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Nuclear Science and Engineering Volume 163, 2009 - Issue 2
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Technical Paper

Development of a Three-Dimensional Time-Dependent Calculation Scheme for Molten Salt Reactors and Validation of the Measurement Data of the Molten Salt Reactor Experiment

J. KópháziBudapest University of Technology, Institute of Nuclear Technology H-1111 Budapest, Műegyetem rakpart 9, Hungary
,
D. LathouwersDelft University of TechnologyDepartment of Radiation, Radionuclides and Reactors Physics of Nuclear Reactors Mekelweg 15, 2629 JB Delft, Netherlands
&
J. L. KloostermanDelft University of TechnologyDepartment of Radiation, Radionuclides and Reactors Physics of Nuclear Reactors Mekelweg 15, 2629 JB Delft, Netherlands
Pages 118-131 | Published online: 10 Apr 2017

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Daniel Wooten & Jeffrey J. Powers. (2018) A Review of Molten Salt Reactor Kinetics Models. Nuclear Science and Engineering 191:3, pages 203-230.
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J. F. Prolo Filho & L. B. Barichello. (2014) General Expressions for Auxiliary Equations of a Nodal Formulation for Two-Dimensional Transport Calculations. Journal of Computational and Theoretical Transport 43:1-7, pages 352-373.
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Articles from other publishers (34)

Thi-Dung Nguyen & W.F.G. van Rooijen. (2023) Design of reactor physics experiments in support of chloride-fueled Molten Salt Reactor research & development. Annals of Nuclear Energy 181, pages 109479.
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Ao Zhang, Ming Dai, Maosong Cheng, Chunyan Zou & Jingen Chen. (2023) High-fidelity neutronics simulation of channel-type molten salt reactors. Nuclear Engineering and Design 401, pages 112063.
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Jianhui Wu, Jingen Chen, Xiangzhou Cai, Chunyan Zou, Chenggang Yu, Yong Cui, Ao Zhang & Hongkai Zhao. (2022) A Review of Molten Salt Reactor Multi-Physics Coupling Models and Development Prospects. Energies 15:21, pages 8296.
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Songyang Liu, Tian Zhang & Xiang Wang. (2022) Steady-state analyses of an smDFR with coupled Serpent-OpenFOAM calculation. Nuclear Engineering and Design 396, pages 111892.
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Y. Cui, J.G. Chen, J.H. Wu, C.Y. Zou, L. Cui, F. He & X.Z. Cai. (2022) Development and verification of a three-dimensional spatial dynamics code for molten salt reactors. Annals of Nuclear Energy 171, pages 109040.
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Fan Zhu, Bin Deng, Jianhui Wu, Chenggang Yu, Jingen Chen & Xiangzhou Cai. (2021) Three dimensional steady‐state neutronics/thermal‐hydraulics coupled simulation for a molten salt reactor moderated by zirconium hydride rods. International Journal of Energy Research 45:8, pages 12358-12382.
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Guifeng Zhu, Wei Guo, Xuzhong Kang, Chunyan Zou, Yang Zou, Rui Yan & Ye Dai. (2020) Neutronic effect of graphite dimensional change in a small modular molten salt reactor. International Journal of Energy Research 45:8, pages 11976-11991.
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Y. Cui, J.G. Chen, M. Dai & X.Z. Cai. (2021) Development of a steady state analysis code for molten salt reactor based on nodal expansion method. Annals of Nuclear Energy 151, pages 107950.
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Marco Tiberga, Danny Lathouwers & Jan Leen Kloosterman. (2020) A multi-physics solver for liquid-fueled fast systems based on the discontinuous Galerkin FEM discretization. Progress in Nuclear Energy 127, pages 103427.
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Chenghui Wan, Tianliang Hu & Liangzhi Cao. (2020) Multi-physics numerical analysis of the fuel-addition transients in the liquid-fuel molten salt reactor. Annals of Nuclear Energy 144, pages 107514.
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Y. Cui, L. Cui, S.P. Xia, J.G. Chen & X.Z. Cai. (2020) Dynamic analysis for a 2 MW liquid-fueled molten salt reactor. Progress in Nuclear Energy 126, pages 103381.
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John P. Carter & R.A. Borrelli. (2020) Integral molten salt reactor neutron physics study using Monte Carlo N-particle code. Nuclear Engineering and Design 365, pages 110718.
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Marco Tiberga, Rodrigo Gonzalez Gonzaga de Oliveira, Eric Cervi, Juan Antonio Blanco, Stefano Lorenzi, Manuele Aufiero, Danny Lathouwers & Pablo Rubiolo. (2020) Results from a multi-physics numerical benchmark for codes dedicated to molten salt fast reactors. Annals of Nuclear Energy 142, pages 107428.
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Rodrigo Costa Diniz, Alessandro da Cruz Gonçalves & Felipe Siqueira de Souza da Rosa. (2020) Neutron point kinetics model with precursors’ shape function update for molten salt reactor. Nuclear Engineering and Design 360, pages 110466.
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Gui-Feng Zhu, Rui Yan, Hong-Hua Peng, Rui-Min Ji, Shi-He Yu, Ya-Fen Liu, Jian Tian & Bo Xu. (2019) Application of Monte Carlo method to calculate the effective delayed neutron fraction in molten salt reactor. Nuclear Science and Techniques 30:2.
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Long He, Cheng-Gang Yu, Rui-Min Ji, Wei Guo, Ye Dai & Xiang-Zhou Cai. (2019) Development of a dynamics model for graphite-moderated channel-type molten salt reactor. Nuclear Science and Techniques 30:1.
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Chenggang Yu, Long He, Chunyan Zou, Yuwen Ma, Xiangzhou Cai, Jianhui Wu & Jingen Chen. (2018) Th-U breeding performance in a Channel-type molten salt Fast reactor with different starting fuels. Annals of Nuclear Energy 122, pages 91-100.
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Long He, Cheng-Gang Yu, Wei Guo, Ye Dai, Hai-Ling Wang & Xiang-Zhou Cai. (2018) Development of a Coupled Code for Steady-State Analysis of the Graphite-Moderated Channel Type Molten Salt Reactor. Science and Technology of Nuclear Installations 2018, pages 1-10.
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Alexander Lindsay, Gavin Ridley, Andrei Rykhlevskii & Kathryn Huff. (2018) Introduction to Moltres: An application for simulation of Molten Salt Reactors. Annals of Nuclear Energy 114, pages 530-540.
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Alexander Lindsay & Kathryn Huff. (2018) Moltres: finite element based simulation of molten salt reactors. The Journal of Open Source Software 3:21, pages 298.
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Benjamin R. Betzler, Jeffrey J. Powers & Andrew Worrall. (2017) Molten salt reactor neutronics and fuel cycle modeling and simulation with SCALE. Annals of Nuclear Energy 101, pages 489-503.
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. 2017. Molten Salt Reactors and Thorium Energy. Molten Salt Reactors and Thorium Energy 635 774 .
Gang Li, Xueqian Wang, Bin Liang, Xiu Li, Bo Zhang & Yu Zou. (2016) Modeling and control of nuclear reactor cores for electricity generation: A review of advanced technologies. Renewable and Sustainable Energy Reviews 60, pages 116-128.
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Matteo Zanetti, Antonio Cammi, Carlo Fiorina & Lelio Luzzi. (2015) A Geometric Multiscale modelling approach to the analysis of MSR plant dynamics. Progress in Nuclear Energy 83, pages 82-98.
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Bart L. Sjenitzer, J. Eduard Hoogenboom, Javier Jiménez Escalante & Victor Sanchez Espinoza. (2015) Coupling of dynamic Monte Carlo with thermal-hydraulic feedback. Annals of Nuclear Energy 76, pages 27-39.
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A. TresC. B. PicolotoJ. F. Prolo FilhoR. D. da CunhaL. B. Barichello. (2014) Explicit formulation of a nodal transport method for discrete ordinates calculations in two-dimensional fixed-source problems. Kerntechnik 79:2, pages 155-162.
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Manuele Aufiero, Mariya Brovchenko, Antonio Cammi, Ivor Clifford, Olivier Geoffroy, Daniel Heuer, Axel Laureau, Mario Losa, Lelio Luzzi, Elsa Merle-Lucotte, Marco E. Ricotti & Hervé Rouch. (2014) Calculating the effective delayed neutron fraction in the Molten Salt Fast Reactor: Analytical, deterministic and Monte Carlo approaches. Annals of Nuclear Energy 65, pages 78-90.
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K. Nagy, D. Lathouwers, C.G.A. T’Joen, J.L. Kloosterman & T.H.J.J. van der Hagen. (2014) Steady-state and dynamic behavior of a moderated molten salt reactor. Annals of Nuclear Energy 64, pages 365-379.
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Carlo Fiorina, Danny Lathouwers, Manuele Aufiero, Antonio Cammi, Claudia Guerrieri, Jan Leen Kloosterman, Lelio Luzzi & Marco Enrico Ricotti. (2014) Modelling and analysis of the MSFR transient behaviour. Annals of Nuclear Energy 64, pages 485-498.
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Antonio Cammi, Carlo Fiorina, Claudia Guerrieri & Lelio Luzzi. (2012) Dimensional effects in the modelling of MSR dynamics: Moving on from simplified schemes of analysis to a multi-physics modelling approach. Nuclear Engineering and Design 246, pages 12-26.
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L.B. Barichello, L.C. Cabrera & J.F. Prolo Filho. (2011) An analytical approach for a nodal scheme of two-dimensional neutron transport problems. Annals of Nuclear Energy 38:6, pages 1310-1317.
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Antonio Cammi, Valentino Di Marcello, Lelio Luzzi, Vito Memoli & Marco Enrico Ricotti. (2011) A multi-physics modelling approach to the dynamics of Molten Salt Reactors. Annals of Nuclear Energy 38:6, pages 1356-1372.
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Lelio Luzzi, Antonio Cammi, Valentino Di Marcello & Carlo Fiorina. (2010) An approach for the modelling and the analysis of the MSR thermo-hydrodynamic behaviour. Chemical Engineering Science 65:16, pages 4873-4883.
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Thi-Dung Nguyen & W.F.G. Van Rooijen. (2022) Design of Reactor Physics Experiments in Support of Chloride-Fueled Molten Salt Reactor Research & Development. SSRN Electronic Journal.
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