Characterization of silicone gel properties for high power IGBT modules and MEMS

2015 IEEE Conference on Sustainable Utilization And Development In Engineering and Technology (CSUDET) Pub Date : 2015-10-01 DOI:10.1109/CSUDET.2015.7446220

K. Siow, T. Chen, Y. W. Chan, A. Jalar, R. Vemal, S. T. Chua, F. Husna

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引用次数: 9

Abstract

Silicone gels provide the dielectric insulation in insulated gate bipolar transistor (IGBT) power modules to prevent partial discharge, inhibit moisture ingress and keep out contaminants from the internal circuitry. The junction temperatures of these power modules are located between 150oC and 175oC and these temperatures will increase to 200oC in the near future. In addition, power modules are expected to operate for 15 to 20 years. The development time of these power modules is getting shorter to meet the market expectations. Similar demanding conditions are expected for micro-electromechanical systems (MEMS) applications. Hence, there is a need to use characterization tools to short-list silicone gels for further analysis or building of qualification units. Amongst the three silicone gels analysed here, sample C shows the most promise because of its lack of thermal events during the DSC analysis. Sample C also maintains the softness and inertness during the thermal ageing at 150oC for up to 1000 hours. These studies show that judicious use of DSC-TGA, FTIR and gel penetrometer can provide valuable information for the said purpose.

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高功率IGBT模块和MEMS用硅凝胶性能的表征

硅凝胶在绝缘栅双极晶体管(IGBT)电源模块中提供介电绝缘，以防止部分放电，抑制水分进入并防止内部电路中的污染物。这些电源模块的结温位于150 - 175℃之间，在不久的将来这些温度将上升到200℃。此外，电源模块预计将运行15至20年。这些电源模块的开发时间越来越短，以满足市场的期望。微机电系统(MEMS)的应用也需要类似的苛刻条件。因此，需要使用表征工具来筛选硅胶，以便进一步分析或建立合格单元。在这里分析的三种硅凝胶中，样品C显示出最有希望的，因为它在DSC分析期间缺乏热事件。样品C在150℃的热老化过程中也能保持柔软和惰性长达1000小时。这些研究表明，合理使用DSC-TGA、FTIR和凝胶穿透仪可以为上述目的提供有价值的信息。

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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2015 IEEE Conference on Sustainable Utilization And Development In Engineering and Technology (CSUDET)

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