Modified Three-Phase Three-Level DC/DC Converter With Zero-Voltage-Switching Characteristic-Adopting Asymmetrical Duty Cycle Control

In the applications for high-power dc/dc conversion, the power devices usually suffer high voltage and current stress in traditional single-phase dc/dc topologies such as forward, half-bridge, and full-bridge converters, which limits the power level of converter to reach higher. As a superior alternative solution, a three-phase three-level (TPTL) dc/dc converter was investigated in this paper, which has the advantages of lower voltage and current stress on switches, as well as fewer power devices. Adopting a symmetrical control strategy, the input current and output current frequency can be increased by a factor of six compared to the switching frequency, resulting in a reduced filter requirement. However, all the switches are hard-switching, leading to a considerable switching loss. In this paper, an asymmetrical duty cycle control strategy was proposed to the TPTL dc/dc converter. The modified converter remains all the advantages of original control strategy; meanwhile, soft-switching can be achieved using the energy stored in output filter inductance and leakage inductances of transformers (or resonant inductances). The theoretical analysis was presented in details, along with the characteristics and soft-switching condition of the converter. Experimental results from 540 to 600 V input and 48 V/20 A output were presented to verify the theoretical analysis and the performance of the modified converter.