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access icon openaccess Prediction of wind turbine generator bearing failure through analysis of high-frequency vibration data and the application of support vector machine algorithms

This is an open access article published by the IET under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0/)
Received 26/10/2018, Accepted 09/01/2019, Published 15/03/2019

Innovations which help facilitate predictive maintenance strategies have the potential to greatly reduce costs associated with wind turbine O&M by driving efficiency and increasing wind turbine availability. This study uses multiple examples of the same generator bearing failure to provide insight into how condition monitoring systems can be used in to train machine learning algorithms with the ultimate goal of predicting failure and remaining useful life. Results show that by analysing high-frequency vibration data and extracting key features to train support vector machine algorithms, an accuracy of 67% can be achieved in successfully predicting failure 1–2 months before occurrence. This study reflects on the limitations surrounding a generalised training approach, taking advantage of all available data, showing that if too many different examples are considered of different wind turbines and operating conditions, the overall accuracy can be diminished.

Inspec keywords: vibrations; mechanical engineering computing; fault diagnosis; learning (artificial intelligence); support vector machines; remaining life assessment; machine bearings; power generation faults; turbogenerators; wind turbines; condition monitoring

Other keywords: multiple examples; asset management; wind turbine downtime; different wind turbines; onshore developments; high-frequency vibration data; wind turbine generator; time 1.0 month to 2.0 month; generalised training approach; offshore developments; remaining useful life; support vector machine algorithms; condition monitoring systems; generator bearing failure

Subjects: Civil and mechanical engineering computing; Wind power plants; Other topics in statistics; Reliability; Mechanical engineering applications of IT; Knowledge engineering techniques; Mechanical components; Maintenance and reliability

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http://iet.metastore.ingenta.com/content/journals/10.1049/joe.2018.9281
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