A variational nodal formulation for multi-dimensional unstructured neutron diffusion problems

A variational nodal method (VNM) with unstructured-mesh is presented for solving steady-state and dynamic neutron diffusion equations. Orthogonal polynomials are employed for spatial discretization, and the stiffness confinement method (SCM) is implemented for temporal discretization. Coordinate tra...

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Bibliographic Details
Published in:Nuclear engineering and technology 2023, 55(6), , pp.2172-2194
Main Authors: Sun, Qizheng, Xiao, Wei, Li, Xiangyue, Yin, Han, Zhang, Tengfei, Liu, Xiaojing
Format: Article
Language:English
Subjects:
Neutron diffusion equation
Neutron dynamic equation
Partitioned matrix acceleration
Unstructured mesh
Variational nodal method
원자력공학
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Summary:A variational nodal method (VNM) with unstructured-mesh is presented for solving steady-state and dynamic neutron diffusion equations. Orthogonal polynomials are employed for spatial discretization, and the stiffness confinement method (SCM) is implemented for temporal discretization. Coordinate transformation relations are derived to map unstructured triangular nodes to a standard node. Methods for constructing triangular prism space trial functions and identifying unique nodes are elaborated. Additionally, the partitioned matrix (PM) and generalized partitioned matrix (GPM) methods are proposed to accelerate the within-group and power iterations. Neutron diffusion problems with different fuel assembly geometries validate the method. With less than 5 pcm eigenvalue (keff) error and 1% relative power error, the accuracy is comparable to reference methods. In addition, a test case based on the kilowatt heat pipe reactor, KRUSTY, is created, simulated, and evaluated to illustrate the method's precision and geometrical flexibility. The Dodds problem with a step transient perturbation proves that the SCM allows for sufficiently accurate power predictions even with a large time-step of approximately 0.1 s. In addition, combining the PM and GPM results in a speedup ratio of 2–3.
ISSN:1738-5733
2234-358X
DOI:10.1016/j.net.2023.02.021