Electro-thermal modeling of power IGBT modules by heat pipe systems

2017 International Conference on Engineering & MIS (ICEMIS) Pub Date : 2017-05-08 DOI:10.1109/ICEMIS.2017.8273068

A. Driss, S. Maalej, M. Zaghdoudi

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引用次数: 7

Abstract

This paper presents an electro-thermal model of an IGBT with its cooling system. A thermal model based on a Cauer Resistor-Capacitance (RC) thermal network, is developed in order to predict the IGBT junction temperature in transient operation. The thermal resistances and capacitances are obtained by a mathematical transformation that is applied to a model based on the Foster thermal network. An electrical model of the IGBT is also developed, and it takes into account the dependency of the static electrical parameters of the IGBT with the junction temperature. The electro-thermal model is considered in a boost converter applications, and two cooling modes are studied. The first one uses air convection technique, and the second one consists of a heat pipe cooling system of which the heat sink is cooled by cold plates using water circulation. The model predictions show the effectiveness of the heat pipe cooling system for different operating conditions such as the commutation frequency and the duty ratio. It is demonstrated that the heat pipe cooling system limits the junction temperature to low values which remain below the maximum admissible ones.

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基于热管系统的功率IGBT模块的电热建模

本文建立了IGBT及其冷却系统的电热模型。为了预测IGBT在瞬态工作时的结温，建立了基于Cauer电阻-电容(RC)热网络的热模型。热阻和热容通过应用于基于福斯特热网络的模型的数学变换得到。建立了IGBT的电学模型，该模型考虑了IGBT的静态电学参数与结温的关系。在升压变换器应用中考虑了电热模型，并研究了两种冷却模式。第一种采用空气对流技术，第二种采用热管冷却系统，其中散热器采用冷板水循环冷却。模型预测结果表明，在换相频率和占空比等不同工况下，热管冷却系统是有效的。结果表明，热管冷却系统将结温限制在较低的值，该值始终低于最大允许温度。

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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2017 International Conference on Engineering & MIS (ICEMIS)

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