基于扩展移相下考虑死区时间效应的双有源桥变换器运行特性分析

doi:10.19595/j.cnki.1000-6753.tces.250955

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摘要随着开关频率的不断提升,死区时间在开关周期中所占比例显著增加,使得死区时间效应对双有源桥（DAB）变换器的影响日益凸显。该文深入研究DAB变换器在扩展移相（EPS）控制下的死区时间效应,通过对单一桥臂进行理论分析,得出一次、二次侧H桥的输出电压特性和各桥臂输出电压在不同驱动信号时间段下的输出特性。基于桥臂理论,依据电感电流过零点与各桥臂死区时间之间的相对位置,提出考虑死区时间效应的EPS运行模式分类方法,为系统分析提供了新的视角,并揭示了电压跌落、极性反转等一系列死区时间所导致的电压失真现象的机制。理论分析表明,死区时间效应会显著改变传输功率特性,该文对不同运行模式进行约束条件求取和传输功率计算,提出基于死区时间占比M与电压传输比k的传输功率修正模型,量化了死区效应所导致的功率特性偏移,并通过分析模式运行区域为死区参数设计提供了参考。最后,通过实验验证了该文理论分析的正确性,为DAB变换器的优化设计提供了重要参考依据。

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关键词 ：双有源桥变换器, 死区时间效应, 扩展移相（EPS）, 电压失真, 传输功率特性

Abstract：Dual-active-bridge (DAB) converters are widely used in power conversion systems due to their advantages, including high-frequency isolation, simple and symmetrical structure, high power density, and soft-switching capability. Existing research on optimized control strategies for DAB converters is primarily based on traditional ideal models that generally neglect dead time. Moreover, most studies on dead-time focus on specific shift modes under single-phase or multiple-phase shift control. Focusing on the increased dead-time effect caused by higher switching frequency, this paper investigates the operating characteristics of dual- active-bridge converters under extended-phase-shift (EPS) control in the presence of dead-time.
First, based on a simplified equivalent model of the DAB circuit, with a single bridge arm as the object of study, the influence of dead time on the converter's operating waveform is analyzed. The output square-wave voltage of the H-bridge on both sides is determined by the combination of switching devices through which the current flows. The output voltage of a single bridge arm is related only to the driving signal during non-dead-time periods of conduction. The direction of the inductor current determines it during dead-time periods without conduction signals. Secondly, based on the bridge arm theory and the position relationship between the zero-crossing point of the inductor current and the dead-time period of each bridge arm, the DAB converter under EPS control is categorized into 23 operating modes, and the inequality constraints for each mode are established. A transmission power correction model based on the voltage conversion ratio k and the dead-time ratio M is also developed to quantify the influence of dead-time on the transmission power characteristic curve. Subsequently, the converter's operating characteristics under dead time are analyzed. Across different combinations of constraints and phase-shift ratios, the dead-time effect exhibits distinct phenomena that significantly alter the converter's transmission power characteristics. The impact of the voltage conversion ratio k and the dead-time ratio M on the transmission power characteristics is compared. Moreover, a distribution diagram of operating modes across the entire operating range is constructed. Once a specific k-M relationship is satisfied, the distortion modes within a particular area can be eliminated. Then, the transmission power correction mode is further simplified based on classification criteria for boundary conditions and dead-zone phenomena. Finally, the theoretical analysis is verified using the experimental platform.
The following conclusions can be drawn. (1) The addition of dead-time causes a series of different dead-time effects in the converter under specific operating parameters and switch combinations. (2) The dead-time ratio M causes a deviation between the actual power model in operation and the traditional ideal power model, and the deviation is more significant when the external phase shift ratio D₂ is small, or the converter is operating in a light-load mode. (3) The proposed power correction model can accurately characterize the transmission characteristics of the converter under actual operating conditions, providing a basis for the precise power control and dead-time compensation design of DAB converters.

Key words： Dual-active-bridge converter dead-time effect extended-phase-shifting (EPS) voltage distortion transmission power characteristics

收稿日期: 2025-06-04

PACS:

TM46

基金资助:智能电网国家科技重大专项（2024ZD0801300）和宁波市“科创甬江2035”关键技术（2024Z141）资助项目

通讯作者: 陈剑飞男,1987年生,教授,博士生导师,研究方向为DC-DC变换器、多电平变换器和可再生能源发电技术等。E-mail: jianfei@whu.edu.cn

作者简介: 魏光灿男,2000年生,硕士研究生,研究方向为新能源发电技术、电力电子变换器。E-mail: guangcanwei@whu.edu.cn

引用本文:

魏光灿, 陈剑飞, 何怡刚, 吴聪. 基于扩展移相下考虑死区时间效应的双有源桥变换器运行特性分析[J]. 电工技术学报, 2026, 41(10): 3353-3369. Wei Guangcan, Chen Jianfei, He Yigang, Wu Cong. Analysis of the Operating Characteristics of Dual-Active-Bridge Converter Considering the Effect of Dead-Time under Extended-Phase-Shift Operation. Transactions of China Electrotechnical Society, 2026, 41(10): 3353-3369.

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