七电平有源中点钳位式逆变器中飞跨电容电压平衡的移相调控方法

doi:10.19595/j.cnki.1000-6753.tces.242148

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摘要七电平有源中点钳位式（ANPC）拓扑能有效降低滤波电感需求,有望实现更高的功率密度和效率,但移相脉冲宽度调制（PS-PWM）下飞跨电容的电压调节能力有限,而飞跨电容电压不平衡会恶化变换器的可靠性和输出电能质量。为此,该文基于PS-PWM技术提出一种飞跨电容电压调控方法,该方法通过修正飞跨单元PWM信号相位以调节电感电流纹波形状,从而改变飞跨电容充/放电电流,原理上不受负载电流极性影响,不改变变换器输出等效占空比。在0~1/3与2/3~1占空比下,源侧飞跨电容和载侧飞跨电容存在独立充/放电区域,改变对应PWM信号相位,可以改变飞跨电容充/放电状态下的电感电流幅值而不改变充/放电时间,定向调整飞跨电容电压;在1/3~2/3占空比下,PWM相位变化同时影响飞跨电容充/放电电流幅值及时间,推导相关数学模型确定单一PWM相位自由度下两级飞跨电容的充/放电状态,采用飞跨电容电压迟滞比较控制可以改善此占空比范围内的电压偏移情况。因此,所提修正PWM相位方法可在0~1占空比范围内改善飞跨电容的电压不平衡问题。

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关键词 ：七电平, 有源中点钳位, 飞跨电容, 移相脉冲宽度调制, 电压调控

Abstract：The 7-level active neutral point clamped (ANPC) topology effectively reduces the need for filter inductance, offering the potential for higher power density and efficiency. However, under phase-shifted pulse width modulation (PS-PWM), the voltage regulation capability of the flying capacitors is limited, and imbalances in flying capacitor voltage can degrade converter reliability and output power quality. This paper proposes a flying capacitor voltage regulation method based on PS-PWM. This method adjusts the PWM phase of the flying capacitor unit to modulate the ripple shape of the inductor current, thereby modifying the charging/discharging current of the flying capacitor. The method is fundamentally unaffected by load current polarity and does not alter the effective duty cycle of the converter output.
In the 0~1/3 modulation range, the charging current of the source-side flying capacitor is primarily related to the inductor current during the high-level period of the PWM-A signal near the source side. It is independent of the high-level periods of PWM-B and PWM-C signals. Moreover, the high-level period of the PWM-A signal does not affect the charging and discharging process of the load-side flying capacitor. Given a duty ratio D, adjusting the phase φ_A of the PWM-A signal can linearly modulate the average amplitude of the corresponding inductor current ripple without changing its ripple duration. This adjustment allows precise control of the source-side flying capacitor’s charge over the switching period, thereby regulating its voltage. During this process, the charging/discharging state of the flying capacitor only occurs during the high-level periods of the PWM-A, PWM-B, and PWM-C signals. By ensuring that the high-level periods of the PWM signals do not overlap, the source-side flying capacitor voltage can be independently controlled without affecting the load-side flying capacitor. Similarly, adjusting the phase φ_C of the PWM-C signal can linearly modulate the discharge current amplitude of the load-side flying capacitor. As long as the high-level periods of the PWM signals do not overlap, the load-side flying capacitor voltage can be independently controlled.
In the 1/3~2/3 modulation range, changes in the PWM signal phases affect the flying capacitor’s charging and discharging current amplitude and duration. By deriving the phase-shift modulation model of the average charging current of the source-side and load-side flying capacitors over the switching period concerning the PWM-A and PWM-C signal phases φ_A and φ_C, the charging/discharging states of the two-stage flying capacitors can be determined under the single PWM phase degree of freedom. An appropriate voltage modulation strategy can be selected depending on the degree of flying capacitor voltage offset. Subsequently, adjusting the phases of PWM-A or PWM-C can improve the voltage offset of the flying capacitors and optimize the voltage balance between the source and load-side flying capacitors.
In the 2/3~1 modulation range, the charging and discharging states of the flying capacitors occur during the low-level periods of the PWM-A, PWM-B, and PWM-C signals. The regulation principle in this range is similar to that in the 0~1/3 modulation range. In this case, adjusting the phases φ_A and φ_C of the low-level periods of PWM-A and PWM-C signals can achieve independent and linear voltage regulation for the source-side and load-side flying capacitors.
Thus, the proposed improved PS-PWM phase modulation method can effectively address the voltage imbalance in the flying capacitors over the entire 0~1 modulation range.

Key words： Seven-level active neutral point clamp (ANPC) flying capacitor phase-shifted pulse width modulation (PS-PWM) voltage regulation

收稿日期: 2024-11-29

PACS:

TM464

基金资助:国家重点研发计划资助项目（2024YFB4007504）

通讯作者: 丰昊男,1991年生,副教授,博士生导师,研究方向为宽禁带功率半导体器件及应用。E-mail: hfeng6@cqu.edu.cn

作者简介: 李祥男,1999年生,硕士研究生,研究方向为多电平变换器调制方法及应用。E-mail: lixiang@stu.cqu.edu.cn

引用本文:

李祥, 丰昊, 冉立. 七电平有源中点钳位式逆变器中飞跨电容电压平衡的移相调控方法[J]. 电工技术学报, 2025, 40(24): 8066-8079. Li Xiang, Feng Hao, Ran Li. Phase-Shift Method for Seven-Level Active Neutral Point Clamped Inverter Flying Capacitor Voltage Control. Transactions of China Electrotechnical Society, 2025, 40(24): 8066-8079.

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