Oscillating Heat Transfer Prediction in Porous Structures Using Generative AI-Assisted Explainable Machine Learning
Abstract
Predicting and interpreting thermal performance under oscillating flow in porous structures remains a critical challenge due to the complex coupling between fluid dynamics and geometric features. This study introduces a data-driven wGAN-LBM-Nested_CV framework that integrates generative deep learning, numerical simulation based on the lattice Boltzmann method (LBM), and interpretable machine learning to predict and explain the thermal behavior in such systems. A wide range of porous structures with diverse topologies were synthesized using a Wasserstein generative adversarial network with gradient penalty (wGAN-GP), significantly expanding the design space. High-fidelity thermal data were then generated through LBM simulations across various Reynolds (Re) and Strouhal numbers (St). Among several machine learning models evaluated via nested cross-validation and Bayesian optimization, XGBoost achieved the best predictive performance for the average Nusselt number (Nu) (R^2=0.9981). Model interpretation using SHAP identified the Reynolds number, Strouhal number, porosity, specific surface area, and pore size dispersion as the most influential predictors, while also revealing synergistic interactions among them. Threshold-based insights, including Re > 75 and porosity > 0.6256, provide practical guidance for enhancing convective heat transfer. This integrated approach delivers both quantitative predictive accuracy and physical interpretability, offering actionable guidelines for designing porous media with improved thermal performance under oscillatory flow conditions.