Avoiding under-reaching in twin circuit lines without residual current input from the parallel line

Mutual coupling presents difficult problems during single phase to earth fault, in transmission line protection. In lines, on multiple circuit towers or on the same right of way, the zero-sequence circuits of the lines get mutually coupled, causing an error in the apparent impedance seen by the rela...

Full description

Saved in:
Bibliographic Details
Main Authors: Mukerjee R.N., Bin Abdullah M.F., Tan K.K., Nallagownden P.
Other Authors: 7003827066
Format: Conference Paper
Published: 2023
Subjects:
Tags: Add Tag
No Tags, Be the first to tag this record!
id my.uniten.dspace-29728
record_format dspace
spelling my.uniten.dspace-297282024-04-18T09:27:10Z Avoiding under-reaching in twin circuit lines without residual current input from the parallel line Mukerjee R.N. Bin Abdullah M.F. Tan K.K. Nallagownden P. 7003827066 57188825497 24777357100 24448545300 Distance measurement Fault location Mutual coupling Power system faults Power system relaying Power transmission Protective relaying Boolean functions Computer networks Electric breakdown Electric current measurement Electric fault location Electric power system protection Iterative methods Parallel algorithms Relay protection Distance measurement Fault location Mutual coupling Power system faults Power system relaying Power transmission Protective relaying Coupled circuits Mutual coupling presents difficult problems during single phase to earth fault, in transmission line protection. In lines, on multiple circuit towers or on the same right of way, the zero-sequence circuits of the lines get mutually coupled, causing an error in the apparent impedance seen by the relay. This causes the distance protection relay at one end of the faulty line to overreach and the relay at the other end to under-reach. Also, incorrect sensing of the ground fault due to zero-sequence voltage inversion caused by mutual coupling in the zero-sequence network may lead to false trip of the neighbouring healthy line. The paper develops characteristic expressions for the effective sequence impedances experienced by a twin-circuit, both with and without mutual coupling and presents a non-iterative microprocessor based real time algorithm for computing fault distance and zero sequence compensation in basic distance relaying scheme, Residual current measurement from the parallel circuit is not required in the algorithm. � 2007 RPS. Final 2023-12-28T07:56:35Z 2023-12-28T07:56:35Z 2007 Conference Paper 2-s2.0-51349145178 https://www.scopus.com/inward/record.uri?eid=2-s2.0-51349145178&partnerID=40&md5=57d228a11547e05d153b3406b08010b7 https://irepository.uniten.edu.my/handle/123456789/29728 4510191 1115 1120 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Distance measurement
Fault location
Mutual coupling
Power system faults
Power system relaying
Power transmission
Protective relaying
Boolean functions
Computer networks
Electric breakdown
Electric current measurement
Electric fault location
Electric power system protection
Iterative methods
Parallel algorithms
Relay protection
Distance measurement
Fault location
Mutual coupling
Power system faults
Power system relaying
Power transmission
Protective relaying
Coupled circuits
spellingShingle Distance measurement
Fault location
Mutual coupling
Power system faults
Power system relaying
Power transmission
Protective relaying
Boolean functions
Computer networks
Electric breakdown
Electric current measurement
Electric fault location
Electric power system protection
Iterative methods
Parallel algorithms
Relay protection
Distance measurement
Fault location
Mutual coupling
Power system faults
Power system relaying
Power transmission
Protective relaying
Coupled circuits
Mukerjee R.N.
Bin Abdullah M.F.
Tan K.K.
Nallagownden P.
Avoiding under-reaching in twin circuit lines without residual current input from the parallel line
description Mutual coupling presents difficult problems during single phase to earth fault, in transmission line protection. In lines, on multiple circuit towers or on the same right of way, the zero-sequence circuits of the lines get mutually coupled, causing an error in the apparent impedance seen by the relay. This causes the distance protection relay at one end of the faulty line to overreach and the relay at the other end to under-reach. Also, incorrect sensing of the ground fault due to zero-sequence voltage inversion caused by mutual coupling in the zero-sequence network may lead to false trip of the neighbouring healthy line. The paper develops characteristic expressions for the effective sequence impedances experienced by a twin-circuit, both with and without mutual coupling and presents a non-iterative microprocessor based real time algorithm for computing fault distance and zero sequence compensation in basic distance relaying scheme, Residual current measurement from the parallel circuit is not required in the algorithm. � 2007 RPS.
author2 7003827066
author_facet 7003827066
Mukerjee R.N.
Bin Abdullah M.F.
Tan K.K.
Nallagownden P.
format Conference Paper
author Mukerjee R.N.
Bin Abdullah M.F.
Tan K.K.
Nallagownden P.
author_sort Mukerjee R.N.
title Avoiding under-reaching in twin circuit lines without residual current input from the parallel line
title_short Avoiding under-reaching in twin circuit lines without residual current input from the parallel line
title_full Avoiding under-reaching in twin circuit lines without residual current input from the parallel line
title_fullStr Avoiding under-reaching in twin circuit lines without residual current input from the parallel line
title_full_unstemmed Avoiding under-reaching in twin circuit lines without residual current input from the parallel line
title_sort avoiding under-reaching in twin circuit lines without residual current input from the parallel line
publishDate 2023
_version_ 1806426384117006336
score 13.222552