What question did this study set out to answer?

The aim is to enhance the design of fin-integrated phase change material systems for better thermal management.

March 26, 2026Open Access

SINDy-Based Surrogate Modeling for Coupled Thermofluid Analysis in the Design of PCM Thermal Energy Storage Systems

Key Points

The aim is to enhance the design of fin-integrated phase change material systems for better thermal management.
Developed a surrogate model using Sparse Identification of Nonlinear Dynamics (SINDy) for coupled thermofluid analysis.
Evaluated predictive accuracy of the model in a generic 2D fin-integrated PCM device.
The model predicts temperature variations with an error margin of approximately 2K.
Demonstrated effectiveness in streamlining the design process for thermal energy storage systems.

Abstract

Fin-integrated phase change material (PCM) devices embedded in panel structures are being explored as passive thermal control systems for managing heat generated by high-power equipment in artificial satellites. In this study, we aim to streamline the design process of fin-integrated PCM devices by developing a surrogate model for coupled thermofluid analysis using Sparse Identification of Nonlinear Dynamics (SINDy). The proposed model demonstrates the ability to predict temperature variations with approximately 2K error in a generic 2D fin-integrated PCM device.

SINDy-Based Surrogate Modeling for Coupled Thermofluid Analysis in the Design of PCM Thermal Energy Storage Systems

Key Points

Abstract

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