用于交错并联Vienna整流器的三绕组耦合电感及其设计方法

doi:10.19595/j.cnki.1000-6753.tces.242160

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摘要为衰减并网电流高频分量和抑制桥臂间环流,交错并联Vienna整流器每相需要滤波电感与紧耦合电感两个磁性器件,其中紧耦合电感对磁心的利用率较低,使变流器的效率和功率密度难以继续提高。该文针对此问题提出一种三绕组耦合电感,并建立其电路模型和磁路模型,进而提出一种三绕组耦合电感的设计方法。所提三绕组耦合电感通过磁心复用与绕组复用使磁心中的磁通均匀分布并减少绕组匝数,可以降低绕组损耗,尤其适用于大电流应用场景。与滤波电感串联紧耦合电感的传统方案相比,在滤波能力、磁心体积、磁心饱和度和绕组电流密度均不变的前提下,所提三绕组耦合电感使绕组的直流电阻降低了35%,进一步提高了装置的效率。最后,通过有限元仿真与40 kW样机实验的效率对比验证了所设计三绕组耦合电感的可行性和有效性。

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关键词 ： Vienna整流器, 交错并联, 磁集成, 耦合电感

Abstract：Interleaved Vienna rectifiers have been adopted extensively, enhancing power output capability, dispersing loss distribution, improving equivalent switching frequency, and reducing current ripple at the grid side. In the traditional separated scheme, the connecting inductor between the power grid and the converter generally comprises two magnetic components, a filter inductor and a tightly coupled inductor connected in series. The filter inductor is used to attenuate the high-frequency component of the grid current. The tightly coupled inductor forms a large equivalent inductance in the circulating current path to primarily reduce the amplitude of the circulating current between the bridge arms. Both are essential components of the interleaved Vienna rectifier. However, the utilization ratio of the tightly coupled inductor to the magnetic core is low, and two magnetic elements will occupy a larger PCB area. These two reasons make it difficult to improve the power density and efficiency of the interleaved system.
This paper proposes a three-winding coupled inductor that integrates the filter inductor and the coupled inductor on a single magnetic core. The flux in the magnetic core is evenly distributed, and the number of turns of the winding is reduced by reusing the magnetic core and the winding. Firstly, the structure of the proposed three-winding coupled inductor is given, and its equivalent circuit model is analyzed to obtain the relationship between its equivalent fundamental inductance, equivalent circulating inductance, and the self-inductance and mutual inductance of each winding. Secondly, the magnetic circuit model is analyzed to obtain the relationship between each winding’s self and mutual inductances and each magnetic circuit’s magnetic resistance. Then, the design method is given considering the air leakage path, and a three-winding coupled inductor with a rated current of 60 A (RMS value) is designed. Compared with the traditional separated scheme and the two-winding weakly coupled inductor scheme, the DC resistance of the designed three-winding coupled inductor is reduced by 35% and 11%, respectively, with the filter capacity, core volume, core saturation, and winding current density unchanged. The 40 kW three-phase Vienna rectifier using the three-winding coupled inductor achieves a maximum efficiency of 98.5%.
In view of the low utilization of the magnetic core of the tightly coupled inductor in the interleaved Vienna rectifier, this paper proposes a three-winding coupled inductor using integrated magnetic. The proposed inductor reduces losses and improves the power density of the device. Finite element simulation has proved the feasibility and effectiveness of the three-winding coupled inductor. The experiment on the prototype of an interleaved three-phase Vienna rectifier with a rated power of 40 kW proves that the designed three-winding coupled inductor has lower loss than the traditional separated scheme and the two-winding weakly coupled inductor scheme.

Key words： Vienna rectifier interleaved magnetic integration coupled inductor

收稿日期: 2024-12-02

PACS:

TM46

基金资助:省部级重点实验室基金资助项目（6142217）

通讯作者: 宫金武男,1981年生,副教授,博士生导师,研究方向为高效率高功率密度电力电子变换技术、宽禁带半导体器件应用、电能质量分析与治理。E-mail: gongjinwu@whu.edu.cn

作者简介: 王开国男,1998年生,硕士研究生,研究方向为大功率磁元件的综合优化设计。E-mail: wangkaiguo@whu.edu.cn

引用本文:

王开国, 宫金武, 潘尚智, 苑士鑫, 孙宗昌. 用于交错并联Vienna整流器的三绕组耦合电感及其设计方法[J]. 电工技术学报, 2025, 40(24): 7984-7998. Wang Kaiguo, Gong Jinwu, Pan Shangzhi, Yuan Shixin, Sun Zongchang. Three-Winding Coupled Inductor and Its Design Method for Interleaved Vienna Rectifiers. Transactions of China Electrotechnical Society, 2025, 40(24): 7984-7998.

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