The rotor as a sensor – observing shear and veer from the operational data of a large wind turbine

This paper demonstrates the observation of wind shear and veer directly from the operational response of a wind turbine equipped with blade load sensors. Two independent neural-based observers, one for shear and one for veer, are first trained using a machine-learning approach and then used to produ...

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Veröffentlicht in:Wind Energy Science 2024-06, Vol.9 (6), p.1419-1429
Hauptverfasser: Bertelè, Marta, Meyer, Paul J., Sucameli, Carlo R., Fricke, Johannes, Wegner, Anna, Gottschall, Julia, Bottasso, Carlo L.
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Sprache:eng
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Zusammenfassung:This paper demonstrates the observation of wind shear and veer directly from the operational response of a wind turbine equipped with blade load sensors. Two independent neural-based observers, one for shear and one for veer, are first trained using a machine-learning approach and then used to produce estimates of these two wind characteristics from measured blade load harmonics. The study is based on a dataset collected at an experimental test site featuring a highly instrumented 8 MW wind turbine, an IEC-compliant (International Electrotechnical Commission) met mast, and a vertical profiling lidar reaching above the rotor top. The present study reports the first demonstration of the measurement of wind veer with this technology and the first validation of shear and veer with respect to lidar measurements spanning the whole rotor height. Results are presented in terms of correlations, exemplary time histories, and aggregated statistical metrics. Measurements of shear and veer produced by the observers are very similar to the ones obtained with the widely adopted profiling lidar while avoiding its complexity and associated costs.
ISSN:2366-7451
2366-7443
2366-7451
DOI:10.5194/wes-9-1419-2024