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Fault Diagnosis of Rotating Machinery Based on One-Dimensional Deep Residual Shrinkage Network with a Wide Convolution Layer

Jingli Yang, Tianyu Gao, Shouda Jiang, Shijie Li, Qing Tang

2020Shock and Vibration21 citationsDOIOpen Access PDF

Abstract

In actual engineering applications, inevitable noise seriously affects the accuracy of fault diagnosis for rotating machinery. To effectively identify the fault classes of rotating machinery under noise interference, an efficient fault diagnosis method without additional denoising procedures is proposed. First, a one-dimensional deep residual shrinkage network, which directly takes the raw vibration signals contaminated by noise as input, is developed to realize end-to-end fault diagnosis. Then, to further enhance the noise immunity of the diagnosis model, the first layer of the model is set to a wide convolution layer to extract short time features. Moreover, an adaptive batch normalization algorithm (AdaBN) is introduced into the diagnosis model to enhance the adaptability to noise. Experimental results illustrate that the fault diagnosis model for rotating machinery based on one-dimensional deep residual shrinkage network with a wide convolution layer (1D-WDRSN) can accurately identify the fault classes even under noise interference.

Topics & Concepts

ResidualNoise (video)Convolution (computer science)Noise reductionNormalization (sociology)Fault (geology)Interference (communication)VibrationEngineeringComputer scienceAlgorithmElectronic engineeringArtificial intelligenceArtificial neural networkAcousticsElectrical engineeringSociologyChannel (broadcasting)PhysicsImage (mathematics)AnthropologySeismologyGeologyMachine Fault Diagnosis TechniquesEngineering Diagnostics and ReliabilityStructural Integrity and Reliability Analysis
Fault Diagnosis of Rotating Machinery Based on One-Dimensional Deep Residual Shrinkage Network with a Wide Convolution Layer | Litcius