A method for identifying surface contamination components of composite insulators based on hyperspectral imaging

A method for identifying surface contamination components of composite insulators based on hyperspectral imaging

The surface contamination components of composite insulators significantly influence the pollution flashover voltage. To develop a more efficient and practical method for identifying typical contamination components, this paper proposes a hyperspectral imaging-based identification method. Firstly, s...

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Bibliographic Details
Main Authors: MIAO Jin, QIN Jun, CHEN Junyu, WU Junfeng, REN Ming, LIU Runyu
Format: Article
Language:zho
Published: zhejiang electric power 2025-01-01
Series:Zhejiang dianli
Subjects:
insulating silicone rubber
insulation contamination
reflective spectral imaging
contamination degree
spectral feature extraction
Online Access:https://zjdl.cbpt.cnki.net/WKE3/WebPublication/paperDigest.aspx?paperID=7cbf33f1-28a0-46d6-8d5c-292ee94857fa
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Summary:The surface contamination components of composite insulators significantly influence the pollution flashover voltage. To develop a more efficient and practical method for identifying typical contamination components, this paper proposes a hyperspectral imaging-based identification method. Firstly, silicone rubber samples with single or mixed contamination of seven typical pollutants are prepared using standard artificial contamination methods, and hyperspectral 2D pixel data of these samples are acquired under simulated sunlight conditions. Next, kernelized principal component analysis (KPCA) is introduced at the 2D pixel level to effectively extract pixel data features of the typical contamination components. A 3D feature subspace is then established in the spectral dimension using envelope elimination and KPCA. Finally, the kernel support vector machine (KSVM) algorithm is employed to identify the pixel features of the seven contamination components. Results show that the proposed method achieve an identification accuracy of 93.75% for contamination components on the silicone rubber surface and over 80% for mixed contaminants. This study provides a novel approach for rapid on-site analysis of contamination components and flashover characteristics of composite insulators, as well as a reference for live-line inspections and pollution degree measurements in laboratories.
ISSN:1007-1881

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