基于对称控制的三相并网变流器单输入单输出阻抗建模与分析

doi:10.19595/j.cnki.1000-6753.tces.222388

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摘要三相并网变流器的不对称控制结构会导致频率耦合效应,降低其接入弱电网的稳定裕度,增加了阻抗分析的复杂度。首先,该文提出一种三相并网变流器的对称控制策略,以消除由锁相环和直流电压环引起的频率耦合效应。该控制策略通过在控制环路中引入直流电压环q轴补偿,以形成对称的直流电压闭环结构,同时引入对称锁相环,消除传统锁相环的非对称动态特性。因此,三相并网变流器可建模为单输入单输出的阻抗复矢量形式,进而可采用标准奈奎斯特准则进行阻抗稳定性分析,能够直观地说明控制器对系统阻抗特性的主导作用。然后,对并网变流器的阻抗特性进行分析,得出弱电网中对称锁相环的带宽对系统稳定性有着至关重要的影响,并且,不同运行工况也会改变并网变流器的阻抗特性,进而影响系统的稳定性。最后,仿真和实验结果验证了所提控制策略对频率耦合效应抑制的有效性以及阻抗特性分析的准确性。

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关键词 ：三相并网变流器, 频率耦合, 对称控制, 弱电网, 稳定性分析

Abstract：With the development of renewable energy power systems, three-phase grid-tied converters (GTCs) are widely used as grid-tied interfaces of wind, solar, and battery systems. Because renewable sources are distributed in remote areas, long-distance transmission lines result in a weak grid. In the weak grid, the asymmetric control structure of a three-phase gird-tied converter leads to frequency coupling, which is not conducive to the stability of the system and the design of the controller. Therefore, a symmetric control strategy is proposed to compensate for the asymmetry of the dq axis caused by the phase-locked loop (PLL) and DC-link voltage control (DVC). Then, the frequency coupling effect is eliminated, and GTCs are modeled as a single-input and single-output (SISO) admittance complex vector. The stability analysis based on the SISO admittance can reveal the inducement of system oscillation and simplify the parameters design of the controller.
Firstly, the dq-frame admittance model of the DVC-embedded GTC with the conventional control strategy is developed, and the instantaneous power balance of the filter is considered for accuracy. Then, the unified impedance modeling approach transforms the real admittance matrix into the complex admittance. Since the dq axis is asymmetric, the complex conjugate components of the PCC voltage and current are introduced, and the frequency coupling effect is inevitable. Consequently, the symmetric PLL (SPLL) and the q-axis compensation of DVC are introduced. Compared with the synchronous reference frame PLL (SRF-PLL), SPLL controls the q-axis and d-axis of common coupling (PCC) voltage points. Therefore, the output of the SPLL is a complex vector angle that tracks the amplitude and phase of the PCC voltage. For DVC, to compensate for the asymmetry of q-axis control, q-axis voltage feedforward compensation and q-axis current feedback compensation are introduced, respectively, effectively eliminating the conjugate components of the DVC. Moreover, the accuracy of the symmetric control model is verified by the sweep frequency method. The sweep frequency results show that the diagonal elements are equal, and the off-diagonal elements are opposite in the dq-frame admittance matrix. In other words, GTC becomes a symmetric system, and the frequency coupling is suppressed. The simulation results demonstrate that the proposed scheme does not affect the dynamic and steady-state performance of the system.
Besides, based on the SISO model, the admittance characteristics of GTC are analyzed. The influencing factors of the admittance characteristics are divided into two parts, namely, the control parameters and the operating conditions. In the control system, high-bandwidth SPLL can cause the system to oscillate, while the DVC parameter changes have little effect on stability. Furthermore, oscillations are triggered when inductive reactive power is injected into the system, while the opposite is true when capacitive reactive power is injected. Further analysis shows that the SPLL dominates the GTC phase characteristics in the low-frequency band. The parallel admittance introduced by the SPLL dynamics has a negative resistance effect, significantly reducing the system stability margin. The experimental results verify the effectiveness of the proposed symmetric control strategy and the accuracy of the theoretical analysis.
The conclusions of this paper can be summarized as follows: (1) By introducing the SPLL and q-axis compensation of DVC, the frequency coupling effect of GTC is eliminated. (2) Based on the analysis of SISO admittance characteristics, SPLL dominates the frequency characteristics of GTC in the low-frequency band, and its negative resistance characteristics lead to system instability. (3) Different operating conditions affect the admittance characteristics of GTC. The injection of inductive reactive power is detrimental to system stability, and the injection of capacitive reactive power is the opposite.

Key words： Three-phase grid-tied converter frequency coupling symmetric control weak grid stability analysis

收稿日期: 2023-01-03

PACS:

TM46

基金资助:国家重点研发计划资助项目（2021YFB2601600, 2021YFB1600203）

通讯作者: 程鹏男,1988年生,博士,副研究员,硕士生导师,研究方向为新能源电力系统、新能源动力系统。E-mail: p.cheng@ncepu.edu.cn

作者简介: 王震男,1996年生,博士研究生,研究方向新能源并网技术、能源交通融合。E-mail: wangzhen@ncepu.edu.cn

引用本文:

王震, 程鹏, 贾利民. 基于对称控制的三相并网变流器单输入单输出阻抗建模与分析[J]. 电工技术学报, 2024, 39(6): 1777-1791. Wang Zhen, Cheng Peng, Jia Limin. Single-Input Single-Output Impedance Modeling and Analysis of Three-Phase Grid-Tied Converter Based on Symmetric Control. Transactions of China Electrotechnical Society, 2024, 39(6): 1777-1791.

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