基于SHEPWM的永磁同步电机电流闭环控制策略

doi:10.19595/j.cnki.1000-6753.tces.241563

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摘要受逆变器容许开关频率限制, 高速或大功率驱动系统存在低载波比运行工况, 常规异步脉宽调制（PWM）低次谐波较大。特定谐波消除脉宽调制（SHEPWM）能有效消除低次谐波, 但其指令电压的周期性更新特征制约了矢量控制算法的应用。锁相环的引入提升了指令电压的更新速度, 但受到谐波消除算法的制约, 动态过程中实际输出电压偏差较大, 动态响应性能依然不高。为此, 该文提出一种基于占空比自适应补偿的SHEPWM电流闭环控制方案。该方案依据电流控制误差对占空比进行自适应补偿, 从而在无需不同调制策略切换的情况下实现了系统动态响应速度和稳态谐波消除特性的统一。在分析电压偏差影响的基础上, 讨论了占空比补偿方案机理及其实现方案。为验证方案的有效性, 在电动汽车驱动电机实验平台上对算法进行了测试。

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关键词 ：占空比补偿, 特定谐波消除, 锁相环, 矢量控制

Abstract：Regarding high-speed electric drives, the ratio of the switching to the fundamental frequency is low due to the limited switching frequency allowed. As a result, the low-order harmonics of conventional asynchronous pulse width modulation are relatively large. Selective harmonic elimination pulse width modulation (SHEPWM) can effectively eliminate low-order harmonics. Still, the actual output voltage deviation is relatively large during the dynamic process, which affects the dynamic performance of the field-oriented control system. To suppress the influence of deviation voltage on the system, this paper proposes a SHEPWM current closed-loop control scheme based on duty cycle adaptive compensation.
Firstly, the current closed-loop implementation scheme of SHEPWM is introduced. This scheme achieves phase matching between field-oriented control and synchronous modulation by utilizing a phase-locked loop. Through the discretization modeling of the phase-locked loop, a theoretical basis is provided for parameter tuning. Subsequently, the influence of the control instructions of the SHEPWM algorithm and the actual output volt-second imbalance of the inverter on the control system is analyzed. This paper proposes a duty cycle compensation method based on current error and designs a dynamic weighting factor through a nonlinear error function for duty cycle compensation. This scheme eliminates the deviation voltage in the dynamic process, thereby improving dynamic performance. During the steady-state process, the deviation voltage is not compensated, thereby ensuring the steady-state harmonic performance of SHEPWM.
Experiments were conducted on the 18 kW IPMSM hardware platform. At the rated rotational speed, compared with the traditional F-SHE modulation scheme, the dynamic regulation time of D-SHE is shortened from 45ms to 22 ms, and the current overshoot during the dynamic process is significantly reduced. During the steady-state process, the duty cycle compensation amount of D-SHE is approximately 0, thus ensuring the harmonic elimination performance. The fifth and seventh harmonics of the stator current are reduced to 2.4% and 2.8% respectively, and the total harmonic distortion is like that of the P-SHE modulation strategy without duty cycle compensation.
The following conclusions can be drawn. (1) The complete SHE switching period is equivalent to being divided into 12 switch sequences. The current sampling points are fixed at the starting points of the ideal spatial vector, achieving phase synchronization and ensuring the stability of the switch sequence. (2) Optimizing the synchronous modulation strategy: Due to its fixed switching time, the actual output voltage deviation during the dynamic process affects the dynamic response performance of the control system. (3) The proposed strategy designs an adaptive dynamic weighting factor through a nonlinear error function. During the dynamic response process, the duty cycle deviation is adaptively compensated by correcting the switching time. However, when the system is in steady-state conditions, the duty cycle deviation of the switching Angle of SHEPWM is not corrected, thus not affecting the harmonic elimination characteristics in the steady-state conditions.

Key words： Duty cycle compensation selective harmonic elimination phase-locked loop vector control

收稿日期: 2024-09-04

PACS:

TM351

基金资助:国家自然科学基金资助项目（52477186）

通讯作者: 杨淑英男, 1980年生, 教授, 博士生导师, 研究方向为风力发电系统、电驱动系统。E-mail: yangsyhfah@163.com

作者简介: 蔡展鹏男, 2000年生, 硕士, 研究方向为永磁同步电机驱动控制。E-mail: 2022170428@mail.hfut.edu.cn

引用本文:

蔡展鹏, 杨淑英, 王奇帅, 王辉. 基于SHEPWM的永磁同步电机电流闭环控制策略[J]. 电工技术学报, 2025, 40(20): 6460-6473. Cai Zhanpeng, Yang Shuying, Wang Qishuai, Wang Hui. Current Closed-Loop Control Strategy of Permanent Magnet Synchronous Motor Based on SHEPWM. Transactions of China Electrotechnical Society, 2025, 40(20): 6460-6473.

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