Articles | Volume 4, issue 4
Wind Energ. Sci., 4, 549–561, 2019
https://doi.org/10.5194/wes-4-549-2019
Wind Energ. Sci., 4, 549–561, 2019
https://doi.org/10.5194/wes-4-549-2019
Research article
11 Oct 2019
Research article | 11 Oct 2019

Validation of a lookup-table approach to modeling turbine fatigue loads in wind farms under active wake control

Hector Mendez Reyes et al.

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Cited articles

Annoni, J., Gebraad, P., Scholbrock, A., Fleming, P., and van Wingerden, J.-W.: Analysis of axial-induction-based wind plant control using an engineering and a high-order wind plant model, Wind Energy, 19, 1135–1150, 2016. a
Bak, C., Zahle, F., Bitsche, R., Kim, T., de, A., Henriksen, L. C., Natarajan, A., and Hansen, M.: Description of the DTU 10 MW Reference Wind Turbine, Tech. Rep. DTU Wind Energy Report-I-0092, DTU Wind Energy, 2013. a
Boorsma, K.: Power and loads for wind turbines in yawed conditions, Tech. Rep. ECN-E–12-047, Energy reserach Center of the Netherlands, 2012. a, b, c, d
Boorsma, K.: Active Wake Control by pitch adjustment. Analysis of field measurements, Tech. Rep. ECN-E–15-042, Energy research Centre of the Netherlands, 2015. a
Boorsma, K. and Schepers, J.: New MEXICO Experiment, Preliminary overview with initial validation, Tech. Rep. ECN-E–14-048, ECN, 2014. a, b
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Short summary
Within wind farms, the wind turbines interact with each other through their wakes. Turbines operating in these wakes have lower power production and increased wear and tear. Wake redirection is control strategy to steer the wakes aside from downstream turbines, increasing the power yield of the farm. Models for predicting the power gain and impacts on wear exist, but they are still immature and require validation. The validation of such a model is the purpose of this paper.