Early Warning and Inhibition of HVDC Subsequent Commutation Failure During Recovery Process Under Grid Fault

Initiation of ac fault may lead to the commutation failure, and the high-voltage direct current (HVDC) system is still confronted with the risk of subsequent commutation failure (SCF) during recovery process prior to the fault clearance. In this paper, the mechanism of subsequent commutation failure is investigated through the analysis of controller response and ac-dc interaction under the symmetrical and asymmetrical faults. According to the modulation theory, a switching function method based on the line-to-line voltages is introduced to depict the voltage transfer characteristics of converters under asymmetrical faults. The early warning criterion and its corresponding early warning system for the subsequent commutation failure (SCF-EWS) are developed by taking the risks of controller regulation and the variations of electrical quantities into account. For the purpose of suppression, an emergency advance control strategy against the subsequent commutation failure (SCF-EAC) is also presented. The analysis and the proposed schemes are verified by the CIGRE benchmark model that is shipped with the PSCAD/EMTDC software under different fault conditions, and the simulation results demonstrate the feasibility and superior performance.

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