Deep learning-based mechanical fault detection and diagnosis of electric motors using directional characteristics of acoustic signals

IF 0.3 4区 工程技术 Q4 ACOUSTICS
Srinivasa Ippili, Matthew B. Russell, Peng Wang, David W. Herrin
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引用次数: 0

Abstract

Early identification of rotating machinery faults is crucial to avoid catastrophic fail- ures upon installation. Contact-based vibration acquisition approaches are traditionally used for the purpose of machine health monitoring and end-of-line quality control. In complex working conditions, it can be difficult to perform an accurate accelerometer based vibration test. Acoustic signals (sound pressure and particle velocity) also contain important information about the operating state of mechanical equipment and can be used to detect different faults. A deep learning approach, namely, one-dimensional convolutional neural networks (1D-CNNs) can directly process raw time signals, thereby eliminating the human dependence on fault feature extraction. An experimental research study is conducted to test the proposed 1D-CNN methodology on three different electric motor faults. The results from the study indicate that the fault detection performance from the acoustic-based measurement method is very effective and thus can be a good replacement to the conventional accelerometer-based methods for detection and diagnosis of mechanical faults in electric motors.
基于声信号方向特征的深度学习电机机械故障检测与诊断
旋转机械故障的早期识别是避免安装时发生灾难性故障的关键。基于接触的振动采集方法传统上用于机器健康监测和生产线末端质量控制。在复杂的工作条件下,很难进行精确的基于加速度计的振动测试。声信号(声压和粒子速度)还包含有关机械设备运行状态的重要信息,可用于检测不同的故障。一种深度学习方法,即一维卷积神经网络(1d - cnn)可以直接处理原始时间信号,从而消除了人类对故障特征提取的依赖。针对三种不同的电机故障,对提出的1D-CNN方法进行了实验研究。研究结果表明,基于声学测量方法的故障检测性能非常有效,可以很好地替代传统的基于加速度计的电机机械故障检测和诊断方法。
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来源期刊
Noise Control Engineering Journal
Noise Control Engineering Journal 工程技术-工程:综合
CiteScore
0.90
自引率
25.00%
发文量
37
审稿时长
3 months
期刊介绍: NCEJ is the pre-eminent academic journal of noise control. It is the International Journal of the Institute of Noise Control Engineering of the USA. It is also produced with the participation and assistance of the Korean Society of Noise and Vibration Engineering (KSNVE). NCEJ reaches noise control professionals around the world, covering over 50 national noise control societies and institutes. INCE encourages you to submit your next paper to NCEJ. Choosing NCEJ: Provides the opportunity to reach a global audience of NCE professionals, academics, and students; Enhances the prestige of your work; Validates your work by formal peer review.
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