Optimal Sizing and Material Choice for Additively Manufactured Compact Plate Heat Exchangers

With advancements in additive manufacturing (AM) capabilities, new opportunities arise to design compact heat exchangers (cHEXs) that leverage AM's degrees of freedom (DOFs) to enhance energy and material efficiency. However, excessive size reduction in counterflow cHEXs can compromise effectiveness due to axial heat conduction through the solid material, influenced by thermal conductivity and wall thickness. This study investigates how AM material selection and thin-wall production limitations might constrain the core size of counterflow plate heat exchangers when targeting maximum power density. An optimization framework evaluates power densities for six materials: plastic, austenitic steel, Al2O3, AlN, aluminum, and copper. Evaluations are conducted under constant effectiveness and pressure drop while accounting for AM-specific plate thickness limits and a lower bound on plate spacing to address fouling. Across all scenarios, copper cHEXs exhibit the lowest power density, despite high thermal conductivity. Without constraints on plate thickness and spacing, the optimal plastic cHEX achieves a power density 1800x greater than the steel baseline, while copper decreases by a factor of 0.98. With equal plate thickness of 0.5 mm for all materials, plastic retains the highest power density, 12.2x more than copper. Introducing a fouling constraint of 0.8 mm plate spacing shifts the optimal material to austenitic steel. When material-specific plate thicknesses are considered, the plastic cHEX achieves the highest power density, five times greater than copper, due to superior thin-wall resolution. This study highlights the impact of AM constraints on the energy and material efficiency of cHEXs, and shows that low-conductivity materials like plastic or austenitic steel can outperform high-conductivity materials like copper in compact designs.