Your search keyword '"instantaneous trigger solid-state switch"' showing total 3 results

1. Research and experiment of a current-limiting HVDC circuit breaker

Author

Yi Du, Junpeng Deng, Hongyang Lin, Huan Zheng, Kangli Xiang, and Yu Shen

Subjects

circuit breakers, power grids, short-circuit currents, HVDC power transmission, HVDC power convertors, power transmission control, power transmission reliability, switching convertors, fault current limiters, short-circuit faults, hybrid HVDC CB, buffer circuit, stored energy circuit, mechanical HVDC circuit breakers, HVDC currents, reliable HVDC grid, operating speed, series connection, electronic switching devices, control strategy, equalising circuit, instantaneous trigger solid-state switch, fault pretreatment, parallel connection, breaking speed, current-limiting HVDC circuit breaker, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Existing mechanical HVDC circuit breakers (CB) are capable of interrupting HVDC currents within several tens of milliseconds, but this is too slow to satisfy the requirements of a reliable HVDC grid. HVDC CB based on semiconductors can easily overcome the limitations of operating speed, but need large number of the series (parallel) connection of electronic switching devices. To overcome these shortcomings, this paper introduces a topology of hybrid CB; this paper first describes the principle of hybrid CB; then a control strategy of fault pre-treatment is also proposed, that is, the ‘pre-action and action (or recovery)’ of the switches, in order to improve the breaking speed of the hybrid CB and the equalising circuit of its solid-state switch has been designed. The proposed topology and control strategy do not produce loss in the normal operation of CB, and instantaneous trigger solid-state switch with quickly cutting short-circuit current during short-circuit faults; at last the simulation and experiment of the hybrid HVDC CB have also been done. The results turn out when a short circuit occurs, the hybrid HVDC CB can quickly break the short-circuit current; the buffer circuit can be provided for the release of the stored energy circuit.

Published

2019

2. Research and experiment of a current-limiting HVDC circuit breaker.

Author

Du, Yi, Deng, Junpeng, Lin, Hongyang, Zheng, Huan, Xiang, Kangli, and Shen, Yu

Subjects

HIGH-voltage direct current transmission, ELECTRIC circuit breakers, ELECTRIC current converters, ELECTRIC power distribution grids, SHORT circuits

Abstract

Existing mechanical HVDC circuit breakers (CB) are capable of interrupting HVDC currents within several tens of milliseconds, but this is too slow to satisfy the requirements of a reliable HVDC grid. HVDC CB based on semiconductors can easily overcome the limitations of operating speed, but need large number of the series (parallel) connection of electronic switching devices. To overcome these shortcomings, this paper introduces a topology of hybrid CB; this paper first describes the principle of hybrid CB; then a control strategy of fault pre-treatment is also proposed, that is, the 'pre-action and action (or recovery)' of the switches, in order to improve the breaking speed of the hybrid CB and the equalising circuit of its solid-state switch has been designed. The proposed topology and control strategy do not produce loss in the normal operation of CB, and instantaneous trigger solid-state switch with quickly cutting short-circuit current during short-circuit faults; at last the simulation and experiment of the hybrid HVDC CB have also been done. The results turn out when a short circuit occurs, the hybrid HVDC CB can quickly break the short-circuit current; the buffer circuit can be provided for the release of the stored energy circuit. [ABSTRACT FROM AUTHOR]

Published

2019

3. Research and experiment of a current‐limiting HVDC circuit breaker

Author

Kangli Xiang, Yi Du, Hongyang Lin, Junpeng Deng, Huan Zheng, and Yu Shen

Subjects

Computer science, power transmission reliability, Energy Engineering and Power Technology, Series and parallel circuits, HVDC power convertors, operating speed, power transmission control, buffer circuit, parallel connection, short-circuit faults, Circuit breaker, stored energy circuit, current-limiting HVDC circuit breaker, switching convertors, business.industry, hybrid HVDC CB, instantaneous trigger solid-state switch, General Engineering, Buffer amplifier, Electrical engineering, breaking speed, HVDC power transmission, electronic switching devices, fault pretreatment, mechanical HVDC circuit breakers, power grids, short-circuit currents, series connection, reliable HVDC grid, Current limiting, fault current limiters, HVDC currents, control strategy, equalising circuit, lcsh:TA1-2040, circuit breakers, lcsh:Engineering (General). Civil engineering (General), Operating speed, business, Software

Abstract

Existing mechanical HVDC circuit breakers (CB) are capable of interrupting HVDC currents within several tens of milliseconds, but this is too slow to satisfy the requirements of a reliable HVDC grid. HVDC CB based on semiconductors can easily overcome the limitations of operating speed, but need large number of the series (parallel) connection of electronic switching devices. To overcome these shortcomings, this paper introduces a topology of hybrid CB; this paper first describes the principle of hybrid CB; then a control strategy of fault pre-treatment is also proposed, that is, the ‘pre-action and action (or recovery)’ of the switches, in order to improve the breaking speed of the hybrid CB and the equalising circuit of its solid-state switch has been designed. The proposed topology and control strategy do not produce loss in the normal operation of CB, and instantaneous trigger solid-state switch with quickly cutting short-circuit current during short-circuit faults; at last the simulation and experiment of the hybrid HVDC CB have also been done. The results turn out when a short circuit occurs, the hybrid HVDC CB can quickly break the short-circuit current; the buffer circuit can be provided for the release of the stored energy circuit.

Published

2018