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Fault Location in Electrical Distribution Networks: a Traveling Wave and Artificial Neural Networks-Based Approach

EasyChair Preprint 15255

6 pagesDate: October 18, 2024

Abstract

Power distribution systems have undergone several transformations in recent years, including the integration of new load profiles, distributed generation, and the grid expansion.
This article presents an approach based on traveling wave theory and artificial neural networks for fault classification and location, which assists the utility by reducing response time and directly impacting system quality and reliability indicators. The proposed method utilizes three-phase voltage and current signals acquired by smart meters installed at the system endpoints. Voltage signals were used to determine the distance from fault using traveling wave theory. In addition, features were extracted from voltage and current signals, which were used as inputs to artificial neural networks, resposible for classifying the fault. The faulty scenarios were simulated using the PSCAD/EMTP software, considering the CIGRE medium voltage test system. The results were very promising. They presented: (i) detection accuracy rate of 100%; (ii) classification accuracy of nearly 100%; and (iii) average errors of less than 1% in fault distance estimation with a mean deviation of 0.4 and mitigation multiple estimation problem of more than 90%.

Keyphrases: Localização de Faltas, Múltipla Estimação, Ondas Viajantes, Perceptron Multicamadas, Redes Neurais Artificiais, Sistemas de Distribuição

BibTeX entry
BibTeX does not have the right entry for preprints. This is a hack for producing the correct reference:
@booklet{EasyChair:15255,
  author    = {Caio Vinicius Colozzo Grilo and Leonardo da Silva Lessa and Denis Vinicius Coury and Ricardo Augusto Souza Fernandes},
  title     = {Fault Location in Electrical Distribution Networks: a Traveling Wave and Artificial Neural Networks-Based Approach},
  howpublished = {EasyChair Preprint 15255},
  year      = {EasyChair, 2024}}
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