Analysis of Energy Loss Characteristics in an Axial-Flow Reactor Coolant Pump Based on Entropy Production Theory

Energies Pub Date : 2024-07-11 DOI:10.3390/en17143399
Zhong Li, Yanna Sun, Weifeng Gong, Dan Ni, Bo Gao
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Abstract

As the critical component of a nuclear power plant (NPP), the reactor coolant pump (RCP) will suffer energy losses during operation, which can lead to a series of safety issues and adversely affect the efficiency and stability of the NPP. In this study, the SST k-ω turbulence model is utilized to simulate the internal flow field of an axial-flow reactor coolant pump (RCP) under operating conditions of 0.8QN to 1.2QN. Combined with entropy production theory, the distribution characteristics and hydraulic causes of energy loss within different regions of the RCP are revealed. The research findings are as follows: the total entropy production in the RCP first decreases and then increases during operation; with turbulent entropy production consistently accounting for over 70% of the total, and direct entropy production accounting for less than 10%. The impeller and annular casing are always the main components responsible for hydraulic losses within the pump. As the flow rate increases, the total entropy production in the impeller initially decreases and then increases, accounting for between 34.3% and 51% of the total; with energy losses mainly concentrated on the suction side of the impeller blades. The total entropy production in the annular casing gradually increases under operating conditions ranging from 0.8QN to 1.2QN, accounting for between 20.4% and 50.3% of the total. Rotor-stator interaction (RSI), backflow, and flow separation near the volute tongue are significant causes of energy losses within the annular casing. Optimizing the geometric parameters of the impeller and annular casing is an effective way to reduce flow losses in axial-flow RCPs. The research results can provide a reference for the development of optimization techniques for RCPs.
基于熵产生理论的轴流式反应堆冷却剂泵能量损失特性分析
作为核电站(NPP)的关键部件,反应堆冷却剂泵(RCP)在运行过程中会产生能量损失,从而引发一系列安全问题,并对核电站的效率和稳定性产生不利影响。本研究利用 SST k-ω 湍流模型模拟了轴流式反应堆冷却剂泵 (RCP) 在 0.8QN 至 1.2QN 运行条件下的内部流场。结合熵产生理论,揭示了 RCP 不同区域能量损失的分布特征和水力原因。研究结果如下:在运行过程中,RCP 的总产熵量先减后增;其中湍流产熵量始终占总产熵量的 70% 以上,而直接产熵量不足 10%。叶轮和环形套管始终是造成泵内水力损失的主要部件。随着流量的增加,叶轮中的总熵产生量先是减少,然后增加,占总熵产生量的 34.3% 到 51%;能量损失主要集中在叶轮叶片的吸入侧。在 0.8QN 至 1.2QN 的运行条件下,环形套管中的总熵产生量逐渐增加,占总量的 20.4% 至 50.3%。转子-定子相互作用 (RSI)、回流和涡舌附近的流动分离是环形套管内能量损失的重要原因。优化叶轮和环形套管的几何参数是减少轴流式循环流化床流量损失的有效方法。研究结果可为开发 RCP 的优化技术提供参考。
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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