Electric Field Control by Nonlinear Field Dependent Conductivity Dielectrics Characterization for High Voltage Power Module Packaging

2019 IEEE International Workshop on Integrated Power Packaging (IWIPP) Pub Date : 2019-04-24 DOI:10.1109/IWIPP.2019.8799101

M. Tousi, M. Ghassemi

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引用次数: 19

Abstract

Accelerated aging in next-generation insulation systems for wide bandgap (WBG) power electronic modules is the most significant barrier to realizing high-voltage, high-power-density conversion devices and systems. Accelerated aging in these systems is the result of two factors: 1) voltage pulses faster (with a dv⁄dt up to 100 kV/μs) and more repetitive (with a frequency up to 500 kHz), and 2) electric field stress higher than that found in existing state-of-the-art technologies. Current geometrical techniques for electric field control in power modules cannot address this issue alone. Our goal in this paper is to characterize nonlinear field-dependent conductivity (FDC) materials applied to high electric stress regions that, in combination with geometrical techniques, can well address high electric field stress issue. Studies are carried out in COMSOL Multiphysics. The influence of applied voltage type, AC and DC, is investigated. It is shown that a bridging FDC coating layer can lead to more electric field reduction than non-bridging one.

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基于非线性场相关电导率介质特性的高压电源模块封装电场控制

下一代宽带隙(WBG)电力电子模块绝缘系统的加速老化是实现高电压、高功率密度转换器件和系统的最大障碍。这些系统中的加速老化是两个因素的结果:1)电压脉冲更快(dv / dt高达100 kV/μs)和更重复(频率高达500 kHz)，以及2)电场应力高于现有的最先进技术。目前电力模块电场控制的几何技术无法单独解决这一问题。我们在本文中的目标是表征应用于高电应力区域的非线性场相关电导率(FDC)材料，结合几何技术，可以很好地解决高电场应力问题。在COMSOL Multiphysics中进行了研究。研究了施加电压类型(交流电压和直流电压)的影响。结果表明，桥接的FDC涂层比非桥接的FDC涂层更能减小电场。

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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2019 IEEE International Workshop on Integrated Power Packaging (IWIPP)

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