Flow-priority optimization of additively manufactured variable-TPMS lattice heat exchanger based on macroscopic analysis

TL;DR

This paper develops a macroscopic modeling and optimization approach for TPMS lattice heat exchangers, demonstrating that flow-priority optimized lattice structures significantly improve heat transfer efficiency over uniform lattices.

Contribution

It introduces a novel macroscopic flow and heat transfer model for TPMS lattice heat exchangers and optimizes lattice distribution based on flow priorities, validated through experiments.

Findings

Optimized lattice structures outperform uniform lattices in heat transfer efficiency.

The macroscopic model accurately predicts performance improvements.

Experimental results show an average 28.7% enhancement in heat transfer.

Abstract

Heat exchangers incorporating triply periodic minimal surface (TPMS) lattice structures have attracted considerable research interest because they promote uniform flow distribution, disrupt boundary layers, and improve convective heat-transfer performance. However, from the perspective of forming a macroscopic flow pattern optimized for heat-exchange efficiency, a uniform lattice is not necessarily the optimal configuration. This study initially presents a macroscopic modeling approach for a two-fluid heat exchanger equipped with a TPMS Primitive lattice. The macroscopic flow analysis is conducted based on the Darcy--Forchheimer theory. Under the assumption that heat is transferred solely at the interface between the fluid and the TPMS walls, a macroscopic heat-transfer model is developed using a volumetric heat-transfer coefficient, which serves as an artificial property characterizing the unit-volume heat-transfer capability. To regulate the relative dominance of the hot and cold flows-effectively, the channel widths-within the heat exchanger, we adopt the isosurface threshold of the Primitive lattice as the design variable and construct an optimization scheme for the lattice distribution using the previously described macroscopic model. The optimization is subsequently carried out for a planar heat exchanger where the hot and cold fluids each follow U-shaped flow trajectories. The optimal solution was verified, and its validity was examined through detailed geometric analysis and experiments conducted using metal LPBF. The optimal solution derived from the macroscopic model also demonstrated a clear performance advantage over the uniform lattice in the experimental results. The optimal solution obtained from the macroscopic model also demonstrated a clear performance improvement over the uniform lattice, with an average enhancement of 28.7% in the experimental results.