A diffuse interface method for simulation-based screening of heat transfer processes with complex geometries

TL;DR

This paper introduces a diffuse interface method for simulating heat transfer in complex geometries, offering a stable, efficient alternative to conformal meshing with comparable accuracy and reduced computational cost.

Contribution

The work presents a novel diffuse interface approach with automated phase field generation and boundary condition extension for heat transfer simulation in complex geometries.

Findings

Enables accurate heat transfer simulation with significantly reduced computation time.

Provides a stable, automated alternative to conformal meshing for complex geometries.

Predicts performance using measures of diffuse interface quality.

Abstract

Frequently, the design of physicochemical processes requires screening of large numbers of alternative designs with complex geometries. These geometries may result in conformal meshes which introduce stability issues, significant computational complexity, and require user-interaction for their creation. In this work, a method for simulation of heat transfer using the diffuse interface method to capture complex geometry is presented as an alternative to a conformal meshing, with analysis and comparisons given. The methods presented include automated non-iterative generation of phase fields from CAD geometries and an extension of the diffuse interface method for mixed boundary conditions. Simple measures of diffuse interface quality are presented and found provide predictions of performance. The method is applied to a realistic heat transfer problem and compared to the traditional conformal mesh approach. It is found to enable reasonable accuracy at an order-of-magnitude reduction in simulation time or comparable accuracy for equivalent simulation times.