Silicon carbide high-temperature packaging module fabrication

The 1st IEEE Workshop on Wide Bandgap Power Devices and Applications Pub Date : 2013-10-01 DOI:10.1109/WIPDA.2013.6695591

W. Brokaw, J. Elmes, B. Grummel, Z. Shen, Thomas Wu

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引用次数: 2

Abstract

A proposed method for accommodating high-temperature operation has been studied and developed through combined efforts of Advanced Power Electronics Corporation (ApECOR) and University of Central Florida. A novel process is being explored that will ultimately lead to design, fabrication, and verification of high temperature packaging for silicon carbide (SiC) power modules. The process is established to advance the operational capabilities of power modules during high-temperature conditions. Prototype modules were produced and underwent significant testing to establish capability of operation at a minimum temperature of 350 °C with probable expectation of operation in excess of 400 °C. A strenuous thermal cycle testing apparatus was established to rapidly cycle prototype modules between 80 °C and 350 °C in excess of 150 iterations per module. Analysis of the testing data did not exhibit degradation in the module performance characteristics, indicating successful module design performance. Based on the scope and goals of this research effort, further development of the design process is believed to be feasible for progression towards further development and commercialization.

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碳化硅高温封装模块制造

通过先进电力电子公司(ApECOR)和中佛罗里达大学的共同努力，提出了一种适应高温运行的方法。目前正在探索一种新的工艺，最终将导致碳化硅(SiC)功率模块的高温封装的设计、制造和验证。该工艺的建立是为了提高功率模块在高温条件下的运行能力。原型模块已经生产出来，并进行了重要的测试，以确定在350°C的最低温度下运行的能力，并可能在超过400°C的温度下运行。建立了一个剧烈热循环测试装置，在80°C和350°C之间快速循环原型模块，每个模块超过150次迭代。对测试数据的分析没有显示出模块性能特征的下降，表明模块设计性能成功。基于这项研究工作的范围和目标，设计过程的进一步发展被认为是可行的，可以进一步发展和商业化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The 1st IEEE Workshop on Wide Bandgap Power Devices and Applications

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