Low thermal resistance packaging for high power electronics

N. Shashidhar, A. Rao
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Abstract

Alumina and aluminum nitride substrates are routinely used in micro-electronic packaging where large quantity of heat needs to be dissipated, such as in LED packaging, high power electronics and laser packaging. Heat management in high power electronics or LED's is crucial for their lifespan and reliability. The ever-increasing need for higher power keeps challenging the packaging engineers to become more sophisticated in their packaging. With the availability of a 40 μm thick, high thermal conductivity ribbon alumina from Corning, the options available for packaging engineers has widened. This product has very high dielectric breakdown (~10kV at 40 μm thick), high thermal conductivity (>36 W/mK) and is rugged enough to be handled (with components attached) during packaging. These characteristics make ribbon alumina a cost-effective alternative to incumbent materials such as thick aluminum nitride, for use in high power microelectronics packaging. In this paper, high power LED and IGBT modules are modeled using commercially available code from ANSYS®. A geometry representative of typical LED packaging and IGBT packaging is constructed with Ansys Design Modeler platform and the allied meshing is done employing in-built Meshing tool in ANSYS Workbench®. We show that packaging with ~40 μm ribbon alumina delivers performance on par with or better than packaging with thicker aluminum nitride substrates.
用于大功率电子器件的低热阻封装
氧化铝和氮化铝基板通常用于需要散热的微电子封装,例如LED封装、高功率电子和激光封装。高功率电子器件或LED的热管理对其寿命和可靠性至关重要。对更高功率的不断增长的需求不断挑战包装工程师在他们的包装变得更加复杂。随着康宁40 μm厚的高导热氧化铝带状材料的问世,包装工程师的选择范围扩大了。该产品具有非常高的介电击穿(40 μm厚时~10kV),高导热系数(>36 W/mK),并且在包装过程中足够坚固,可以处理(附带组件)。这些特性使带状氧化铝成为一种具有成本效益的替代现有材料,如厚氮化铝,用于高功率微电子封装。在本文中,大功率LED和IGBT模块使用ANSYS®的商用代码进行建模。使用Ansys Design Modeler平台构建典型LED封装和IGBT封装的几何代表,并使用Ansys Workbench®中的内置网格工具完成相关网格划分。我们的研究表明,使用~40 μm带状氧化铝封装的性能与使用更厚的氮化铝基板封装的性能相当或更好。
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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