Development and Implementation of CFD-Informed Models for the Advanced Subchannel Code CTF

Blyth, Taylor S.

doi:10.2172/1355890

Cited by 10 publications

(1 citation statement)

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“…Several methods have been proposed to address the integration of high-fidelity and low-fidelity codes to predict quantities of interests in an efficient manner. Examples are the improved modelling of spacer grid effects in sub-channel thermal-hydraulics M&S [11] and the calibration methodology developed for gap conductance modeling in fuel rod heat transfer of a core thermal-hydraulics model by leveraging a high-fidelity fuel performance code [12].…”

Section: Improved Multi-physics Multi-scale Mandsmentioning

confidence: 99%

Innovations in Multi-Physics Methods Development, Validation, and Uncertainty Quantification

Avramova

Abarca

Hou

et al. 2021

JNE

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This paper provides a review of current and upcoming innovations in development, validation, and uncertainty quantification of nuclear reactor multi-physics simulation methods. Multi-physics modelling and simulations (M&S) provide more accurate and realistic predictions of the nuclear reactors behavior including local safety parameters. Multi-physics M&S tools can be subdivided in two groups: traditional multi-physics M&S on assembly/channel spatial scale (currently used in industry and regulation), and novel high-fidelity multi-physics M&S on pin (sub-pin)/sub-channel spatial scale. The current trends in reactor design and safety analysis are towards further development, verification, and validation of multi-physics multi-scale M&S combined with uncertainty quantification and propagation. Approaches currently applied for validation of the traditional multi-physics M&S are summarized and illustrated using established Nuclear Energy Agency/Organization for Economic Cooperation and Development (NEA/OECD) multi-physics benchmarks. Novel high-fidelity multi-physics M&S allow for insights crucial to resolve industry challenge and high impact problems previously impossible with the traditional tools. Challenges in validation of novel multi-physics M&S are discussed along with the needs for developing validation benchmarks based on experimental data. Due to their complexity, the novel multi-physics codes are still computationally expensive for routine applications. This fact motivates the use of high-fidelity novel models and codes to inform the low-fidelity traditional models and codes, leading to improved traditional multi-physics M&S. The uncertainty quantification and propagation across different scales (multi-scale) and multi-physics phenomena are demonstrated using the OECD/NEA Light Water Reactor Uncertainty Analysis in Modelling benchmark framework. Finally, the increasing role of data science and analytics techniques in development and validation of multi-physics M&S is summarized.

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Section: Improved Multi-physics Multi-scale Mandsmentioning

confidence: 99%