A low-voltage ride-through(LVRT)control strategy for the multi-port power electronic transformer(PET)based on power co-regulation is proposed.During the sag and recovery of the grid-side voltage of the medium-voltage ...A low-voltage ride-through(LVRT)control strategy for the multi-port power electronic transformer(PET)based on power co-regulation is proposed.During the sag and recovery of the grid-side voltage of the medium-voltage ac(MVac)port,the grid-connected active power of the low-voltage ac(LVac)port,rather than the power from external renewable energy sources(e.g.,photovoltaic(PV)),is adjusted quickly to rebalance the power flowing across all ports,thereby preventing overcurrent and overvoltage.Moreover,a power-coordinate-frame-based LVRT mode classification is designed,and a total of six LVRT modes are classified to meet the LVRT requirements in all power configuration scenarios of the PET.In this way,the PET is endowed with the LVRT capability in both power-generation and power-consumption states,which is significantly different from traditional power generation systems such as PV or wind power.Furthermore,by optimizing the active power regulation path during LVRT transition,the overcurrent problem caused by the grid-voltage sag-depth detection delay is overcome.Finally,the effectiveness of the proposed control scheme is verified by experiments on a hardware-in-the-loop platform.展开更多
基金supported by the National Nature Science Foundation of China(Grant No.U2034201)the key project of Science and Technology Innovation Program of Army Engineering Uni-versity(Grant No.KYCQJQZL2119)。
文摘A low-voltage ride-through(LVRT)control strategy for the multi-port power electronic transformer(PET)based on power co-regulation is proposed.During the sag and recovery of the grid-side voltage of the medium-voltage ac(MVac)port,the grid-connected active power of the low-voltage ac(LVac)port,rather than the power from external renewable energy sources(e.g.,photovoltaic(PV)),is adjusted quickly to rebalance the power flowing across all ports,thereby preventing overcurrent and overvoltage.Moreover,a power-coordinate-frame-based LVRT mode classification is designed,and a total of six LVRT modes are classified to meet the LVRT requirements in all power configuration scenarios of the PET.In this way,the PET is endowed with the LVRT capability in both power-generation and power-consumption states,which is significantly different from traditional power generation systems such as PV or wind power.Furthermore,by optimizing the active power regulation path during LVRT transition,the overcurrent problem caused by the grid-voltage sag-depth detection delay is overcome.Finally,the effectiveness of the proposed control scheme is verified by experiments on a hardware-in-the-loop platform.
