Lattice Benchmarking of Deterministic, Monte Carlo and Hybrid Monte Carlo Reactor Physics Codes for the Soluble-Boron-Free SMR Cores

Author

Syed B. Alam, Missouri University of Science and TechnologyFollow
Dinesh Kumar
Bader Almutairi
Tuhfatur Ridwan
Cameron S. Goodwin
For full list of authors, see publisher's website.

Abstract

Since the use of deterministic transport code WIMS can significantly reduce the computational time compared to the Monte Carlo (MC) code Serpent and hybrid MC code MONK, one of the major objectives of this study is to observe whether deterministic code WIMS can provide accuracy in reactor physics calculations while comparing Serpent and MONK. Therefore, numerical benchmark calculations for a soluble-boron-free (SBF) small modular reactor (SMR) assembly have been performed using the WIMS, Serpent and MONK. Although computationally different in nature, these codes can solve the neutronic transport equations and calculate the required neutronic parameters. A comparison in neutronic parameters between the three codes has been carried out using two types of candidate fuels: 15% ²³⁵U enriched homogeneously mixed all-UO₂ fuel and 18% ²³⁵U enriched micro–heterogeneous ThO₂-UO₂ duplex fuel in a 2D fuel assembly model using a 13×13 arrangement. The eigenvalue/reactivity (k_∞) and 2D assembly pin power distribution at different burnup states in the assembly depletion are compared using three candidate nuclear data files: ENDF/B-VII, JEF2.2 and JEF3.1. A good agreement in k_∞ values was observed among the codes for both the candidate fuels. The differences in k_∞ between the codes are ~200 pcm when cross-sections based on the same nuclear data file are used. A higher difference (up to ~450 pcm) in the k_∞ values is observed among the codes using cross-sections based on different data files. Finally, it can be concluded from this study that the good agreement in the results between the codes found provides enhanced confidence that modeling of SBF, SMR propulsion core systems with micro-heterogeneous duplex fuel can be performed reliably using deterministic neutronics code WIMS, offering the advantage of less expensive computation than that of the MC Serpent and hybrid MC MONK codes.

Recommended Citation

S. B. Alam et al., "Lattice Benchmarking of Deterministic, Monte Carlo and Hybrid Monte Carlo Reactor Physics Codes for the Soluble-Boron-Free SMR Cores," Nuclear Engineering and Design, vol. 356, Elsevier B.V, Jan 2020.

The definitive version is available at https://doi.org/10.1016/j.nucengdes.2019.110350

Department(s)

Nuclear Engineering and Radiation Science

Keywords and Phrases

Benchmarking; Deterministic; Hybrid Monte Carlo; Micro-Heterogeneous Thorium-Based Duplex Fuel; Monte Carlo; Small Modular Reactor (SMR)

International Standard Serial Number (ISSN)

0029-5493

Document Type

Article - Journal

Document Version

Citation

File Type

text

Language(s)

English

Rights

© 2020 Elsevier B.V., All rights reserved.

Publication Date

01 Jan 2020