DC fault protection for modular multi‐level converter‐based HVDC multi‐terminal systems with solid state circuit breakers

“…The common domain between (15a) and (15b) determines the range of R VL . Three constraints, expressed by (6), (9), and (15), make a feasible final region for R VL during a DC-side fault in which it is assured safe operation of the MMC, voltage regulation for the RACN as well as frequency stability for the RACN. It should be noted that satisfying (6) would be adequate, during the fault, for the IACN because the VL of the IACN limits the current flown through the diodes; this provides enough time interval for the ACCB to disconnect the IACN from the DC-side.…”

“…Using DC circuit breakers (DCCB) instead of ACCB is another suggestion [1,[7][8][9][10]; several drawbacks could be named such as having a high cost, design and implementation complications, imposing high transient over-voltages on switching devices and requiring additional equipment such as reinforced surge arresters and insulations [11]. Moreover, the DCCB is unable to prevent a frequency instability too.…”

Design of DC‐side fault current limiter for MMC‐HVDC systems: Safety of the MMC along with frequency stability

“…The common domain between (15a) and (15b) determines the range of R VL . Three constraints, expressed by (6), (9), and (15), make a feasible final region for R VL during a DC-side fault in which it is assured safe operation of the MMC, voltage regulation for the RACN as well as frequency stability for the RACN. It should be noted that satisfying (6) would be adequate, during the fault, for the IACN because the VL of the IACN limits the current flown through the diodes; this provides enough time interval for the ACCB to disconnect the IACN from the DC-side.…”

“…Using DC circuit breakers (DCCB) instead of ACCB is another suggestion [1,[7][8][9][10]; several drawbacks could be named such as having a high cost, design and implementation complications, imposing high transient over-voltages on switching devices and requiring additional equipment such as reinforced surge arresters and insulations [11]. Moreover, the DCCB is unable to prevent a frequency instability too.…”

Design of DC‐side fault current limiter for MMC‐HVDC systems: Safety of the MMC along with frequency stability

“…Furthermore, the system is shut down and no real or reactive power is exchanged, which will take a considerable long time to recover for the system [22]. By disconnecting the MMC with ac grid, dc CB (DCCB) can also be used to protect the MMC [23][24][25][26][27][28][29][30][31][32]. Usually, the DCCB is categorised into mechanical, solid-state and hybrid DCCB.…”

Review on topology‐based dc short‐circuit fault ride‐through strategies for MMC‐based HVDC system

“…The DCCB successfully turned off 5.1 kA under 10 kV DC [24]. Stumpe et al [25] present a selective protection concept for unidirectional solid‐state DCCBs and modular multilevel converters (MMCs) to detect line faults in MTDC systems. Sano and Takasaki [26] propose a solid‐state DCCB for the VSC‐HVDC system which can realise DC fault clearing and rapid restoration of power transmission.…”

SF₆passive resonance DC circuit breaker combined with a superconducting fault current limiter