余热排出系统(PRHRS)设计。由于熔盐与水的不兼容特性,以及其高运行温度,采用空气作为最终热阱来设计PRHRS成为必然。为实现系统最简化、体积最小化以及排热与保温兼顾的设计目标,本文从MSR堆芯活性区到外界空气热阱传热过程的模型入手,建立了PRHRS优化设计模型,获得了优化设计方案,并基于改进的RELAP5/MOD4.0程序(针对TMSR-SF1的专门改进程序)开展了PRHRS容量论证评价,经计算分析,PRHRS容量设计合理,可确保反应堆全厂断电(SBO)后排热安全。Shanghai Institute of Applied Physics proposed a technical solution based on the Thorium-based Molten Salt Solid-state Test Reactor(TMSR-SF1) based on TRISO-coated spherical particulate fuel and liquid fluoride salt. One of the most important works is the design of passive residual heat removal system(PRHRS). Because of the incompatibility between molten salt and water and its high operating temperature, it is necessary to use air as the final heat sink to design PRHRS. In order to achieve the design objectives of system simplification, volume minimization and consideration of heat removal and insulation, starting with the model of heat transfer process from MSR core active zone to external air heat sink, this paper establishes the PRHRS optimization design model, obtains the optimization design scheme, and based on the improved RELAP5/MOD4.0 code(special improved code for TMSR-SF1) carries out the demonstration and evaluation of PRHRS capacity. Calculation and analysis show that the design of PRHRS capacity is reasonable, which can ensure the heat removal safety after the reactor SBO.

关 键 词：熔盐堆(MSR) 钍基熔盐固态试验堆(TMSR-SF1) 非能动余热排出系统(PRHRS) 优化设计 安全分析 

分 类 号：TL334[核科学技术—核技术及应用]