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引用次数: 2
摘要
米兰理工大学(Politecnico di Milano)正在开发一种多物理场有限体积法(FVM)求解器,将中子物理学和激波物理学结合起来,用于分析激波内爆裂变材料[1]。本文提出的求解器可用于亚临界钚实验的初步安全评估[2],更广泛地说,可用于裂变材料发生强能量事件(如化学爆炸)时的临界安全评估[3]。为此,将多群SP3中子输运模型与流体动力激波物理模型相结合[4],适合于描述强激波在固体材料中的传播。冲击物理模块实现了一个动态网格来再现材料变形,其控制方程以任意拉格朗日欧拉(ALE)公式编写,以在大变形的情况下保持网格质量。
A Coupled Neutronics Shock Physics Solver: Implementation of an SN Neutron Transport Module
A multiphysics finite volume method (FVM) solver, coupling neutronics and shock physics, is under development at Politecnico di Milano for the analysis of shock imploding fissile materials [1]. The proposed solver can be a useful tool to make preliminary safety assessment of subcritical plutonium experiments [2] and, more in general, to perform criticality safety evaluations in case of strongly energetic events (such as chemical explosions) involving fissile materials [3]. To this aim, a multi-group SP3 neutron transport model is coupled with a hydrodynamic shock physics model [4], suitable to describe the propagation of strong shockwaves in solid materials. The shock physics module implements a dynamic mesh to reproduce material deformations and its governing equations are written in an Arbitrary Lagrangian Eulerian (ALE) formulation to preserve the mesh quality in case of large distortions.
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