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Drift region integrated microchannel structure for direct cooling of power electronics

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4 Author(s)
Kremena Vladimirova ; Grenoble Electrical Engineering Lab (G2Elab), 961 Houille Blanche, 38402 St Martin d'Hères, France ; Jean-Christophe Crebier ; Yvan Avenas ; Christian Schaeffer

Direct liquid microchannel cooling is of great interest when considering the thermal management of high heat flux power devices and modules. This paper presents an original concept for efficient cooling of power devices based on the integration of a microchannel cooler, including numerous parallel through wafer fluid vias, directly into the drift region of the power device and perpendicular to the PN junction. Simulation results proved that no negative side effects are resulting from this integration regarding the electrical performance of the device. Electrical tests were carried out to validate the functionality of the fabricated prototypes. The effectiveness of the proposed cooling technique was evaluated with hydraulic and thermal numerical models. In line with the device design and the microchannel cooler analysis an experimental setup for the measurement of the thermal and hydraulic performances of the concept was realized. Pressure drops were measured and compared with the theoretical results.

Published in:

2011 IEEE Energy Conversion Congress and Exposition

Date of Conference:

17-22 Sept. 2011