An aeroacoustics-based approach for wind turbine blade damage detection

Wind turbine blades (WTBs) are susceptible to faults in the harsh wind farm environments, making their safety a matter of paramount importance. Unfortunately, existing composite blade monitoring methods face various limitations in practical use. To address this issue, the study presents an intelligent fault detection method to assess the health of both the structural integrity and its skin. This has never been tried before by scholars. The study begins with the collection of acoustic signals from the blade chamber. Second, these signals are processed using wavelet packet decomposition (WPD) and Fast Fourier Transform to generate two-dimensional feature matrices. Third, apply the obtained matrices to train a one-dimensional convolutional neural network (CNN), enabling advanced feature extraction and classification, which forms the basis of the WPD-CNN model. Finally, the proposed method was experimentally verified. It has been found that the proposed WPD-CNN model achieves fault detection accuracies ranging from 87.14% to 98.57%, depending on the types of feature matrices used for training the model. These results highlight the model’s strong performance in diagnosing WTBs. Additionally, the study emphasizes the advantage of using frequency spectrum-derived features over traditional time-domain waveform features for effective WTB fault detection.

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Towards the Prediction of Airfoil Trailing Edge Crack Size Through Aerodynamic Noise Measurements for Both Clean and Turbulent Inflow Conditions

Zhang,

Watson,

Ragni

et al. 2023

Preprint

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An aeroacoustics-based approach for wind turbine blade damage detection

Cited by 4 publications

References 21 publications

Concise review: aerodynamic noise prediction methods and mechanisms for wind turbines

Concise review: aerodynamic noise prediction methods and mechanisms for wind turbines

Acoustic monitoring of wind turbine blades using wavelet packet analysis and 1D convolutional neural networks

Towards the Prediction of Airfoil Trailing Edge Crack Size Through Aerodynamic Noise Measurements for Both Clean and Turbulent Inflow Conditions

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