A Novel Feedforward Scheme for Enhancing Dynamic Performance of Vector-Controlled Dual Active Bridge Converter with Dual Phase Shift Modulation for Fast Battery Charging Systems

feedforward control dual active bridge dynamic performance enhancement battery charging battery charging; constant current-constant voltage; dual active bridge; dual-phase shift modulation; dynamic performance enhancement; feedforward control; linear active disturbance rejection control; soft switching; vector control vector control soft switching constant current-constant voltage Settore IINF-01/A - Elettronica dual-phase shift modulation linear active disturbance rejection control 530 620
DOI: 10.3390/electronics13193791 Publication Date: 2024-09-24T12:54:17Z
ABSTRACT
This paper proposes a novel feedforward control scheme to achieve a very smooth transition from Constant Current (CC) to Constant Voltage (CV) charging modes, the commonly used method for electric vehicle charging applications. Furthermore, a three-loop model-independent Linear Active Disturbance Rejection Control (LADRC)-based system is proposed, replacing the traditional two-loop Proportional-Integral (PI) control system. The extra loop performs a decoupled dq vector control of the inductor current, which is typically not used in single-phase Dual Active Bridge (DAB) systems. This additional loop not only facilitates the optimal determination of both internal and external phase shift angles of a Dual-Phase Shift (DPS) modulator but also lowers the peak input current of the converter, allowing for lower-rated switches. Numerical simulations using MATLAB/Simulink demonstrate the robustness of the proposed control strategy against both input voltage disturbances and load disturbances during the transition from CC to CV charging modes. Hence, the dynamic performance of the charging system is significantly improved with minimal controller effort.
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