Results from a multi-physics numerical benchmark for codes dedicated to molten salt fast reactors

•We present a multi-physics benchmark for codes targeting molten salt fast reactors.•The benchmark is general and includes steady-state and transient calculations.•We present the results of the benchmarking campaign of four multi-physics tools.•Results show excellent agreement among all partners.•Th...

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Veröffentlicht in:	Annals of nuclear energy 2020-07, Vol.142, p.107428, Article 107428
Hauptverfasser:	Tiberga, Marco, de Oliveira, Rodrigo Gonzalez Gonzaga, Cervi, Eric, Blanco, Juan Antonio, Lorenzi, Stefano, Aufiero, Manuele, Lathouwers, Danny, Rubiolo, Pablo
Format:	Artikel
Sprache:	eng
Schlagworte:	Benchmark Code-to-code comparison Fast-spectrum Molten salt reactor Multi-physics Neutronics Nuclear Experiment Physics Thermal-hydraulics
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creator	Tiberga, Marco de Oliveira, Rodrigo Gonzalez Gonzaga Cervi, Eric Blanco, Juan Antonio Lorenzi, Stefano Aufiero, Manuele Lathouwers, Danny Rubiolo, Pablo
description	•We present a multi-physics benchmark for codes targeting molten salt fast reactors.•The benchmark is general and includes steady-state and transient calculations.•We present the results of the benchmarking campaign of four multi-physics tools.•Results show excellent agreement among all partners.•The provided result set is useful to test and develop similar multi-physics codes. Verification and validation of multi-physics codes dedicated to fast-spectrum molten salt reactors (MSR) is a very challenging task. Existing benchmarks are meant for single-physics codes, while experimental data for validation are absent. This is concerning, given the importance numerical simulations have in the development of fast MSR designs. Here, we propose the use of a coupled numerical benchmark specifically designed to assess the physics-coupling capabilities of the aforementioned codes. The benchmark focuses on the specific characteristics of fast MSRs and features a step-by-step approach, where physical phenomena are gradually coupled to easily identify sources of error. We collect and compare the results obtained during the benchmarking campaign of four multi-physics tools developed within the SAMOFAR project. Results show excellent agreement for all the steps of the benchmark. The benchmark generality and the broad spectrum of results provided constitute a useful tool for the testing and development of similar multi-physics codes.
doi_str_mv	10.1016/j.anucene.2020.107428
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Verification and validation of multi-physics codes dedicated to fast-spectrum molten salt reactors (MSR) is a very challenging task. Existing benchmarks are meant for single-physics codes, while experimental data for validation are absent. This is concerning, given the importance numerical simulations have in the development of fast MSR designs. Here, we propose the use of a coupled numerical benchmark specifically designed to assess the physics-coupling capabilities of the aforementioned codes. The benchmark focuses on the specific characteristics of fast MSRs and features a step-by-step approach, where physical phenomena are gradually coupled to easily identify sources of error. We collect and compare the results obtained during the benchmarking campaign of four multi-physics tools developed within the SAMOFAR project. Results show excellent agreement for all the steps of the benchmark. 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Verification and validation of multi-physics codes dedicated to fast-spectrum molten salt reactors (MSR) is a very challenging task. Existing benchmarks are meant for single-physics codes, while experimental data for validation are absent. This is concerning, given the importance numerical simulations have in the development of fast MSR designs. Here, we propose the use of a coupled numerical benchmark specifically designed to assess the physics-coupling capabilities of the aforementioned codes. The benchmark focuses on the specific characteristics of fast MSRs and features a step-by-step approach, where physical phenomena are gradually coupled to easily identify sources of error. We collect and compare the results obtained during the benchmarking campaign of four multi-physics tools developed within the SAMOFAR project. Results show excellent agreement for all the steps of the benchmark. 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subjects	Benchmark Code-to-code comparison Fast-spectrum Molten salt reactor Multi-physics Neutronics Nuclear Experiment Physics Thermal-hydraulics
title	Results from a multi-physics numerical benchmark for codes dedicated to molten salt fast reactors
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