A New Fault Location Approach for Acoustic Emission Techniques in Wind Turbines

Muñoz, Carlos Quiterio Gómez; Márquez, Fausto Pedro García

doi:10.3390/en9010040

Cited by 80 publications

(28 citation statements)

References 27 publications

(25 reference statements)

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“…The main contributions of this paper lie in the following aspects: This paper presents a new approach to determine the possibility of an error in the analysis of the data from SCADA system. There are many studies where fault prediction and diagnosis of WTs regarding the SCADA data are discussed, eg, based on the frequency of occurrence of the failures, using data mining algorithm to built time series models, studying the standard turbine performance parameters and the physics of the different failures, using graphical methods, or employing sensitivity analysis . However, these methods are not based on the multiple correlations that each parameter can have with rest of the parameter measured by the SCADA systems. The proposed methodology considers all the correlations between all the variables of the SCADA systems.…”

Section: Introductionmentioning

confidence: 99%

Advanced analytics for detection and diagnosis of false alarms and faults: A real case study

Marugán

Márquez

2019

Wind Energy

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Onshore and offshore wind farms require a high level of advanced maintenance. Supervisory control and data acquisition (SCADA) and condition monitoring systems are now being employed, generating large amounts of data. They require robust and flexible approaches to convert dataset into useful information. This paper presents a novel approach based on the correlations of SCADA variables to detect and identify faults and false alarms in wind turbines. A correlation matrix between all the SCADA variables is used for pattern recognition. A new method based on curve fittings is employed for detecting false alarms and abnormal behaviours or faults in the components. The study is done in a real case study, validated with false alarms.

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Section: Introductionmentioning

confidence: 99%

Advanced analytics for detection and diagnosis of false alarms and faults: A real case study

Marugán

Márquez

2019

Wind Energy

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“…A proper CMS can be used to detect more faults. Early detection of incipient faults prevents major component failures and allows predictive strategies to be carried out [18][19][20]. The capability of a CMS depends on the number and type of sensors, and signal processing [21][22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Optimal Dynamic Analysis of Electrical/Electronic Components in Wind Turbines

et al. 2017

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Electrical and electronic components are very important subcomponents in modern industrial wind turbines. Complex multimegawatt wind turbines are continuously being installed both onshore and offshore, continuously increasing the demand for sophisticated electronic and electrical components. In this work, most critical electrical and electronic components in industrial wind turbines have been identified and the applicability of appropriate condition monitoring processes simulated. A fault tree dynamic analysis has been carried out by binary decision diagrams to obtain the system failure probability over time and using different time increments to evaluate the system. This analysis allows critical electrical and electronic components of the converters to be identified in different conditions. The results can be used to develop a scheduled maintenance that improves the decision making and reduces the maintenance costs.

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“…On the one hand, incipient faults would likely generate weak vibration energy, which could hardly cause any significant physical degradation within the solid structure, which makes it impossible for the vibration sensor to capture any useful pattern. On the other hand, acoustic sensor can cover a much more extensive range of frequencies which enables it to be embedded with much more extended types of fault signals [5,6]. However, the disadvantages accompanying the merits are the low signal to noise ratio (SNR) and low computational efficiency.…”

Section: Introductionmentioning

confidence: 99%

Correlated EEMD and Effective Feature Extraction for Both Periodic and Irregular Faults Diagnosis in Rotating Machinery

2017

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Intelligent fault diagnosis of complex machinery is crucial for industries to reduce the maintenance cost and to improve fault prediction performance. Acoustic signal is an ideal source for diagnosis because of its inherent characteristics in terms of being non-directional and insensitive to structural resonances. However, there are also two main drawbacks of acoustic signal, one of which is the low signal to noise ratio (SNR) caused by its high sensitivity and the other one is the low computational efficiency caused by the huge data size. These would decrease the performance of the fault diagnosis system. Therefore, it is significant to develop a proper feature extraction method to improve computational efficiency and performance in both periodic and irregular fault diagnosis. To enhance SNR of the acquired acoustic signal, the correlation coefficient (CC) method is employed to eliminate the redundant intrinsic mode functions (IMF), which comes from the decomposition procedure of pre-processing known as ensemble empirical mode decomposition (EEMD), because the higher the correlated coefficient of an IMF is, the more significant fault signatures it would contain, and the redundant IMF would compromise both the SNR and the computational cost performance. Singular value decomposition (SVD) and sample Entropy (SampEn) are subsequently used to extract the fault feature, by exploiting their sensitivities to irregular and periodic fault signals, respectively. In addition, the proposed feature extraction method using sparse Bayesian based pairwise coupled extreme learning machine (PC-SBELM) outperforms the existing pairwise-coupling probabilistic neural network (PC-PNN) and pairwise-coupling relevance vector machine (PC-RVM) by 1.8% and 2%, respectively, to achieve an accuracy of 93.9%. The experiments conducted on the periodic and irregular faults in the gears and bearings have demonstrated that the proposed hybrid fault diagnosis system is effective.

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A New Fault Location Approach for Acoustic Emission Techniques in Wind Turbines

Cited by 80 publications

References 27 publications

Advanced analytics for detection and diagnosis of false alarms and faults: A real case study

Advanced analytics for detection and diagnosis of false alarms and faults: A real case study

Optimal Dynamic Analysis of Electrical/Electronic Components in Wind Turbines

Correlated EEMD and Effective Feature Extraction for Both Periodic and Irregular Faults Diagnosis in Rotating Machinery

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