用于中压变换器的单通道IGBT栅极驱动器

Q2 Computer Science

International Journal of Electrical and Electronic Engineering and Telecommunications Pub Date : 2021-02-26 DOI:10.11648/J.JEEE.20210901.13

Sokchea Am, P. Chrin, Bunthern Kim, L. Phing.

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引用次数: 0

摘要

本文讨论了中压(MV)应用中IGBT模块的栅极驱动系统。主要研究IGBT栅极驱动器的两个功能:脉冲信号传输和功率传输。对于每个函数，给出了合适的拓扑结构。然后，出于安全和设备保护的原因，所有栅极驱动器功能必须维持高和极高的电绝缘电压能力。为了实现低成本的设计，绝缘系统可以借助罐式铁心平面变压器中的绝缘材料来实现。因此，对于每个功能，锅芯变压器及其相关电子元件的优化设计都是在虚拟原型工具(遗传算法:MATLABTM中的GA代码)的帮助下进行的。第一部分着重于脉冲信号传输函数所选拓扑的优化设计。给出了该函数的双目标(最大输出电压和最小输入电流)问题，该问题导致了Pareto前。在假定不同保温层厚度的情况下，得到了几种帕累托锋面的结果。第二部分着重于电力传输功能的拓扑优化设计。最大变换器效率(ηcon)和最小输出功率(Pout)被认为是一个双目标。因此，对于几种不同的绝缘厚度，可以获得许多帕累托前沿的结果。最后，发明了一个单通道IGBT栅极驱动器的原型来验证所提出的设计。

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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A Single Channel IGBT Gate Drivers for Medium Voltage Converters

This article treats the gate driver system for IGBT modules in Medium-Voltage (MV) applications. The study focuses principally on two functions of an IGBT gate driver: an impulse signal transmission and a power transmission. For each function, the suitable topology is proposed. Then, for safety and device's protection reason, all gate driver functions must sustain the high and very high galvanic insulation voltage capabilities. For low-cost design, the insulation system can be achieved with the help of the insulating material in a pot core planar transformer. Therefore, for each function, the optimized design of a pot-core transformer and its associated electronics components is performed with the help of a virtual prototyping tool (a genetic algorithm: GA code in MATLABTM). The first section focuses on optimization design of a selected topology for an impulse signal transmission function. A bi-objective (maximize the output voltage vout and minimize the input current imos) problem of this function that leads to a Pareto front is presented. Several Pareto fronts’ results are obtained assuming different insulation layers thickness. The second part focuses on optimization design of a selected topology for a power transmission function. Maximize the converter efficiency (ηcon) and minimize the output power (Pout) are considered as a bi-objective. Thus, numerous Pareto fronts’ results are achieved for a few different insulation thicknesses. Finally, the prototype of a single channel IGBT gate driver is invented to validate the proposed design.

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来源期刊

International Journal of Electrical and Electronic Engineering and Telecommunications Engineering-Electrical and Electronic Engineering

CiteScore

5.90

自引率

0.00%

发文量

期刊介绍： International Journal of Electrical and Electronic Engineering & Telecommunications. IJEETC is a scholarly peer-reviewed international scientific journal published quarterly, focusing on theories, systems, methods, algorithms and applications in electrical and electronic engineering & telecommunications. It provide a high profile, leading edge forum for academic researchers, industrial professionals, engineers, consultants, managers, educators and policy makers working in the field to contribute and disseminate innovative new work on Electrical and Electronic Engineering & Telecommunications. All papers will be blind reviewed and accepted papers will be published quarterly, which is available online (open access) and in printed version.