Application of Axis Orbit Image Optimization in Fault Diagnosis for Rotor System

The shape characteristic of the axis orbit plays an important role in the fault diagnosis of rotating machinery. However, the original signal is typically messy, and this affects the identification accuracy and identification speed. In order to improve the identification effect, an effective fault i...

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Bibliographic Details
Published inInternational journal of rotating machinery Vol. 2020; no. 2020; pp. 1 - 13
Main Authors Jiang, Wangwang, Xue, Xuanyi, Shao, Jie, Pang, Xinyu
Format Journal Article
LanguageEnglish
Published Cairo, Egypt Hindawi Publishing Corporation 2020
Hindawi
Hindawi Limited
Subjects
Accuracy
Correlation analysis
Decomposition
Efficiency
Fault detection
Fault diagnosis
Fourier transforms
Identification
Image processing
Invariants
Machinery
Mathematical analysis
Mathematical morphology
Methods
Morphology
Neural networks
Noise
Nuclear power plants
Optimization
Orbits
Rotating machinery
Signal processing
Support vector machines
Test rigs
Wavelet transforms
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Summary:The shape characteristic of the axis orbit plays an important role in the fault diagnosis of rotating machinery. However, the original signal is typically messy, and this affects the identification accuracy and identification speed. In order to improve the identification effect, an effective fault identification method for a rotor system based on the axis orbit is proposed. The method is a combination of ensemble empirical mode decomposition (EEMD), morphological image processing, Hu invariant moment feature vector, and back propagation (BP) neural network. Experiments of four fault forms are performed in single-span rotor and double-span rotor test rigs. Vibration displacement signals in the X and Y directions of the rotor are processed via EEMD filtering to eliminate the high-frequency noise. The mathematical morphology is used to optimize the axis orbit including the dilation and skeleton operation. After image processing, Hu invariant moments of the skeleton axis orbits are calculated as the feature vector. Finally, the BP neural network is trained to identify the faults of the rotor system. The experimental results indicate that the time of identification of the tested axis orbits via morphological processing corresponds to 13.05 s, and the identification accuracy rate ranges to 95%. Both exceed that without mathematical morphology. The proposed method is reliable and effective for the identification of the axis orbit and aids in online monitoring and automatic identification of rotor system faults.
ISSN:1023-621X
1542-3034
DOI:10.1155/2020/9540791