This paper presents an investigation of the potential for reduction of fluctuating loads on wind turbine blades with the use of flaplike deflectable trailing edges. More specifically, the aeroelastic response of an elastically mounted airfoil section with a deflectable trailing edge is investigated. This is done by coupling a model for the aerodynamic forces on a deforming airfoil with a linear spring/damper model for the elastic deformation of a rigid airfoil to which the forces associated with the deflection of the trailing edge are added. The analysis showed that when the airfoil experienced a wind step from 10to12ms the standard deviation of the normal force could be reduced by up to 85% when the flap was controlled by the reading of the airfoil flapwise position and velocity, while reductions of up to 95% could be obtained when the flap was controlled by the reading of the angle of attack. When the airfoil experienced a turbulent wind field, the standard deviation of the normal force could be reduced by 81% for control based on measured angle of attack. The maximum reduction using a combination of flapwise position and velocity was 75%. The maximum deflection of the trailing edge geometry was, in all the considered cases, small enough to justify the use of a potential flow code for calculation of the aerodynamic forces. Calculations showed that the effect of a time lag in the actuators and sensors may drastically reduce the efficiency of the control algorithm. Likewise, the effect of a low maximum actuation velocity reduces the efficiency of the control algorithm. The analysis of the two-dimensional (2D) aeroservoelastic system shown in this paper indicates that the potential of using trailing edge flaps for reduction of fluctuating loads is significant.

1.
Larsen
,
T.
,
Madsen
,
H.
, and
Thomsen
,
K.
, April 2004, “
Active Load Reduction Using Individual Pitch, Based on Local Blade Flow Measurements
,”
Proc. EWEA The Science of Making Torque From Wind, Delft, Netherlands
.
2.
Bossanyi
,
E.
, April 2004, “
Developments in Individual Blade Pitch Control
,”
Proc. EWEA The Science of Making Torque From Wind, Delft, Netherlands
.
3.
Yen Nakafuji
,
D.
,
van Dam
,
C.
,
Smith
,
R.
, and
Collins
,
S.
, 2001, “
Active Load Control for Airfoils using Microtabs
,”
J. Sol. Energy Eng.
0199-6231,
123
, pp.
282
289
.
4.
Basualdo
,
S.
, feb 2004, “
Load Alleviation on Wind Turbines using Variable Airfoil Geometry (A Two-Dimensional Analysis)
,” Masters thesis, Department of Mechanical Engineering, Technical University of Denmark.
5.
Theodorsen
,
T.
, 1935, “
General Theory of Aerodynamical Instability and the Mechanism of Flutter
,” NACA Report 496, Vol.
496
.
6.
Leishman
,
J.
, March/April 1994, “
Unsteady Lift of a Flapped Airfoil by Indicial Concepts
,”
J. Aircr.
0021-8669,
31
, pp.
288
297
.
7.
Hariharan
,
N.
, and
Leishman
,
J.
, Sept/Oct 1996, “
Unsteady Aerodynamics of a Flapped Airfoil in Subsonic Flow by Indicial Concepts
,”
J. Aircr.
0021-8669,
33
, pp.
855
868
.
8.
Katz
,
J.
, and
Weihs
,
D
, 1978, “
Hydrodynamic Propulsion by Large Amplitude Oscillation of an Airfoil with Chordwise Flexibility
,”
J. Fluid Mech.
0022-1120,
88
, pp.
485
497
.
9.
Katz
,
J.
, and
Weihs
,
D.
, 1979, “
The Effect of Chordwise Flexibility on the Lift of a Rapidly Accelerated Airfoil
,”
Aeronaut. Q.
0001-9259,
30
, pp.
360
370
.
10.
van der Wall
,
B.
, and
Geissler
,
W.
, May 1999, “
Expreimental and Numerical Investigations on Steady and Unsteady Behavior of a Rotor Airfoil with a Piezoelectric Trailing Edge Flap
,”
55th American Helicopter Society Forum, Montreal, Canada
.
11.
Gaunaa
,
M.
, 2005, “
Unsteady 2D Potential-flow Forces on a Variable Geometry Airfoil Undergoing Arbitrary Motion
,” Technical report—Risø-R-1478(EN), To appear.
12.
Fuglsang
,
P.
,
Bak
,
C.
,
Gaunaa
,
M.
, and
Antoniou
,
I.
, 2004, “
Design and Verification of the Risø-B1 Airfoil Family for Wind Turbines
,”
J. Sol. Energy Eng.
0199-6231,
126
, pp.
1002
1010
.
13.
Garrick
,
I.
, May 1936, “
Propulsion of a Flapping and Oscillating Airfoil
,” NACA Report—NO. 567, pp.
419
427
.
14.
von Karman
,
T.
, and
Sears
,
W.
, 1938, “
Airfoil Theory for Non-Uniform Motion
,”
J. Aeronaut. Sci.
0095-9812,
5
, pp.
379
390
.
15.
Gaunaa
,
M.
, April 2002, “
Unsteady Aerodynamic Forces on NACA 0015 Airfoil in Harmonic Translatory Motion
,” Ph.D. Thesis, Dept. of Mech. Eng, Danish Techn. Univ.—MEK-FM-2002-02.
16.
Hansen
,
M.
,
Gaunaa
,
M.
, and
Madsen
,
H.
, June 2004, “
A Beddoes-Leishman Type Dynamic Stall Model in State-Space and Indicial Formulations
,” Technical report—Risø-R-1354(EN), http://www.risoe.dk/rispubl/VEA/ris-r-1354.htmhttp://www.risoe.dk/rispubl/VEA/ris-r-1354.htm.
17.
Jones
,
R.
, April 1940, “
The Unsteady Lift of a Wing of Finite Aspect Ratio
,” NACA Report—Tech. Report 681.
18.
Troldborg
,
N.
, 2004, “
Computational Study of the Risø-B1-18 Airfoil Equipped with Actively Controlled Trailing Edge Flaps
,” Master Thesis, Technical University of Denmark, Department of Mechanical Engineering, Fluid Mechanics.
19.
Michelsen
,
J.
, 1992, “
Basis3D—a Platform for Development of Multiblock PDE Solvers
,” Technical Report AFM 92-05, Department of Fluid Mechanics,
Technical University of Denmark
.
20.
Michelsen
,
J.
, 1994, “
Block-Structured Multigrid Solution of 2D and 3D Elliptic PDE’s
,” Technical Report AFM 94-06, Department of Fluid Mechanics, Technical University of Denmark.
21.
Sørensen
,
N.
, 1995, “
General Purpose Flow Solver Applied to Flow over Hills
,” Technical Report Risø-R-827(EN).
Risø National Laboratory
.
22.
Veers
,
P.
, March 1998, “
Three-Dimensional Wind Simulation
,” Sandia Report, SAND88-0152-VC-261.
23.
DS472, 1986, “
Dansk Ingeniørforenings og IngeniørSammenslutnings Norm for Last og Sikkerhed for Vindmøllekonstruktioner
,” 1. udg. Danish Design Code for Wind Turbines (In danish).
24.
Sears
,
W.
, 1941, “
Some Aspects of Non-Stationary Airfoil Theory and Its Practical Application
,”
J. Aeronaut. Sci.
0095-9812,
8
, pp.
104
108
.
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