Abstract
Various research projects have focused on active aerodynamic load control of wind turbines using control devices on the blades, for example flaps. The aerodynamic load predictions of utilized aeroelastic codes have not yet been fully validated with full rotor CFD or experimental results. In this study, a comparison
between aerodynamic predictions of the aeroelastic code HAWC2 and the Navier-Stokes code EllipSys3D for the NREL 5MW reference wind turbine rotor in a stiff configuration equipped with a deformable trailing edge flap is performed. A case where the half rotor plane experiences an inflow resembling the wake from an upstream wind turbine is investigated, which is appropriate for comparing
the predictions of the two codes related to the abrupt aerodynamic response and the influence of the controllable flap. The trailing edge flap is actuated to alleviate the added loads from a non-uniform inflow mimicking a half-wake situation, using different control methods and maximum flap angles. Three
different control inputs are simulated: a prescribed flap angle based on the a priori knowledge of the inflow velocity, a controller based on the blade root flap-wise moment feedback, and finally a controller based on a Pitot tube velocity feedback measured at flap mid-span. Good agreement is found between
EllipSys3D and HAWC2 in the prediction of the dynamic blade loads, considering the high complexity of the flow case.
between aerodynamic predictions of the aeroelastic code HAWC2 and the Navier-Stokes code EllipSys3D for the NREL 5MW reference wind turbine rotor in a stiff configuration equipped with a deformable trailing edge flap is performed. A case where the half rotor plane experiences an inflow resembling the wake from an upstream wind turbine is investigated, which is appropriate for comparing
the predictions of the two codes related to the abrupt aerodynamic response and the influence of the controllable flap. The trailing edge flap is actuated to alleviate the added loads from a non-uniform inflow mimicking a half-wake situation, using different control methods and maximum flap angles. Three
different control inputs are simulated: a prescribed flap angle based on the a priori knowledge of the inflow velocity, a controller based on the blade root flap-wise moment feedback, and finally a controller based on a Pitot tube velocity feedback measured at flap mid-span. Good agreement is found between
EllipSys3D and HAWC2 in the prediction of the dynamic blade loads, considering the high complexity of the flow case.
| Original language | English |
|---|---|
| Title of host publication | Proceedings of EWEA 2012 - European Wind Energy Conference & Exhibition |
| Number of pages | 13 |
| Publisher | European Wind Energy Association (EWEA) |
| Publication date | 2012 |
| Publication status | Published - 2012 |
| Event | EWEC 2012 - European Wind Energy Conference & Exhibition - Copenhagen, Denmark Duration: 16 Apr 2012 → 19 Apr 2012 http://events.ewea.org/annual2012/ |
Conference
| Conference | EWEC 2012 - European Wind Energy Conference & Exhibition |
|---|---|
| Country/Territory | Denmark |
| City | Copenhagen |
| Period | 16/04/2012 → 19/04/2012 |
| Internet address |