Abstract To study the unsteady wind turbine load response under the atmospheric boundary-layer turbulence, we use a measured spectral model from a field experiment to generate atmospheric turbulent flow under different stability and analyze the loads of a full-scale 5 MW wind turbine based on the blade element momentum theory. The results of the spectral analysis show that the measured spectral model has a −1 power law region with higher turbulent kinetic energy relative to other standard spectral models, which indicates an energy-dominant boundary-layer turbulence. By the spectral analysis of the wind-turbine loads, there are three critical frequency: energy-dominant frequency, decoupling frequency and wind-turbine rotation frequency. Below the energy-dominant frequency, power and thrust respond strongly to the energy-dominant boundary-layer turbulence. The modulation effect of the atmospheric boundary-layer turbulence on the unsteady wind-turbine response continues until the decoupling frequency. After that, the power and thrust are mainly influenced by the wind-turbine rotation frequency. The decoupling frequency is strongly correlated with the tip speed ratio, but is weakly influenced by the atmospheric stability. A mathematical model of decoupling frequency and tip speed ratio is also established, which can help to determine the range of turbulence scales that can influence the wind turbine performance.

Load

Load