TY - GEN

T1 - Aerodynamic coupling of rotor and tower in HAWTs

AU - Gomez, Alejandro

AU - Seume, Joerg R.

PY - 2009

Y1 - 2009

N2 - This article presents results obtained computationally for the influence of the tower on the aerodynamics of the rotor. Tower models implemented in aeroelastic codes fail to account for aerodynamic: coupling of the rotor and the tower. Computational studies of this coupling have shown that induced unsteady circulations both on the blades and on the tower appear during the blade passage which cannot be? accounted for using a traditional BEM analysis integrated with a Beddoes-Leishman dynamic: stall model. On the blades, the effect can be represented by means of an induced aerodynamic force which is a function of the circumferential position and geometrical parameters. The flow around the tower is affected in such a way that the upwind stagnation point and the vortex separation points of its wake are displaced 3 times per revolution, for a three bladed rotor. This induces unsteady lateral loads on the tower and also a meandering of the wake. An interaction of the profile aerodynamic characteristics with the unsteady vortex shedding of the tower is observed. The methodology used is based on 2D CFD simulations whose results are generalized for an efficient implementation on aeroelastic codes based on BEM formulations. The1 results are summarized in a correction function for the lift coefficient of the airfoil to account for the aerodynamic: coupling with the tower. The work presented in this paper represents an important step towards the understanding of the effects of the 3p loads on the support structure of a HAWT due? to rotor-structure aerodynamic and aeroelastic interaction.

AB - This article presents results obtained computationally for the influence of the tower on the aerodynamics of the rotor. Tower models implemented in aeroelastic codes fail to account for aerodynamic: coupling of the rotor and the tower. Computational studies of this coupling have shown that induced unsteady circulations both on the blades and on the tower appear during the blade passage which cannot be? accounted for using a traditional BEM analysis integrated with a Beddoes-Leishman dynamic: stall model. On the blades, the effect can be represented by means of an induced aerodynamic force which is a function of the circumferential position and geometrical parameters. The flow around the tower is affected in such a way that the upwind stagnation point and the vortex separation points of its wake are displaced 3 times per revolution, for a three bladed rotor. This induces unsteady lateral loads on the tower and also a meandering of the wake. An interaction of the profile aerodynamic characteristics with the unsteady vortex shedding of the tower is observed. The methodology used is based on 2D CFD simulations whose results are generalized for an efficient implementation on aeroelastic codes based on BEM formulations. The1 results are summarized in a correction function for the lift coefficient of the airfoil to account for the aerodynamic: coupling with the tower. The work presented in this paper represents an important step towards the understanding of the effects of the 3p loads on the support structure of a HAWT due? to rotor-structure aerodynamic and aeroelastic interaction.

UR - http://www.scopus.com/inward/record.url?scp=84869992897&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:84869992897

SN - 9781615677467

T3 - European Wind Energy Conference and Exhibition 2009, EWEC 2009

SP - 4304

EP - 4314

BT - European Wind Energy Conference and Exhibition 2009, EWEC 2009

T2 - European Wind Energy Conference and Exhibition 2009, EWEC 2009

Y2 - 16 March 2009 through 19 March 2009

ER -