Commutation failure(CF)is an inherent problem faced by line commutated converter high voltage direct current(LCC-HVDC)technology.To completely solve the problem of CF,we have proposed a novel hybrid commutated convert...Commutation failure(CF)is an inherent problem faced by line commutated converter high voltage direct current(LCC-HVDC)technology.To completely solve the problem of CF,we have proposed a novel hybrid commutated converter(HCC)technology based on reverse blocking integrated gate commutated thyristor,which can utilise two methods for commutation:enhanced grid voltage commutation and active turn-off forced com-mutation.In this paper,the topology and operating principle of HCC are proposed.Then,the control and protection strategy is designed based on the current variation trend under AC faults.To verify the effectiveness of HCC in mitigating CF,a 120-kV/360-MW HCC-HVDC model is built in PSCAD/EMTDC,adopting LCC at the rectifier side and HCC at the inverter side.Based on this model,HCC steady-state and fault transient stresses are analysed.Various AC faults are simulated and the performance of HCC-HVDC is compared with LCC-HVDC.Finally,the results show that the HCC topol-ogy and proposed control strategy can solve CF under all fault conditions with almost the same attributes as LCC,such as large capacity,low cost,low loss and high reliability,which is meaningful for the application of HCC to the HVDC transmission system.展开更多
The world’s first hybrid commutated converter(HCC)—a next-generation high-voltage direct current(HVDC)transmission valve based on integrated gate commutated thyristor(IGCT)technology—officially commenced commercial...The world’s first hybrid commutated converter(HCC)—a next-generation high-voltage direct current(HVDC)transmission valve based on integrated gate commutated thyristor(IGCT)technology—officially commenced commercial operation at the Lingbao Converter Station in Henan Province,China,on December 28,2025,as shown in Figure 1.This milestone signifies the resolution of the“commutation failure”challenge that has plagued global HVDC transmission systems for over half a century.展开更多
基金National Natural Science Foundation of China-State Grid Corporation Joint Fund for Smart Grid,Grant/Award Number:U2166602。
文摘Commutation failure(CF)is an inherent problem faced by line commutated converter high voltage direct current(LCC-HVDC)technology.To completely solve the problem of CF,we have proposed a novel hybrid commutated converter(HCC)technology based on reverse blocking integrated gate commutated thyristor,which can utilise two methods for commutation:enhanced grid voltage commutation and active turn-off forced com-mutation.In this paper,the topology and operating principle of HCC are proposed.Then,the control and protection strategy is designed based on the current variation trend under AC faults.To verify the effectiveness of HCC in mitigating CF,a 120-kV/360-MW HCC-HVDC model is built in PSCAD/EMTDC,adopting LCC at the rectifier side and HCC at the inverter side.Based on this model,HCC steady-state and fault transient stresses are analysed.Various AC faults are simulated and the performance of HCC-HVDC is compared with LCC-HVDC.Finally,the results show that the HCC topol-ogy and proposed control strategy can solve CF under all fault conditions with almost the same attributes as LCC,such as large capacity,low cost,low loss and high reliability,which is meaningful for the application of HCC to the HVDC transmission system.
文摘The world’s first hybrid commutated converter(HCC)—a next-generation high-voltage direct current(HVDC)transmission valve based on integrated gate commutated thyristor(IGCT)technology—officially commenced commercial operation at the Lingbao Converter Station in Henan Province,China,on December 28,2025,as shown in Figure 1.This milestone signifies the resolution of the“commutation failure”challenge that has plagued global HVDC transmission systems for over half a century.
