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Main Authors: Shin, Jeesuk, Kim, Cheolwoong, Yang, Sunwoong, Lee, Minseo, Kim, Sung Joong, Jeon, Joongoo
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.16447
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author Shin, Jeesuk
Kim, Cheolwoong
Yang, Sunwoong
Lee, Minseo
Kim, Sung Joong
Jeon, Joongoo
author_facet Shin, Jeesuk
Kim, Cheolwoong
Yang, Sunwoong
Lee, Minseo
Kim, Sung Joong
Jeon, Joongoo
contents Severe accidents (SAs) in nuclear power plants have been analyzed using thermal-hydraulic (TH) system codes such as MELCOR and MAAP. These codes efficiently simulate the progression of SAs, while they still have inherent limitations due to their inconsistent finite difference schemes. The use of empirical schemes incorporating both implicit and explicit formulations inherently induces unidirectional coupling in multi-physics analyses. The objective of this study is to develop a novel numerical method for TH system codes using physics-informed neural network (PINN). They have shown strength in solving multi-physics due to the innate feature of neural networks-automatic differentiation. We propose a node-assigned PINN (NA-PINN) that is suitable for the control volume approach-based system codes. NA-PINN addresses the issue of spatial governing equation variation by assigning an individual network to each nodalization of the system code, such that spatial information is excluded from both the input and output domains, and each subnetwork learns to approximate a purely temporal solution. In this phase, we evaluated the accuracy of the PINN methods for the hydrodynamic module. In the 6 water tank simulation, PINN and NA-PINN showed maximum absolute errors of 1.678 and 0.007, respectively. It should be noted that only NA-PINN demonstrated acceptable accuracy. To the best of the authors' knowledge, this is the first study to successfully implement a system code using PINN. Our future work involves extending NA-PINN to a multi-physics solver and developing it in a surrogate manner.
format Preprint
id arxiv_https___arxiv_org_abs_2504_16447
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Node Assigned physics-informed neural networks for thermal-hydraulic system simulation: CVH/FL module
Shin, Jeesuk
Kim, Cheolwoong
Yang, Sunwoong
Lee, Minseo
Kim, Sung Joong
Jeon, Joongoo
Machine Learning
Severe accidents (SAs) in nuclear power plants have been analyzed using thermal-hydraulic (TH) system codes such as MELCOR and MAAP. These codes efficiently simulate the progression of SAs, while they still have inherent limitations due to their inconsistent finite difference schemes. The use of empirical schemes incorporating both implicit and explicit formulations inherently induces unidirectional coupling in multi-physics analyses. The objective of this study is to develop a novel numerical method for TH system codes using physics-informed neural network (PINN). They have shown strength in solving multi-physics due to the innate feature of neural networks-automatic differentiation. We propose a node-assigned PINN (NA-PINN) that is suitable for the control volume approach-based system codes. NA-PINN addresses the issue of spatial governing equation variation by assigning an individual network to each nodalization of the system code, such that spatial information is excluded from both the input and output domains, and each subnetwork learns to approximate a purely temporal solution. In this phase, we evaluated the accuracy of the PINN methods for the hydrodynamic module. In the 6 water tank simulation, PINN and NA-PINN showed maximum absolute errors of 1.678 and 0.007, respectively. It should be noted that only NA-PINN demonstrated acceptable accuracy. To the best of the authors' knowledge, this is the first study to successfully implement a system code using PINN. Our future work involves extending NA-PINN to a multi-physics solver and developing it in a surrogate manner.
title Node Assigned physics-informed neural networks for thermal-hydraulic system simulation: CVH/FL module
topic Machine Learning
url https://arxiv.org/abs/2504.16447