Optimal Synergetic Operation and Experimental Evaluation of an Ultra-Compact GaN-Based Three-Phase 10 kW EV Charger

Fast charging of electric vehicles (EVs) requires isolated AC/DC converters with a wide output voltage range of 200V to 1000V. Combining a three-level Vienna Rectifier (VR) with four isolated Dual-Active-Bridge DC/DC Converter (DABC) modules and latest-generation 600V GaN technology enables very high switching frequencies of 560 kHz for the VR and up to 330 kHz for the DABCs. Hence, in this paper an ultra-compact realization of a 10 kW EV charger module with a power density of 9 kW/dm ³ (about 150 W/in ³ ), not including the coldplate, is presented. In this context, a simplified DABC modulation method and straightforward yet accurate (confirmed by experiments) loss models for the DABCs and the VR are introduced, which facilitate a thorough investigation of the optimum synergetic operation of the two stages: For the considered converter, changing the VR operating mode from conventional 3/3-PWM (where the two stages operate rather independently and hence all three VR bridge-legs operate with PWM) to 1/3-PWM (where the DABCs shape the voltage of the shared intermediate DC-link such that always only one of the VR’s three bridge-legs must operate with PWM) results in an advantageous efficiency improvement of up to about 2% over a large part of the output voltage and power range, and in a peak efficiency of more than 97%. Further, the synergetic operation of the two-stage system (VR and DABCs) is experimentally verified for the first time, confirming the modeling results and the efficiency advantage of 1/3-PWM (i.e., 95.4% vs. 95.1% at the rated load of 10 kW and with 500V output voltage). Conducted EMI pre-compliance measurements indicate that the change of the operating strategy from 3/3-PWM to 1/3-PWM only requires minor changes of the EMI filter design.