Suzhou Electric Appliance Research Institute
期刊號: CN32-1800/TM| ISSN1007-3175

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基于MFCC和CNN的變壓器聲學(xué)特征提取及故障識別

來源:電工電氣發(fā)布時間:2023-06-30 12:30 瀏覽次數(shù):310

基于MFCC和CNN的變壓器聲學(xué)特征提取及故障識別

宋誠1,夏翔1,王鑫一2,楊文星2,姚平2
(1 國網(wǎng)湖北省電力有限公司孝感供電公司,湖北 孝感 432000;
2 長江大學(xué) 物理與光電工程學(xué)院,湖北 荊州 434023)
 
    摘 要:在變壓器故障診斷中,為解決使用傳統(tǒng)分類器方法存在的泛化能力弱、識別率不高等問題,提出了一種基于梅爾頻率倒譜系數(shù) (MFCC) 和卷積神經(jīng)網(wǎng)絡(luò) (CNN) 的變壓器聲學(xué)特征提取及故障識別方法。利用數(shù)字麥克風(fēng)采集變壓器在不同工作狀態(tài)下的聲音信號,經(jīng)預(yù)處理后計算其 MFCC 特征作為靜態(tài)特征,并進(jìn)一步處理得到 ΔMFCC 特征以及 ΔΔMFCC 特征作為動態(tài)特征;引入卷積神經(jīng)網(wǎng)絡(luò)模型作為分類器,分別使用靜態(tài)特征與三者的融合特征作為數(shù)據(jù)集進(jìn)行了訓(xùn)練;對兩個模型的訓(xùn)練結(jié)果進(jìn)行了分析,并在其他配電室對系統(tǒng)進(jìn)行了驗證實驗。實驗結(jié)果表明,該方法能夠有效地根據(jù)變壓器工作聲音識別變壓器的正常工作狀態(tài)、過載狀態(tài)以及放電故障,且動態(tài)特征的引入能夠在一定程度上提高模型的識別效果。
    關(guān)鍵詞: 變壓器;聲音信號;故障診斷;梅爾頻率倒譜系數(shù);卷積神經(jīng)網(wǎng)絡(luò);動態(tài)特征
    中圖分類號:TM407     文獻(xiàn)標(biāo)識碼:A     文章編號:1007-3175(2023)06-0049-06
 
Transformer Acoustic Feature Extraction and Fault
Identification Based on MFCC and CNN
 
SONG Cheng1, XIA Xiang1, WANG Xin-yi2, YANG Wen-xing2, YAO Ping2
(1 State Grid Hubei Electric Power Co., Ltd. Xiaogan Power Supply Company, Xiaogan 432000, China;
2 School of Physics and Optoelectronic Engineering, Yangtze University, Jingzhou 434023, China)
 
    Abstract: The traditional classifier method has problems of weak generalization ability and low recognition rate when diagnosing transformer faults, so the paper proposes a transformer acoustic feature extraction and fault identification method based on Mel Frequency Cepstral Coefficient(MFCC)and Convolutional Neural Networks(CNN). First, acoustic signals of transformers in different operating states are collected by digital microphones, and after the preprocess their MFCC features are calculated as static features and then further processed to obtain ΔMFCC features as well as ΔΔMFCC features as dynamic features. Second, the convolutional neural network model is introduced as the classifier, and static features and the fused features of the three are used respectively as the data set for training. Third, training results of the two models are analyzed, and the system is validated with experiments in other distribution rooms. The experimental results show that this method can effectively identify the normal working state, the overload state and the discharge fault of transformers based on their working sound. Besides, the introduction of dynamic features can increase the identification of the model to a certain extent.
    Key words: transformer; acoustic signals; fault diagnosis; Mel frequency cepstral coefficient; convolutional neural network; dynamic feature
 
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