Author:
Pei Xiping,Han Songtao,Bao Yanyan,Chen Wei,Li Hengjie
Abstract
When the winding of the power transformer is short-circuited, the winding will experience constant vibration, which will cause axial instability of the winding, and then lead to winding looseness, deformation, bulge, etc., therefore, a diagnosis method based on the Improved Pelican Optimization Algorithm and Convolutional Neural Network (IPOA-CNN) for short-circuit voiceprint signal of transformer windings is proposed. At the same time, considering the input parameter dimension of deep learning cannot be too high, a new feature parameter selection method is constructed for this model. Firstly, the frequency characteristics of winding acoustic vibration signals are analyzed, and then the characteristic parameters of transformer acoustic signals are extracted by Wavelet Packet Energy Spectrum (WPES) and Mel Frequency Cepstrum Coefficient (MFCC), respectively. Then, the two methods are combined to construct the WM feature extraction algorithm, and the Weighted Kernel Principal Component Analysis (WKPCA) is used to reduce the dimension of the feature to obtain the feature parameters with accurate feature information and low redundancy; Finally, combined with Sobol sequence to optimize the initial population of Pelican Optimization Algorithm (POA), the convolution kernel of Convolutional neural network (CNN) was optimized by IPOA, and the optimal convolution kernel was obtained. The transformer winding short-circuits voiceprint diagnosis models of WKPCA-WM and IPOA-CNN were constructed, which realized the accurate diagnosis of winding short-circuit voiceprint. The validity and feasibility of the method are verified by the acoustic signal data collected in the laboratory.
Subject
Economics and Econometrics,Energy Engineering and Power Technology,Fuel Technology,Renewable Energy, Sustainability and the Environment
Reference22 articles.
1. A novel hyperbolic fuzzy entropy measure for discrimination and taxonomy of transformer winding faults;Abbasi;Ieee Trans. Instrum. Meas.,2022
2. Experimental verification and finite element analysis of short-circuit electromagnetic force for dry-type transformer[J];Ahn;Ieee Trans. Magnetics,2012
3. Spectra and carbonyl index changes on processed beef fats using Fourier transform infrared spectrometer and principal component analysis;Aminullah;Spectrosc. Lett.,2020
4. Improved detection sensitivity with combined WPT and HHT for power transformer winding deformation analysis[C];Arivamudhan,2014
5. Application of artificial neural network on diagnosing location and extent of disk space variations in transformer windings using frequency response analysis[C];Beckham,2022