Distribution Systems High-Impedance Fault Location: A Parameter Estimation Approach

High-impedance fault location has always been a challenge for protection engineering. On the other hand, if this task is successfully realized, maintenance action could be performed in order to avoid potential injuries. For an effective protection scheme, high-impedance fault location should be perf...

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Bibliographic Details
Published in:IEEE transactions on power delivery 2016-08, Vol.31 (4), p.1806-1814
Main Authors: Iurinic, Leonardo Ulises, Herrera-Orozco, A. Ricardo, Goncalves Ferraz, Renato, Suman Bretas, Arturo
Format: Article
Language:English
Subjects:
Capacitance
Current measurement
Electric power lines
Fault location
high-impedance fault
Impedance
Mathematical model
parameter estimation
Radio frequency
Repair & maintenance
Voltage measurement
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Summary:High-impedance fault location has always been a challenge for protection engineering. On the other hand, if this task is successfully realized, maintenance action could be performed in order to avoid potential injuries. For an effective protection scheme, high-impedance fault location should be performed, but a lack of research on this area is noted. This paper proposes a new analytical formulation for high-impedance fault location in power systems. The approach is developed in the time domain, considering a high-impedance fault model consisting of two antiparallel diodes. Using this model, the fault distance and parameters are estimated as a minimization problem. First, a linear least square-based estimator is applied without consideration of line capacitance. Second, a steepest descent-based estimator is proposed in order to consider the line capacitance. Studies were carried out with the IEEE 13 bus modeled in the Alternate Transients Program. Encouraging test results are found indicating the method's potential for real-life applications.
ISSN:0885-8977
1937-4208
DOI:10.1109/TPWRD.2015.2507541