Switching Loss Reduction for an MMC-Fed AC/DC Converter

IF 5 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE open journal of power electronics Pub Date : 2023-12-14 DOI:10.1109/OJPEL.2023.3343330

Kaveh Pouresmaeil;Maurice G.L. Roes;Nico H. Baars;Cornelis G.E. Wijnands

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Abstract

Medium-voltage connected ultra-fast chargers are getting more popular for charging electric vehicles with large battery capacities. Here, the solution based on a modular multilevel converter is more promising, since the isolation stage can be realized as a single medium-frequency transformer interconnecting the modular multilevel converter to a single-phase ac/dc converter. A new operating scheme is proposed for this converter, enabling zero-voltage switching and nearly zero-current switching across the entire load range. In contrast to the conventional phase-shift control method, the proposed scheme effectively reduces the reactive power through the ac/dc converter, leading to decreased turn-off switching losses in the ac/dc converter and a lower RMS current stress in the power path. A control scheme, integrating the operating principle, is developed for the modular multilevel converter. The method is verified through simulation and measurements on a scaled-down prototype. The results validate the theoretical analysis and practical feasibility of the proposed operating principle and the developed control scheme.

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降低 MMC 供电交直流转换器的开关损耗

中压连接超快速充电器在为大容量电池电动汽车充电方面越来越受欢迎。在这里，基于模块化多电平转换器的解决方案更有前途，因为隔离级可以通过将模块化多电平转换器与单相交流/直流转换器互连的单个中频变压器来实现。我们为这种转换器提出了一种新的运行方案，可在整个负载范围内实现零电压开关和近乎零电流开关。与传统的移相控制方法相比，所提出的方案能有效降低通过交流/直流转换器的无功功率，从而减少交流/直流转换器的关断开关损耗，降低功率路径中的有效值电流应力。为模块化多电平转换器开发了一种控制方案，其中集成了工作原理。该方法通过对缩小原型的模拟和测量进行了验证。结果验证了所提出的工作原理和所开发的控制方案的理论分析和实际可行性。

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