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An algorithm for the detection of DC series-arc faults using a Convolution Neural Network

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Abstract:

Due to the highly dangerous nature of electrical failures, and more specifically electric arc faults, the detection of such problems has become absolutely necessary. In c...Show More

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Abstract:

Due to the highly dangerous nature of electrical failures, and more specifically electric arc faults, the detection of such problems has become absolutely necessary. In contrast to the majority of methods proposed in scientific literature that are based on frequency analysis, we propose a method of detection based on CNN models (LeNet5 -

$28^{\ast}28$ and

$64^{\ast}64$ images). For this method, the line current must first be recorded (the dataset is composed of about 11000 signatures with and without arc faults). Series-arc faults are produced in circuits that comprise a 270-Volt DC supply voltage and loads that are mainly resistive. The selected sections of the current signals are then transformed into a 2D matrix (images). Then, the network must then be trained, tested and validated using the dataset. The performance of this method must also be also studied and discussed. In fact, the results of the detection process must then be presented using a confusion matrix in order to provide more precise information. Experimental results show that the method that we are proposing can effectively detect arcing faults.

Published in: 2022 IEEE 67th Holm Conference on Electrical Contacts (HLM)

Date of Conference: 23-26 October 2022

Date Added to IEEE Xplore: 08 December 2022

ISBN Information:

ISSN Information:

DOI: 10.1109/HLM54538.2022.9969784

Conference Location: Tampa, FL, USA

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Contents

I. Introduction

The process of continuous-voltage topology is now commonly used in many different systems, such as the electrical avionic system. The detection of electrical-arcing faults (particularly serial-arc faults) has therefore become critically important because of the high level of danger that they present. Many of the detection methods are described in scientific literature and the majority of them concern the detection of arc faults in solar photovoltaic panels (see Section [1]). It is possible to perform a temporal analysis of the electrical characteristics of the current, and in some cases the voltage, of the power supply (e.g. an analysis of the variance, etc.). That said, most of the proposed methods are based on a frequency analysis of the line current. In Section [2], the authors have proposed a detection method for DC SSPC (28V-supply voltage) and have retained the bandwidth frequency [10Hz, 10kHz] in the case of inductive loads.

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An algorithm for the detection of DC series-arc faults using a Convolution Neural Network

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An algorithm for the detection of DC series-arc faults using a Convolution Neural Network

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I. Introduction

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