Phasor-Based Double-Ended Method for Fault Location on N-Circuit Transmission Lines
Subject Areas :
Research Article
Moossa Khodadadi Arpanahi
1
,
Majid Khoshnama
2
1 - Pardisan Engineering Company, Isfahan, Iran
2 - Pardisan Engineering Company, Isfahan, Iran
Received: 2022-03-03
Accepted : 2022-06-12
Published : 2022-05-22
Keywords:
Fault Location,
N-circuit,
Double-ended,
phasor,
Transmission,
Abstract :
Existing double-ended fault location methods in transmission systems can be applied only to single or double-circuit transmission lines. They conventionally use different abc-domain or sequence network equivalent circuits for different fault types. Furthermore, some methods do not consider shunt capacitances of the line, inductive or capacitive coupling between different phases, and (or) the cases of untransposed lines, simultaneously. In this paper, a comprehensive and fast phasor-based double-ended fault location method is proposed which can be used for N-circuit transmission lines. For this purpose, first, a matrix-vector equivalent circuit (MVEC) is proposed that leads to a unique formulation for fault location problem regardless of fault type, number of line circuits, being transposed or untransposed while it considers inductive and capacitive coupling between the phases. Then, based on the MVEC formulation, a bi-level algorithm is suggested that quickly finds the fault location, despite its iterative nature. The proposed method does not need to know impedances of local and remote end sources. Furthermore, its accuracy is not sensitive to fault impedance. Various case studies in terms of fault types, fault impedances, and distances from the measurement side in the presence of noise reveal the accuracy and applicability of the proposed fault location method.
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