“Development And Testing Of A System Thermal-Hydraulics Model For A 50-Mwel-Class Pressurized Water Reactor - Small Modular Reactor (Pwr-Smr)”

IF 0.5 Q4 NUCLEAR SCIENCE & TECHNOLOGY

Journal of Nuclear Engineering and Radiation Science Pub Date : 2023-08-24 DOI:10.1115/1.4063240

Shu Jun Wang, Xianmin Huang, Y. Rao, B. Bromley

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引用次数: 1

Abstract

This paper describes the development, analysis, testing of a RELAP5-3D system thermal-hydraulics model for a 50-MWel-class pressurized water reactor - small modular reactor (PWR-SMR), similar to that by NuScale Power. This study focuses on a series of sensitivity tests to investigate the impacts of model changes. Parameters considered in the sensitivity study included the surge line junction resistance (SLJR), steam generator (SG) heat transfer area (SGHTA), SG primary flow area (SGPFA), SG secondary pressure (SGSP), and SG secondary flow rate (SGSF). Results for the reference and sensitivity simulations are compared with available design data. The flow in the primary circuit of the PWR-SMR is driven by natural circulation, and can be sensitive to changes in hydraulic resistance and pressure drop in system components. Initial results demonstrated significant flow oscillations. As a result of sensitivity studies, it was found that the surge line junction resistance needed to be increased to a factor of 30 to reduce mass flow oscillations to less than ±2%. Modifications to the steam generator heat transfer area, primary flow area, or secondary pressure have very little impact in reducing flow oscillations. However, it was found that the steam generator secondary flow rate will affect primary circuit flow oscillations, and when the SGSF was artificially increased from 68 kg/s (design data) to 91 kg/s (a 36% increase), the oscillations were eliminated, along with better matching with design data for core flow rate and inlet/outlet temperatures.

查看原文本刊更多论文

50mwell级压水堆-小型模块化堆(Pwr-Smr)系统热工模型的开发与测试

本文介绍了RELAP5-3D系统热工模型的开发、分析和测试，该模型适用于与NuScale Power类似的50 mwell级压水堆-小型模块化反应堆(PWR-SMR)。本研究主要通过一系列敏感性测试来考察模型变化的影响。灵敏度研究中考虑的参数包括喘振线结阻(SLJR)、蒸汽发生器(SG)换热面积(SGHTA)、SG一次流面积(SGPFA)、SG二次压力(SGSP)和SG二次流量(SGSF)。参考和灵敏度模拟结果与现有设计数据进行了比较。PWR-SMR一次回路中的流量由自然循环驱动，并且对系统组件的液压阻力和压降变化很敏感。初步结果显示明显的流动振荡。灵敏度研究的结果发现，浪涌线结电阻需要增加到30倍，才能将质量流振荡降低到±2%以下。对蒸汽发生器换热面积、一次流动面积或二次压力的修改对减少流动振荡的影响很小。然而，研究发现蒸汽发生器二次流量会影响一次回路流量的振荡，当人为地将SGSF从68 kg/s(设计数据)增加到91 kg/s(增加36%)时，振荡被消除，同时堆芯流量和进出口温度与设计数据的匹配更好。

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

Journal of Nuclear Engineering and Radiation Science NUCLEAR SCIENCE & TECHNOLOGY-

CiteScore

1.30

自引率

0.00%

发文量

期刊介绍： The Journal of Nuclear Engineering and Radiation Science is ASME’s latest title within the energy sector. The publication is for specialists in the nuclear/power engineering areas of industry, academia, and government.