非对称方波调制下模块化多电平固态变压器传输功率建模与特性分析

doi:10.19595/j.cnki.1000-6753.tces.231957

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摘要相比于双有源桥级联式固态变压器,模块化多电平换流器H桥（MMC-H）固态变压器仅用单个高频隔离变压器且控制灵活,故障容错率高。但现有MMC-H固态变压器主要采用方波-方波调制,存在系统dv/dt应力和电流谐波大的问题。MMC灵活的非方波调制技术具有优化电压和电流性能良好的前景,但其传输模型和特性未知,极大地限制了MMC-H固态变压器的应用。该文提出正弦-方波、三角-方波两类非对称方波调制下的MMC-H固态变压器的精准功率传输建模和控制方法,揭示其功率传输和电流变化特性,确定最大传输功率点。此外,详细对比两类非方波调制和传统方法下的传输特性差异并阐明原因。结果表明,所提两类非对称调制波和控制方法下的传输功率模型平均误差分别为2.8%和3.4%,准确度高;所提正弦-方波调制和控制方法下在最大传输功率、传输电流峰值、谐波量和器件损耗等方面具有综合最优性能,并具有良好的动态稳定性和快速响应能力。

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关键词 ：模块化多电平变流器, 固态变压器, 功率特性, 非方波调制, 谐波抑制

Abstract：The MMC-H solid-state transformer (SST) uses one high-frequency transformer, greatly reducing the system volume and cost, which is suitable for high to low-voltage conversion scenarios such as distributed energy access and electric vehicle charging stations. However, SST, including MMC-H, typically uses symmetrical square wave modulation to improve transmission power capabilities, leading to the high content of current harmonics. Besides, considering the high voltage level on the MMC side, square wave modulation can make MMC-H experience extremely high dv/dt stress, posing a severe challenge to transformer insulation. Therefore, this paper proposes two asymmetric modulation methods based on MMC topology and studies the current and power variation characteristics of MMC-H SST.
Firstly, this paper proposes the sine-square and triangle-square modulation for MMC-H SST. Based on the proposed SST circuit equivalent model, the power and current expressions for MMC-H under the proposed modulation are presented. The variation of transmission current with power is analyzed, and the reasons for the current difference between different modulations are elucidated. Finally, this paper proposes the overall closed-loop control scheme of MMC-H under asymmetric modulation. The control method includes output voltage closed-loop control, MMC high-frequency nearest level modulation method, and MMC submodules voltage balance control.
The power characteristic curve and current waveform are verified on Matlab/Simulink. Simulation results show that the average errors of the transmission power model with the proposed two modulations are 2.8% and 3.4%, respectively. A hardware-in-the-loop (HIL) experimental platform based on the FPGA and DSP control board has been constructed. The experiment verifies the voltage, current waveform, current peak, and harmonic content of the system at different transmission power. The average error of the proposed modeling method is 5.71%. In addition, dynamic experiments are conducted on the SST system, and the MMC-H SST still has good dynamic stability and fast response ability at asymmetric modulation.
Finally, a comparison is made between the proposed modulation and traditional square wave modulation. Meanwhile, the losses and efficiency of the 1 MW MMC-H SST system are calculated. The following conclusions are drawn from simulation and experimental results. (1) Compared with the traditional square wave modulation, the proposed two modulations reduce the MMC-H system dv/dt stress and current harmonics. (2) The proposed sine-square modulation achieves optimal overall system performance in terms of power variation, current waveform, peak value, and harmonic content. (3) Under steady state and dynamic conditions, the system is stable and consistent with the theoretical waveforms. Therefore, the proposed asymmetric method does not affect the system’s dynamic performance. This paper provides good theoretical support for the optimization and application promotion of the novel MMC-H SST.

Key words： Modular multilevel converter (MMC) solid state transformer (SST) power characteristics non-square modulation harmonic suppression

收稿日期: 2023-11-23

PACS:

TM46

基金资助:重庆市自然科学基金面上项目（cstc2021jcyj-msxmX0871）和重庆英才计划项目（cstc2021ycjh-bgzxm0344）资助

通讯作者: 潘建宇男,1989年生,博士,教授,研究方向为中高压电力变换与控制,SiC电驱动和高电压放电防护技术。E-mail: panjianyu@cqu.edu.cn

作者简介: 杜翊豪男,1999年生,硕士,研究方向为大功率电力变换与控制技术。E-mail: ld10061119@cqu.edu.cn

引用本文:

潘建宇, 杜翊豪, 林文琦, 陈伟根. 非对称方波调制下模块化多电平固态变压器传输功率建模与特性分析[J]. 电工技术学报, 2024, 39(24): 7793-7806. Pan Jianyu, Du Yihao, Lin Wenqi, Chen Weigen. Power Modeling and Operation Characteristics of Modular Multilevel Converter-H Solid State Transformer under Asymmetric Square Wave Modulation. Transactions of China Electrotechnical Society, 2024, 39(24): 7793-7806.

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