New dynamic-inflow engineering models based on linear and nonlinear actuator disc vortex models

New dynamic-inflow engineering models based on linear and nonlinear actuator disc vortex models

Yu, W.
Tavernier, D.
Ferreira, C.
van Kuik, G.A.M.
Schepers, G.

2019

Two new engineering models are presented for the aerodynamic induction of a wind turbine underdynamicthrust.ThemodelsaredevelopedusingthedifferentialformofDuhamelintegrals of indicial responses of actuator disc type vortex models. The time constants of the indicial functions are obtained by the indicial responses of a linearand a nonlinearactuatordisc model. The new dynamic-inflow engineering models are verified against the results of a Computational Fluid Dynamics (CFD) model and compared against the dynamic-inflow engineering models of Pitt-Peters, Øye, and Energy Research Center of the Netherlands (ECN), for several load cases. Comparisons of all models show that two time constants are necessary to predict the dynamic induction. The amplitude and phase delay of the velocity distribution shows a strong radial dependency. Verifying the models against results from the CFD model shows that the model based on the linearactuatordisc vortex modelpredicts a similarperformance as the Øye model. The model based on the nonlinear actuator disc vortex model predicts the dynamic induction betterthantheothermodelsconcerningbothphasedelayandamplitude,especiallyathighload

Actuator disc
CFD
Dynamic inflow
Engineering model
Vortex model
Energy Efficiency
Energy / Geological Survey Netherlands

http://resolver.tudelft.nl/uuid:e4f8fed9-3516-49ab-8fae-5fba3f50bd5f

https://doi.org/10.1002/we.2380

868626

John Wiley and Sons Ltd

1095-4244

Wind Energy, 1-18

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