Flashover voltage and time prediction of polluted silicone rubber insulator based on artificial neural networks

•Clustering the leakage current (LC) with a SOM neural network.•Predicting the insulator flashover voltage (FOV).•Predicting the insulator flashover time (FOT). Insulator flashover prediction is an important task that should be done before any hazards. In this paper, leakage current (LC) analysis us...

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Bibliographic Details
Published inElectric power systems research Vol. 221; p. 109456
Main Authors Mohsenzadeh, Mohammad Mahdi, Hasanzadeh, Saeed, Sezavar, Hamid Reza, Samimi, Mohammad Hamed
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.08.2023
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Summary:•Clustering the leakage current (LC) with a SOM neural network.•Predicting the insulator flashover voltage (FOV).•Predicting the insulator flashover time (FOT). Insulator flashover prediction is an important task that should be done before any hazards. In this paper, leakage current (LC) analysis using neural networks is utilized to predict the flashover voltage (FOV) and flashover time (FOT). Experiments are performed on silicone rubber (SiR) insulators in the salt fog test chamber under different conditions and levels of contamination for LC sampling. To predict flashover, sampled LC at different contamination levels are first clustered by the self-organizing map (SOM) artificial neural network (ANN). Clustering results and other factors are employed to level the situation of LC periods. Afterward, these levels are fed sequentially to another ANN to predict the FOV and FOT. Various sample data are tested and compared with Back Propagation (BP) and Multilayer Perceptron (MLP) neural networks to evaluate the proposed neural network and algorithm. The results confirm the acceptable performance of the proposed neural networks and their ability as an online monitoring system to raise alarms before potential flashover hazards.
ISSN:0378-7796
1873-2046
DOI:10.1016/j.epsr.2023.109456