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浙江大学学报(工学版)
浙江大学学报(工学版)  2026, Vol. 60 Issue (7): 1494-1503    DOI: 10.3785/j.issn.1008-973X.2026.07.012
电气工程     
基于移相均压控制的模块化LCC谐振变换器
孙晖(),张茂梁,方宇辰,刘辰昊,韩尚君,季瑞松
浙江大学 电气工程学院,浙江 杭州 310027
Modular LCC resonant converter based on phase-shift voltage balancing control
Hui SUN(),Maoliang ZHANG,Yuchen FANG,Chenhao LIU,Shangjun HAN,Ruisong JI
College of Electrical Engineering, Zhejiang University, Hangzhou 310027, China
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摘要:

针对模块化LCC谐振变换器中不同模块间谐振参数的偏差导致输出侧严重不均压的问题,利用动态相量法,对LCC谐振变换器进行大信号建模,并将其推广至多模块场景,提出用于移相控制下多模块IPOS-LCC谐振变换器的通用大信号模型. 在此基础上,设计移相均压算法,通过模块内与模块间的移相控制,解决由谐振参数偏差引发的输出侧不均压问题,并降低输出电压纹波. 搭建2 kV输出的三模块IPOS-LCC谐振变换器样机,对提出的移相均压算法进行实验验证. 结果表明,移相均压算法显著降低了实验样机在全输出范围内的电压不平衡度,并有效抑制了总输出电压纹波;在实验样机的启动动态过程中,其仍然能够实现良好的均压效果,使样机各模块的输入电流更加平衡,系统效率提升. 所提算法能够有效提高模块化LCC谐振变换器的输出性能.
关键词: LCC谐振变换器模块化输入并联输出串联IPOS移相控制均压控制高压电源    
Abstract:

Aiming at the severe output voltage imbalance in modular LCC resonant converters caused by resonant parameter deviations among different modules, a large-signal model for LCC resonant converters was established using the dynamic phasor method. This model was extended to multi-module configurations, and a universal large-signal model for multi-module IPOS-LCC resonant converters under phase-shift control was proposed. On this basis, a phase-shift voltage balancing algorithm was designed to resolve the output voltage imbalance induced by resonant parameter variations and reduce the output voltage ripple through intra-module and inter-module phase-shift control. Experimental verification was performed on a three-module IPOS-LCC resonant converter prototype with 2 kV output. The results demonstrated that the phase-shift voltage balancing algorithm significantly reduced the voltage imbalance across the full output range while suppressing the overall output voltage ripple. Effective voltage equalization was realized during the startup transients of the experimental prototype, with improved input current balance among modules and enhanced system efficiency. The proposed algorithm effectively improves the output performance of modular LCC resonant converters.
Key words: LCC resonant converter    modular input-parallel output-series    IPOS    phase-shift control    voltage balancing control    high voltage power supply
收稿日期: 2025-03-27 出版日期: 2026-05-23
CLC:  TM 46  
基金资助: 国家重点研发计划“基础科研条件与重大科学仪器设备研发”资助项目(2023YFF0723700).
作者简介: 孙晖(1971—),男,副教授,博士,从事信号分析处理、高压电源研究. orcid.org/0000-0001-6497-4478. E-mail:ee_sun@zju.edu.cn
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引用本文:

孙晖,张茂梁,方宇辰,刘辰昊,韩尚君,季瑞松. 基于移相均压控制的模块化LCC谐振变换器[J]. 浙江大学学报(工学版), 2026, 60(7): 1494-1503.

Hui SUN,Maoliang ZHANG,Yuchen FANG,Chenhao LIU,Shangjun HAN,Ruisong JI. Modular LCC resonant converter based on phase-shift voltage balancing control. Journal of ZheJiang University (Engineering Science), 2026, 60(7): 1494-1503.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2026.07.012        https://www.zjujournals.com/eng/CN/Y2026/V60/I7/1494

图 1  LCC谐振变换器的典型拓扑结构
图 2  PSM控制下LCC谐振变换器的工作模态
图 3  PSM控制下LCC谐振变换器的时域波形
图 4  单模块LCC谐振变换器的大信号模型
图 5  多模块IPOS-LCC谐振变换器拓扑结构
图 6  多模块LCC谐振变换器的大信号模型
图 7  多模块IPOS-LCC谐振变换器移相均压控制框图
图 8  移相均压控制算法流程图
参数数值参数数值
Ui/V100Cp1/nF4.714
Uo/kV2Lr2/mH1.275
R/kΩ150Cr2/nF15.226
M3Cp2/nF4.698
fPFM/kHz90~150Lr3/mH1.234
fPSM/kHz100Cr3/nF9.801
$ {\varphi _m} $0~2π/3Cp3/nF5.539
Lr1/mH1.565C/nF7.333
Cr1/nF11.901n7
表 1  样机详细参数
图 9  2 kV三模块IPOS-LCC谐振变换器样机
图 10  额定输出条件下样机输出波形对比
图 11  不同控制策略下的样机启动动态过程对比
图 12  全输出范围内不同控制策略下的均压效果对比
图 13  不同控制策略下样机的效率曲线
图 14  不同控制策略下样机的谐振电流对比
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