SAM-ML: Integrating data-driven closure with nuclear system code SAM for improved modeling capability

Abstract

Advanced reactors often involve complicated thermal-fluid (T-F) phenomena. Modeling such phenomena withthe traditional one-dimensional (1-D) system code is a challenging task.The System Analysis Module (SAM), a modern nuclear system code, has developed a coarse mesh multi-dimensional (multi-D) flow modelto capture the spatial effect of T-F phenomena in advanced reactors. As a coarse mesh solver, constitutive relations are required for SAM’s multi-D model for unresolved fine-scale physics, such as turbulence.This work presents a novel approach that integrates neural networks as data-driven closurefor SAM’s multi-D flow model. The data-driven closure is trained with fine-resolution data to ensure its accuracy while maintaining a coarse mesh setup to ensure its efficiency and consistency with SAM. We demonstrate the applicability of this SAM-ML capability in an open volume thermal stratification problem, where a neural network model serves as the eddy viscosity closure. A customized interface between the neural network and SAM is developed to ensure flexible and efficient data exchange. The SAM-ML results demonstrate superior performance compared to SAM’s built-in zero-equation eddy viscosity closure.The case study shows that although the generalization capability of the data-driven closure still needs to be improved for different transient case or different geometric setup, SAM-ML demonstrates good potential for challenging simulation problems with improved accuracy and computational efficiency.