CODE VERIFICATION OF MPACT USING GANAPOL CRITICAL ROD BENCHMARK

Jipu Wang,William R Martin,Benjamin S Collins,M Margulis,P Blaise

doi:10.1051/epjconf/202124710027

Jipu Wang, William R Martin + Show 3 more

Open Access

https://doi.org/10.1051/epjconf/202124710027

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Abstract

This work is dedicated to the code verification of MPACT, which is developed under the Consortium for Advanced Simulation of Light Water Reactors by the University of Michigan and Oak Ridge National Laboratory, where the numerical solution is compared to the reference solution of a benchmark problem with a known analytical solution. In this work, Benchmark Problem 3.4 in Barry Ganapol’s benchmark book was chosen as an MOC code verification test problem. Problem 3.4 is a bare cylinder of infinite height, which is an excellent benchmark problem for 2D MOC. To ensure that this benchmark problem exercised the same code as typically used by MPACT, the bare rod configuration was surrounded by a bounding box filled with a non-scattering material. To avoid implementing a critical rod search in the MPACT code, the MPACT analysis was performed using cross sections that yielded the given c, the average number of secondary neutrons per collision, and a rod radius that was the corresponding critical rod radius. MPACT agreed with all cases to within a few pcm. The convergence behavior was studied. The results show a 2nd order radial convergence, consistent with flat-source approximation. The convergence curves with respect to ray spacing and polar angle quadrature set order were also obtained. The other quantity of interest tabulated for Problem 3.4 was the radial distribution of the scalar flux. Two configurations were analyzed, and the resultant radial flux profiles agreed very well with the tabulated results. The verification of the production neutronics code MPACT has been augmented by the addition of the analytical solutions for an infinite cylinder from the Ganapol benchmark book. These test cases can be included in the regression suite for MPACT.

Highlights

The MPACT code [1] is developed under the Consortium for Advanced Simulation of Light Water Reactors (CASL) by the University of Michigan and Oak Ridge National Laboratory
Previous work published by the authors with Method of Manufactured Solutions (MMS), which is a rigorous code verification method, and Method of Characteristics (MOC) has focused on monoenergetic cross sections and 1D plane geometry [2], [3]
MPACT analyzes pin cells in an LWR lattice, special input processing would be needed to model the isolated cylinder. To ensure that this benchmark problem exercised the same code as typically used by MPACT, the bare rod configuration was surrounded by a bounding box filled with a non-scattering material

Summary

INTRODUCTION

The MPACT code [1] is developed under the Consortium for Advanced Simulation of Light Water Reactors (CASL) by the University of Michigan and Oak Ridge National Laboratory. Previous work published by the authors with Method of Manufactured Solutions (MMS), which is a rigorous code verification method, and Method of Characteristics (MOC) has focused on monoenergetic cross sections and 1D plane geometry [2], [3]. Excellent results were obtained for both fixed source and eigenvalue problems, where observed error convergence rates are consistent with theory. The addition of this MMS verification problem is a significant step for code verification of MPACT. An actual neutron transport benchmark problem was needed for code verification. This work is dedicated to the code verification of the 2D MOC solver in MPACT using a benchmark problem with a known analytical solution.

Ganapol benchmark description

Bounding box assumption

NUMERICAL RESULTS

Eigenvalue results

MPACT flux distribution for critical rods

CONCLUSIONS