Wind Energy Science (Feb 2021)

Pressure-based lift estimation and its application to feedforward load control employing trailing-edge flaps

  • S. Bartholomay,
  • T. T. B. Wester,
  • S. Perez-Becker,
  • S. Konze,
  • C. Menzel,
  • M. Hölling,
  • A. Spickenheuer,
  • J. Peinke,
  • C. N. Nayeri,
  • O. P. Paschereit,
  • K. Oberleithner

DOI
https://doi.org/10.5194/wes-6-221-2021
Journal volume & issue
Vol. 6
pp. 221 – 245

Abstract

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This experimental load control study presents results of an active trailing-edge flap feedforward controller for wind turbine applications. The controller input is derived from pressure-based lift estimation methods that rely either on a quasi-steady method, based on a three-hole probe, or on an unsteady method that is based on three selected surface pressure ports. Furthermore, a standard feedback controller, based on force balance measurements, is compared to the feedforward control. A Clark-Y airfoil is employed for the wing that is equipped with a trailing-edge flap of x/c=30% chordwise extension. Inflow disturbances are created by a two-dimensional active grid. The Reynolds number is Re=290 000, and reduced frequencies of k=0.07 up to k=0.32 are analyzed. Within the first part of the paper, the lift estimation methods are compared. The surface-pressure-based method shows generally more accurate results, whereas the three-hole probe estimate overpredicts the lift amplitudes with increasing frequencies. Nonetheless, employing the latter as input to the feedforward controller is more promising as a beneficial phase lead is introduced by this method. A successful load alleviation was achieved up to reduced frequencies of k=0.192.