Abstract
As the critical parts of wind turbines, rolling bearings are prone to faults due to the extreme operating conditions. To avoid the influence of the faults on wind turbine performance and asset damages, many methods have been developed to monitor the health of bearings by accurately analyzing their vibration signals. Stochastic resonance (SR)-based signal enhancement is one of effective methods to extract the characteristic frequencies of weak fault signals. This paper constructs a new SR model, which is established based on the joint properties of both Power Function Type Single-Well and Woods-Saxon (PWS), and used to make fault frequency easy to detect. However, the collected vibration signals usually contain strong noise interference, which leads to poor effect when using the SR analysis method alone. Therefore, this paper combines the Fourier Decomposition Method (FDM) and SR to improve the detection accuracy of bearing fault signals feature. Here, the FDM is an alternative method of empirical mode decomposition (EMD), which is widely used in nonlinear signal analysis to eliminate the interference of low-frequency coupled signals. In this paper, a new stochastic resonance model (PWS) is constructed and combined with FDM to enhance the vibration signals of the input and output shaft of the wind turbine gearbox bearing, make the bearing fault signals can be easily detected. The results show that the combination of the two methods can detect the frequency of a bearing failure, thereby reminding maintenance personnel to urgently develop a maintenance plan.
Highlights
The bearings of wind turbines work in environments full of noises and coupled signals, making it difficult to identify the weak vibration signals of the wind turbine bearings and to evaluate the bearings’health status
The stochastic resonance (SR) [15,16] transforms redundant noise energy into useful signals, which reduces the noise interference and enlarges the energy of useful signals and improves signal-to-noise ratio (SNR), so the SR method is more suitable for detecting weak signals in noisy environments
A new potential function Power Function Type Single-Well and Woods-Saxon (PWS) is proposed for strengthening the energy of weak signals, which has an extremely rich potential function shapes to match different signal requirements
Summary
The bearings of wind turbines work in environments full of noises and coupled signals, making it difficult to identify the weak vibration signals of the wind turbine bearings and to evaluate the bearings’. Compared with classical SR, the proposed power function potential and Woods-Saxon potential (PWS) can obtain higher output signal-to-noise ratio (SNR) and characteristic frequency amplitude. FDM is a kind of time-domain analysis method based on the Fourier transform, which has been proved to have complete adaptability and a sufficient theoretical foundation It overcomes the problems of traditional time-domain analysis methods such as modal aliasing in EMD and is suitable for analyzing bearing faults.
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