Multi-Level Embedded Three-Dimensional Manifold Microchannel Heat Sink of Aluminum Nitride Direct Bonded Copper for the High-Power Electronic Module-Reference-Cited by-同舟云学术

Multi-Level Embedded Three-Dimensional Manifold Microchannel Heat Sink of Aluminum Nitride Direct Bonded Copper for the High-Power Electronic Module

Published:2023-06-07 Issue:1 Volume:146 Page:
ISSN:1043-7398
Container-title:Journal of Electronic Packaging
language:en
Short-container-title:

Author:

Lin Yujui¹,Wei Tiwei²³,Moy Wyatt Jason¹,Chen Hao⁴,Gupta Man Prakash⁵,Degner Michael⁵,Asheghi Mehdi¹,Mantooth H. Alan⁴,Goodson Kenneth E.¹

Affiliation:

1. Department of Mechanical Engineering, Stanford University , Stanford, CA 94305

2. Department of Mechanical Engineering, Stanford University , Stanford, CA 94305 ; , West Lafayette, IN 47907

3. School of Mechanical Engineering, Purdue University , Stanford, CA 94305 ; , West Lafayette, IN 47907

4. Department of Electrical Engineering, University of Arkansas , Fayetteville, AR 72701

5. Research and Advanced Engineering, Ford Motor Company , Dearborn, MI 48124

Abstract

Abstract Better thermal management is a key enabler of higher power density in traction inverter power modules. For the first time, we successfully fabricated and tested a microchannel with a three-dimensional (3D) manifold cooler (MMC) using aluminum nitride (AlN)-based directed bonded copper (DBC) substrates. The microchannels (width ∼300 μm and height ∼450 μm) and 3D manifold fluidic passages (width ∼300 μm and height ∼600 μm) were fabricated in two DBC substrates using the femtosecond laser and subsequently bonded using transition liquid phase (TLP) bonding. In this study, the hydraulic and thermal performance of the 3D MMC is measured and validated with numerical simulation. The proposed 3D MMC is capable of removing heat at 600 W/cm2 with a 10 kPa pressured drop at the thermal thermal resistance of 0.2 cm2 K/W. The optimized designs via geometric and layout rearrangement were conducted, which indicates the pressure drop can be further reduced by 10× while maintaining the same thermal performance.

Publisher

ASME International

Subject

Electrical and Electronic Engineering,Computer Science Applications,Mechanics of Materials,Electronic, Optical and Magnetic Materials

Link

https://asmedigitalcollection.asme.org/electronicpackaging/article-pdf/146/1/011006/7017390/ep_146_01_011006.pdf

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