DC fault parameter sensitivity analysis

Author

Page, Frederick ; Adam, Grain ; Finney, Stephen ; Holliday, Derrick ; Lie Xu

fYear

2014

fDate

March 31 2014-April 3 2014

Firstpage

1

Lastpage

6

Abstract

At present High Voltage Direct Current (HVDC) Voltage Source Converters (VSC) are susceptible dc faults leading to extreme currents. The fault current cannot be controlled by the converter switching flows in the anti-parallel diodes. Protection devices are, therefore, required to operate with sufficient speed to avoid device failure. A method is introduced to calculate the critical time for protection to operate. Using this method it is then shown how the critical time may be extended by way of optimization of passive system components. In order to perform this optimization a new post-fault (when the converter gating signals are inhibited) model of the Modular Multi-Level (MMC) converter is introduced which drastically reduces simulation time, allowing high resolution parameter sweeps to be performed. The model is validated and is shown to produce fault characteristics similar to that of a conventional switched model.

Keywords

DC power transmission; HVDC power convertors; diodes; fault currents; optimisation; sensitivity analysis; DC fault parameter sensitivity analysis; HVDC voltage source converters; MMC converter; VSC; antiparallel diodes; converter switching flows; device failure; fault current; high voltage direct current; modular multilevel converter; optimization; passive system components; protection devices; DC faults; High Voltage Direct Current transmission; Modular Multi-Level modeling; voltage source converters;

fLanguage

English

Publisher

iet

Conference_Titel

Developments in Power System Protection (DPSP 2014), 12th IET International Conference on

Conference_Location

Copenhagen

Print_ISBN

978-1-84919-834-9

Type

conf

DOI

10.1049/cp.2014.0014

Filename

6822822