Multilevel panel method for wind turbine rotor flow simulations

Abstract: SummaryThe ongoing trend in wind turbine development is towards larger rotors because of the resulting lower cost of energy. These large rotors lead to relatively flexible structures that are more susceptible to the unsteady aerodynamic loading occurring in normal operating conditions. An accurate prediction of these loadings is important for the design of an economically viable and technically reliable wind turbine. Simulation methods of wind turbine aerodynamics currently in use mainly fall into two categori… Show more

“…The accuracy of the selected pressure transducers is well balanced to the prevailing dynamic pressure at the rotating tip of the turbine, whereas the accuracy of experimental pressure data decreases towards the hub. In addition to the results obtained by the ENSOLV numerical solution method the results obtained by a fast multilevel panel method 20,21 that models inviscid, incompressible flow are also shown. Other cases computed with the ENSOLV numerical solution method and compared with experimental data consist of a turbulent wake state (wind speed of 10 m/s, tip speed ratio of 10), a separated flow case (wind speed of 24.12 m/s, tip speed ratio of 4.2) and a standstill condition (wind speed of 29.92 m/s, tip speed ratio 0), the latter only being instructive for the assessment of aerodynamic loads predictions on the rotor in vane position.…”

“…Recent progress 20,21 in reducing the computational burden of the classical panel method for wind turbine applications makes this approach an attractive proposition. Figure 11 shows an example of achieved reductions in integral evaluation time for the newly developed multilevel panel method.…”

“…However, by that time the vast investments in numerical flow simulation methods based on the Euler equations, their successful application, and the prospect of extending the method to general viscous flows was the reason the project was abandoned for good. For wind turbine designs, where the trend is towards higher subsonic rotor tip speeds (currently ~100 m/s), this approach could be revived while keeping the computational costs limited through the use of the fast multilevel panel method 20,21 .…”

Wind Turbine Aerodynamics from an Aerospace Perspective

“…The accuracy of the selected pressure transducers is well balanced to the prevailing dynamic pressure at the rotating tip of the turbine, whereas the accuracy of experimental pressure data decreases towards the hub. In addition to the results obtained by the ENSOLV numerical solution method the results obtained by a fast multilevel panel method 20,21 that models inviscid, incompressible flow are also shown. Other cases computed with the ENSOLV numerical solution method and compared with experimental data consist of a turbulent wake state (wind speed of 10 m/s, tip speed ratio of 10), a separated flow case (wind speed of 24.12 m/s, tip speed ratio of 4.2) and a standstill condition (wind speed of 29.92 m/s, tip speed ratio 0), the latter only being instructive for the assessment of aerodynamic loads predictions on the rotor in vane position.…”

“…Recent progress 20,21 in reducing the computational burden of the classical panel method for wind turbine applications makes this approach an attractive proposition. Figure 11 shows an example of achieved reductions in integral evaluation time for the newly developed multilevel panel method.…”

“…However, by that time the vast investments in numerical flow simulation methods based on the Euler equations, their successful application, and the prospect of extending the method to general viscous flows was the reason the project was abandoned for good. For wind turbine designs, where the trend is towards higher subsonic rotor tip speeds (currently ~100 m/s), this approach could be revived while keeping the computational costs limited through the use of the fast multilevel panel method 20,21 .…”

Wind Turbine Aerodynamics from an Aerospace Perspective

“…Combining the normal velocity from boundary condition (11), the expression for the source strength (14), and the tangential velocity (15) gives an expression for the velocity at the surface, in the inertial coordinate system, as…”

“…The development of advanced multilevel algorithms provides a very significant alleviation of this computational burden. In our work 15 it has been proven that a practical solution can be developed that reduces this burden to O(N ) work. The significance of the multilevel method developed in this work is already illustrated in the same figure and its advantage for large problem sizes is obvious.…”

Fast Multilevel Panel Method for Wind Turbine Rotor Flow Simulations

Interacting Boundary Layer Methods and Applications