Realizing Bipolar Power Semiconductor for Highest Reliable Applications

2019 AEIT HVDC International Conference (AEIT HVDC) Pub Date : 2019-05-01 DOI:10.1109/AEIT-HVDC.2019.8740529

J. Przybilla, U. Kellner-Werdehausen, Sebastian P. Sommer

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引用次数: 1

Abstract

During the 1970s thyristors were used for the first time to realize a Line Commutated Converter (LCC) for High Voltage Direct Current (HVDC) transmission lines which decreased power losses and increased reliability. At that time thyristors with a blocking capability of 1.65 kV and a silicon diameter of 35 mm had been specially developed for this application. Nearly 43,000 thyristors were installed in this first transmission line using thyristors, Cahora Bassa, to transfer 1920 MW at ± 533 kV over 1420 km from Mozambique to South Africa. Currently there is a trend to realize HVDC transmission lines increasingly with Voltage Source Converters (VSC). This was further stimulated by the introduction of the Modular Multilevel Converter technology (MMC) which decreased system complexity greatly. Today's installations are built up to ±500 kV and 2 GW and for future projects ±800 kV with 5 GW are under discussion. Although the main semiconductor device in VSCs is the IGBT, classical bipolar devices are critical for VSC operation, too. Special developed diodes with extreme soft switching behavior are used as Free Wheeling Diodes (FWD) and antiparallel thyristors protect the IGBTs in case of surge current events. Recently Press Pack IGBT (PPI) has come into focus as an alternative realization for VSC architectures.

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实现双极功率半导体的最高可靠性应用

在20世纪70年代，晶闸管首次用于实现高压直流(HVDC)输电线路的线路换向转换器(LCC)，从而降低了功率损耗并提高了可靠性。当时专门为这种应用开发了阻断能力为1.65 kV、硅直径为35 mm的晶闸管。在第一条使用晶闸管Cahora Bassa的输电线路上安装了近43,000个晶闸管，以±533千伏的电压将1920兆瓦的功率从莫桑比克传输到1420公里外的南非。目前高压直流输电线路越来越多地采用电压源变流器(VSC)来实现。模块化多电平转换器技术(MMC)的引入进一步刺激了这一趋势，该技术大大降低了系统的复杂性。目前的装机容量为±500千伏和2吉瓦，未来的装机容量为±800千伏和5吉瓦的项目正在讨论中。虽然VSC中的主要半导体器件是IGBT，但经典的双极器件对VSC的运行也至关重要。特别开发的具有极端软开关特性的二极管用作自由旋转二极管(FWD)，反并联晶闸管在浪涌电流事件时保护igbt。最近，Press Pack IGBT (PPI)作为VSC架构的一种替代实现成为人们关注的焦点。

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 AEIT HVDC International Conference (AEIT HVDC)

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