Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
647137 | Applied Thermal Engineering | 2013 | 10 Pages |
A single-phase, laminar flow, rectangular, and AlN-based micro-channel heat sink (MCHS) with water coolant has been designed and optimized for power electronics packaging. By fabricating micro-channels in the AlN-layer of direct bond copper, the heat conduction path is minimized and high cooling performance of micro-channels is utilized. The scaling effects, including temperature-dependent fluid properties, entrance effect, viscous dissipation and conjugate heat transfer, are considered. Comparison between CFD simulation by ANSYS Fluent and well-established analytical correlations is carried out and importance of entrance effect is emphasized. For the optimal geometry, the total thermal resistance of the AlN-based MCHS is 0.128 K/W at a pressure drop of 66.6 kPa. The conventional packaging structures, in which the Cu-based MCHS is bonded to the direct bond copper by solder or thermal interface material, are investigated to compare with the proposed structure. The proposed structure shows a reduction in thermal resistance by 15% and 80% respectively.
► A new high performance integrated power electronics module design is introduced. ► Micro-channel heat sink is directly etched inside direct bond copper. ► Thermal and hydraulic performances are analyzed numerically and analytically. ► The proposed structure shows a reduction in thermal resistance by 80%.