Multiphysics Analysis of Thorium-Based Fuel Performance Under Reactor Steady-State and Transient Accident

核工程研究与设计 Pub Date : 2020-08-04 DOI:10.1115/icone2020-16325

Chenjie Qiu, Rong Liu, Wenzhong Zhou

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Abstract

The ThO2 fuel has higher thermal conductivity and melting boiling point than the UO2 fuel, which is beneficial to the fast removal of heat and the improvement of fuel melt margin. In this paper, the material properties and thermodynamic behaviors of thorium-based fuel were firstly reviewed. And then the thermal physical properties and the fuel behavior models of Th0.923U0.077O2 fuel and Th0.923Pu0.077O2 fuel have been implemented in fuel performance analysis code FRAPCON and FRAPTRAN. Finally, the performances of Th0.923U0.077O2 fuel, Th0.923Pu0.077O2 fuel and UO2 fuel under both normal operating conditions and transient conditions (RIA and LOCA) are analyzed and compared. The Th0.923U0.077O2 fuel is found to have lower fuel center-line temperature and the thorium-based fuels are observed to have a delayed pellet-cladding mechanical interaction (PCMI) under steady state. Furthermore, the fission gas release, cladding strain and internal fuel energy under transient conditions are found to be lower too. Lastly, the cladding displacement and temperature under transient conditions are also compared. The thorium-based fuel was found to have a higher safety margin and accident resistance than conventional UO2 fuel under both normal operating conditions and accident conditions.

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反应堆稳态和瞬态事故下钍基燃料性能的多物理场分析

与UO2燃料相比，ThO2燃料具有更高的导热系数和熔点，有利于快速脱热和提高燃料熔体裕度。本文首先综述了钍基燃料的材料性质和热力学行为。然后在燃料性能分析程序FRAPCON和FRAPTRAN中实现了Th0.923U0.077O2燃料和Th0.923Pu0.077O2燃料的热物理性质和燃料行为模型。最后，对Th0.923U0.077O2燃料、Th0.923Pu0.077O2燃料和UO2燃料在正常工况和瞬态工况(RIA和LOCA)下的性能进行了分析和比较。发现Th0.923U0.077O2燃料具有较低的燃料中心线温度，并且观察到钍基燃料在稳态下具有延迟的球团包壳机械相互作用(PCMI)。此外，瞬态条件下的裂变气体释放量、包层应变和内部燃料能也较低。最后，对瞬态条件下的包层位移和温度进行了比较。在正常工况和事故工况下，钍基燃料都比常规UO2燃料具有更高的安全裕度和抗事故能力。

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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核工程研究与设计

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