Introducing Passive Nuclear Safety in Water-Cooled Reactors: Numerical Simulation and Validation of Natural Convection Heat Transfer and Transport in Packed Beds of Heated Microspheres

IF 0.5 Q4 NUCLEAR SCIENCE & TECHNOLOGY
Olugbenga O Noah, Johan . F Slabber, Josua P Meyer
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Abstract

Abstract The development of an accident tolerant nuclear fuel for water-cooled reactors would redefined the status of these reactors from traditional active safety to passive safety systems. As a possible solution toward enhancing the safety of light-water reactors (LWRs), loose-coated particles of enriched uranium dioxide (UO2) fuel with the ability to retain gaseous and metallic fission products in the case of a loss of cooling event can be introduced inside Silicon-Carbide cladding tubes of the fuel assembly (see Figs. 1(a) and 1(b)). These coated particles are treated as a bed from where heat is transferred to the cladding tube and the helium gas movement is due to natural convection. A slender geometrical model with tube-to-particle diameter ratio N = 2.503 and porosity ε = 0.546 mimicking the proposed nuclear fuel in the cladding was numerically simulated. This study is to investigate the heat transfer characteristics and flow distribution under buoyancy driven force expected in the cladding tube of the proposed nuclear fuel using a commercial code. Random packing of the particles is achieved by discrete element method (DEM) simulation with the aid of starccm+. The temperature contour and velocity vector plots obtained can be said to be good illustration of anticipated heat transfer and transport phenomenon to occur in the proposed fuel design. Simulated results for particle-to-fluid heat transfer coefficient, Nusselt number, and Rayleigh number which are of prime importance when analyzing natural convection heat transfer performance in fixed bed reactors were validated. Results from this work show close agreement with results obtained in established numerical and experimental works.
介绍水冷堆的被动核安全:加热微球填充床内自然对流传热的数值模拟与验证
摘要:研制事故容错型水冷堆核燃料,将使水冷堆从传统的主动安全系统转变为被动安全系统。作为提高轻水反应堆(LWRs)安全性的一种可能的解决方案,可以在燃料组件的碳化硅包层管中引入包裹松散的浓缩二氧化铀(UO2)燃料颗粒,这些颗粒在冷却事件损失的情况下能够保留气体和金属裂变产物(见图1(a)和1(b))。这些被包覆的颗粒被当作一个床,热量从这里传递到包层管,氦气的运动是由于自然对流。数值模拟了一个管粒比N = 2.503,孔隙率ε = 0.546的细长几何模型。本研究是利用商业规范研究在浮力驱动下核燃料包壳管内的传热特性和流动分布。采用离散元法(DEM)模拟,借助starccm+实现颗粒的随机填充。得到的温度轮廓图和速度矢量图可以说很好地说明了所提出的燃料设计中预期的传热和输运现象。对固定床反应器自然对流换热性能分析中重要的颗粒-流体换热系数、努塞尔数和瑞利数的模拟结果进行了验证。所得结果与已有的数值和实验结果非常吻合。
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
CiteScore
1.30
自引率
0.00%
发文量
56
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.
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