基于GaN器件的双面散热电源模块寄生电容特性研究

2020 IEEE Workshop on Wide Bandgap Power Devices and Applications in Asia (WiPDA Asia) Pub Date : 2020-09-23 DOI:10.1109/WiPDAAsia49671.2020.9360259

Bingyang Li, Kangping Wang, Hongkeng Zhu, Xu Yang, Laili Wang

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引用次数: 1

摘要

本文分析了一种新型氮化镓功率模块双面冷却结构的寄生电容。由于结构的顶部附加陶瓷衬底，寄生电容变得更加复杂。通过分析，所有GaN器件的栅源寄生电容和栅漏寄生电容以及半桥电路GaN器件的上极漏源寄生电容均小于其固有电容的1%。然而，与传统的单面冷却模块相比，半桥电路底部GaN器件的漏源寄生电容(损耗的14%)增加了30%，这是可以接受的，因为这种结构的热阻大约减半。

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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Parasitic Capacitances Characterization of Double-Sided Cooling Power Module Based on GaN Devices

The parasitic capacitances of a novel double-sided cooling structure of GaN power module are analyzed in this paper. Due to the additional top ceramic substrate of the structure, parasitic capacitances become more complex. By analysis, gate-source parasitic capacitance and gate-drain parasitic capacitance of all GaN devices and drain-source parasitic capacitance of upper GaN device of half bridge circuit are less than 1% of the corresponding intrinsic capacitances. However, the drain-source parasitic capacitance (14% of Coss) of bottom GaN device of half bridge circuit increases by 30% compared with traditional single-sided cooling module, which is acceptable since the thermal resistance of this structure is about halved.

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2020 IEEE Workshop on Wide Bandgap Power Devices and Applications in Asia (WiPDA Asia)

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