半导体散热的瞬态热阻抗建模

Conference Record of the 1993 IEEE Industry Applications Conference Twenty-Eighth IAS Annual Meeting Pub Date : 1993-10-02 DOI:10.1109/IAS.1993.299072

K.H. Sueker

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引用次数: 6

摘要

功率半导体器件的热特性由其瞬态热阻抗(TTZ)曲线来定义。这条曲线是设备设计人员通常可以获得的唯一热信息。然而，TTZ曲线仅适用于安装在无热界面阻力的无限散热器上的器件。如果通过界面的热流不恒定，则半导体和散热器形成复合热系统，TTZ曲线不再适用。作者提出了一种将半导体和散热器建模为分布式R/C网络的技术，选择半导体网络是为了匹配器件在感兴趣的时间段内的TTZ曲线。该模型具有良好的理论基础，可用于系统的TTZ曲线的绘制。该模型对于半导体电流的脉冲持续时间跨越TTZ曲线的过渡范围的应用特别有价值。

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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Transient thermal impedance modeling of semiconductor heat sinking

The thermal characteristic of a power semiconductor device is defined by its transient thermal impedance (TTZ) curve. This curve is the only thermal information normally available to the equipment designer. The TTZ curve, however, is only valid for a device mounted on an infinite heat sink with no thermal interface resistance. If heat flow across the interface is not constant, the semiconductor and heat sink form a composite thermal system and the TTZ curve is no longer applicable. The authors present a technique for modeling the semiconductor and heat sink as distributed R/C networks, the semiconductor network being chosen so as to match the TTZ curve for the device over the time period of interest. The model has a theoretically sound basis and it allows a TTZ curve to be developed for the system. The model is especially valuable for applications in which the semiconductor current is of pulse durations spanning the transition range of the TTZ curve.<>

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Conference Record of the 1993 IEEE Industry Applications Conference Twenty-Eighth IAS Annual Meeting

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