This paper provides a discussion on future direct current (DC) network development in terms of system protection under DC-side fault scenarios. The argument between appropriate DC circuit breaker and new DC fault-tolerant converters is discussed after a review on DC technology development and bottleneck issues that require proper solutions. The overcurrent/cost curve of power-electronic DC circuit breakers (CB) superimposed to voltage-source converter (VSC) systems is derived and compared with other possible fault-tolerant power conversion options. This in-advance planning of protection capability is essential for the future development of DC networks
As a key element of the DC grid, the technology of DC circuit breakers (DCCBs) still have difficulty...
Development of multi-terminal HVDC has been held back by the lack of adequate dc breakers. This has ...
The utilization of converter interfaces has the potential to significantly alter the protection syst...
This paper provides a discussion on future direct current (DC) network development in terms of syste...
Multiterminal High Voltage Direct Current (HVDC) systems are anticipated to enable flexible transmis...
This paper compares the DC breaker requirements for different DC breaker protection schemes for high...
The integration of distributed generation such as renewable energy at the distribution is considered...
The use of DC for primary power distribution has the potential to bring significant design, cost and...
High Voltage Direct Current (HVDC) systems are now well-integrated into AC systems in many jurisdict...
This paper investigates DC network partition and alternative DC fault protection strategy for Multi-...
The development of power electronics is driving high voltage (HV) and medium voltage (MV) applicatio...
High voltage dc networks are a promising technology to flexibly transmit power over long distances. ...
This paper presents the fundamental system components of medium-voltage direct current (MVDC) grids,...
This study presents a comprehensive review of dc transmission technologies for future power grids, w...
© 2015 IEEE.Recently proposed meshed HVDC networks include both converters and DC circuit breakers, ...
As a key element of the DC grid, the technology of DC circuit breakers (DCCBs) still have difficulty...
Development of multi-terminal HVDC has been held back by the lack of adequate dc breakers. This has ...
The utilization of converter interfaces has the potential to significantly alter the protection syst...
This paper provides a discussion on future direct current (DC) network development in terms of syste...
Multiterminal High Voltage Direct Current (HVDC) systems are anticipated to enable flexible transmis...
This paper compares the DC breaker requirements for different DC breaker protection schemes for high...
The integration of distributed generation such as renewable energy at the distribution is considered...
The use of DC for primary power distribution has the potential to bring significant design, cost and...
High Voltage Direct Current (HVDC) systems are now well-integrated into AC systems in many jurisdict...
This paper investigates DC network partition and alternative DC fault protection strategy for Multi-...
The development of power electronics is driving high voltage (HV) and medium voltage (MV) applicatio...
High voltage dc networks are a promising technology to flexibly transmit power over long distances. ...
This paper presents the fundamental system components of medium-voltage direct current (MVDC) grids,...
This study presents a comprehensive review of dc transmission technologies for future power grids, w...
© 2015 IEEE.Recently proposed meshed HVDC networks include both converters and DC circuit breakers, ...
As a key element of the DC grid, the technology of DC circuit breakers (DCCBs) still have difficulty...
Development of multi-terminal HVDC has been held back by the lack of adequate dc breakers. This has ...
The utilization of converter interfaces has the potential to significantly alter the protection syst...