| Description |
1 online resource (27 pages) : color illustrations. |
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text txt rdacontent |
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computer c rdamedia |
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online resource cr rdacarrier |
| Series |
NREL/PR ; 5000-81428 |
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NREL/PR ; 5000-81428.
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| Note |
"Wind Power Data and Digital Innovation, October 29, 2021." |
| Bibliography |
Includes bibliographical references (pages 26-27). |
| Funding |
U.S. Department of Energy DE-AC36-08GO28308 |
| Note |
Description based on online resource, PDF version; title from cover (NREL, viewed July 7, 2022). |
| Summary |
Operations and maintenance (O&M) cost of wind plant accounts up to 30% of total energy cost, which can be reduced through continuous monitoring and successfully detecting incipient wind turbine failures. To accomplish this, condition monitoring and predictive maintenance systems are being implemented in wind industry to support O&M decision making. A wide range of approaches for condition monitoring and fault prediction have been developed. These approaches generally use historical data of wind turbines collected by Supervisory Control and Data Acquisition (SCADA) system to identify patterns that lead to failure. These SCADA data show the overall condition of a wind turbine and can be leveraged to detect when the turbine's performance is degrading and to identify if a fault is developing. However, it becomes challenging to predict the failure of a specific wind turbine gearbox bearing, because the SCADA data are often not directly linked to the component. To bridge the gap, we have investigated features calculated from SCADA data using physics-based models and the gearbox design over the years. The damaged metric we used in the physics domain is frictional energy. Combining these physics domain variables with SCADA data as inputs to various machine learning models for gearbox bearing fault prediction, we have demonstrated the benefits of leveraging both physics and data domain models. It was an attempt to improve frictional-energy-based damage metric by adding data domain inputs, as we had learned that the frictional-energy-based damage metric alone is not sufficient to single out failed bearings from healthy. As condition monitoring data (either vibration or oil debris data) has become available at more and more wind plants, we would like to evaluate whether by adding the condition monitoring data can help further improve the performance of frictional-energy-based damage metric for gearbox bearing fault prediction. Both cases by modeling through various machine learning algorithms are discussed in this study along with some observations. |
| Subject |
Wind turbines -- Design and construction -- Simulation methods.
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Structural analysis (Engineering)
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Théorie des constructions.
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structural analysis.
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Structural analysis (Engineering)
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| Indexed Term |
fault prediction |
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gearbox |
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machine learning |
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wind turbine |
| Added Author |
National Renewable Energy Laboratory (U.S.), issuing body.
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| Standard No. |
1845885 OSTI ID |
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0000-0001-7401-8017 |
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0000-0002-6413-947X |
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0000-0003-0134-0907 |
| Gpo Item No. |
0430-P-09 (online) |
| Sudoc No. |
E 9.22:NREL/PR-5000-81428 |
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