Zero-Backflow Power Control Scheme of Dual Bridge Series Resonant DC–DC Converters With High-Accuracy Time Domain Modeling
Yaru Deng, Wensheng Song, Shuai Yin, Ming Zhong, Jian Chen, Xiaoyun Feng
Abstract
In the fundamental harmonic approximation (FHA) modeling of dual bridge series resonant dc–dc converters (DBSRCs), the approximation error of the FHA model will lead to low accuracy of optimization schemes, which will reduce the efficiency of DBSRCs. In this article, first, the time domain analysis (TDA) modeling of the DBSRC is adopted, which can describe the characteristics of the DBSRC accurately. Second, the extended phase shift modulation based on the TDA modeling is discussed, and the backflow power model with the TDA of the DBSRC is developed. On this basis, a zero-backflow power optimization scheme is proposed. In addition, the effects of dead time are analyzed and the compensation method is proposed. The proposed backflow power optimization method with dead time compensation can achieve zero-backflow power and improve the efficiency of the DBSRC. Especially, the proposed method with TDA modeling is more excellent when DBSRC operates in wide voltage range conditions. Finally, a comprehensive experiment comparison of DBSRC under the minimum current trajectory with FHA modeling and the proposed method with TDA modeling is discussed. The experimental results have verified the effectiveness of the proposed scheme.