面向输出性能优化的高低频混合型模块化多电平变换器及其调控策略

doi:10.19595/j.cnki.1000-6753.tces.230880

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摘要为破解中压模块化多电平变换器（MMC）输出性能提升与降本、增效难以有效兼顾的问题,该文提出一种基于高低频混合的新型MMC（NMMC）拓扑。NMMC每个桥臂包含1个由异质交叉连接模块（HCCM）构成的高频子模块和N-1个半桥变换器构成的低频子模块。HCCM的高频桥臂采用SiC MOSFET器件,而HCCM的换向桥臂及低频子模块均采用Si IGBT器件。针对NMMC拓扑,该文采用高低频混合调制策略,充分发挥了SiC MOSFET器件开关损耗低、Si IGBT器件通态损耗低的优势。此外,针对高频子模块提出一种特定的电容电压平衡策略,并详细分析高频子模块的工作状态。进一步地,仿真及实验验证了所提拓扑结构、调制策略、均压策略的可行性和有效性。最后,将所提拓扑与现有MMC拓扑在器件成本和运行损耗方面进行综合对比,证明所提拓扑可以更好地平衡装置的成本及效率指标。

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关键词 ：模块化多电平变换器, Si IGBT, SiC MOSFET, 混合调制, 电平数增倍

Abstract：The traditional modular multilevel converter (MMC) generally adopts a single type of device. The typical Si-based MMC (Si-MMC) has low cost, while SiC-based MMC (SiC-MMC) has high efficiency. In addition, under the same specifications, the price of SiC MOSFET devices is usually 5~8 times that of Si IGBT devices. It is difficult to effectively balance the output performance, cost, and efficiency of the medium voltage MMC. This paper proposes a new MMC (NMMC) topology. Each arm of the proposed NMMC contains a high-frequency sub-module featuring a heterogeneous cross-connect module (HCCM) and a low-frequency sub-module composed of N-1 half-bridge converters. The high-frequency bridge arm of HCCM adopts SiC MOSFET devices, while the commutation bridge arm and low-frequency sub-module adopt Si IGBT devices.
Firstly, the NMMC topology employs a high-low frequency hybrid modulation strategy, providing low switching loss of SiC MOSFET devices and low on-state loss of Si IGBT devices. Secondly, the energy fluctuation mechanism and working state of the high-frequency sub-module in different modes are analyzed. A specific capacitor voltage balancing strategy is proposed for the high-frequency sub-module, and a detailed voltage balancing control flow chart is given.
Simulation and experiments are carried out to verify the proposed topology, modulation strategy, and voltage balancing strategy. The proposed structure achieves 2N+1 levels. Its high-frequency switching action is mainly concentrated in SiC MOSFET devices, while Si IGBT devices work in the low-frequency state. The total loss at different equivalent switching frequencies and output power is analyzed on the Matlab/Simulink and PLECS joint simulation platform. Taking the rated load power of 1.5 MW and the equivalent switching frequency of f_eq= 20 kHz as an example, the total loss of the proposed NMMC is 37.5%, lower than that of Si-MMC and close to that of SiC-MMC. The proposed topology is 80% lower cost than the Si-MMC and 51.8% lower than the SiC-MMC.
The following conclusions can be drawn: (1) The NMMC topology outputs 2N+1 levels with only one high-frequency sub-module per arm, reducing the number of SiC MOSFET devices and overall device cost. (2) The high-frequency action primarily involves SiC MOSFET devices, while the low-frequency action of Si IGBT devices is adopted. Under high equivalent switching frequency and output power, the operation efficiency of the proposed scheme is significantly enhanced. (3) The energy fluctuation mechanism of the high-frequency sub-module DC capacitor is analyzed, and a specific voltage balance strategy is proposed, which can effectively maintain the stability of the high and low-frequency sub-module capacitor voltage.

Key words： Modular multilevel converter Si IGBT SiC MOSFET hybrid modulation level number doubled

收稿日期: 2023-06-09

PACS:

TM464

基金资助:国家自然科学基金（52130704）和湖南省研究生科研创新（CX20230430）资助项目

通讯作者: 郭祺, 男,1993年生,副研究员,研究方向为电力电子变换器、分布式发电与电能质量先进控制。E-mail: qguo_215@163.com

作者简介: 侯玉超, 男,1997年生,博士,研究方向为电力电子在电力系统中的应用。E-mail: houyuchaoyx@163.com

引用本文:

侯玉超, 郭祺, 涂春鸣, 王鑫, 汪颖. 面向输出性能优化的高低频混合型模块化多电平变换器及其调控策略[J]. 电工技术学报, 2024, 39(14): 4467-4479. Hou Yuchao, Guo Qi, Tu Chunming, Wang Xin, Wang Ying. A High and Low Frequency Hybrid Modular Multilevel Converter for Output Performance Optimization and Its Control Strategy. Transactions of China Electrotechnical Society, 2024, 39(14): 4467-4479.

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