A modified wide-area backup protection scheme for shunt-compensated transmission lines

•Backup protection of shunt-compensated lines regardless of compensator type.•Using negative-sequence current angle instead of positive one in asymmetric faults.•Accurate identifying of the faulted line under different fault conditions.•Not influenced by measurement device errors.•The execution time...

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Bibliographic Details
Published in:Electric power systems research 2020-06, Vol.183, p.106274, Article 106274
Main Authors: Ahmadinia, Mohammadreza, Sadeh, Javad
Format: Article
Language:English
Subjects:
Electric power lines
Fault detection
Fault location
Fault tolerance
Measurement
Measuring instruments
Negative-sequence current angle
Phasor measurement unit (PMU)
Phasors
Shunt-compensated line
Studies
Transmission lines
Wide area backup protection (WABP)
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Summary:•Backup protection of shunt-compensated lines regardless of compensator type.•Using negative-sequence current angle instead of positive one in asymmetric faults.•Accurate identifying of the faulted line under different fault conditions.•Not influenced by measurement device errors.•The execution time lower than 3 ms. In this paper, a new modified methodology has been proposed to protect shunt-compensated transmission lines as properly as uncompensated lines. The proposed scheme initially selects the nearest buses to the fault location based on data provided by the phasor measurement units (PMUs). Three buses with the minimum magnitude of the positive-sequence voltages or maximum magnitude of negative (or zero)-sequence voltages are selected as the nearest buses to the fault location. All connected lines to these buses are designated as suspected. Afterward, the suspected line with the maximum absolute difference of positive (or negative)-sequence current angle is concluded as the faulted line. The effectiveness of the proposed technique has been evaluated under various fault scenarios in WSCC 9-bus and IEEE 39-bus test systems in MATLAB/SIMULINK platform. The outputs clearly reveal that the recommended scheme finds the faulted line precisely under different fault types, fault locations, fault resistances, and shunt-compensator types within 3 ms. The modified scheme can also detect high-resistance asymmetrical faults accurately exploiting negative-sequence current angles instead of the positive ones.
ISSN:0378-7796
1873-2046
DOI:10.1016/j.epsr.2020.106274