Abstract
The capability of a model based on Large-Eddy Simulations to reproduce turbulence measurements over a forest of heterogeneous density is assessed. Measurements are obtained from an experimental campaign with a continuous wave lidar mounted on the nacelle of a wind turbine (not considered in this work) that scans over a cone in the upstream direction. The measurements are then compared with the results of the LES of the atmospheric boundary layer in neutral stability conditions. The model comprises a full description of the forest over a large area upstream of the lidar by using plant area density data obtained with airborne laser scans, which also provides the terrain elevation. Although the relatively restricted mesh refinement of the LES leads to a limited representation of turbulence towards higher frequencies, comparisons with the measurements show that the model is capable of reproducing the turbulence levels and spatial coherence in the hypothetical rotor plane. Results permit to conclude that the LES-based model is a suitable tool to identify and predict the microscale effects that terrain features have in the wind resource for sites of high complexity. This work exemplifies the challenges associated to the process and interpretation of data from the employed lidar and its setup, for which a filtering technique potentially useful in future studies is presented.
Highlights
Measurements are obtained from an experimental campaign with a continuous wave lidar mounted on the nacelle of a wind turbine that scans over a cone in the upstream direction
The model comprises a full description of the forest over a large area upstream of the lidar by using plant area density data obtained with airborne laser scans, which provides the terrain elevation
Results permit to conclude that the Large-Eddy Simulations (LES)-based model is a suitable tool to identify and predict the microscale effects that terrain features have in the wind resource for sites of high complexity
Summary
As wind parks are built in remote locations, there is a growing prospect that these will be located on areas that represent a bigger challenge for the wind resource assessment, such as complex terrain and forested regions. The capability of a model based on Large-Eddy Simulations (LES) to reproduce turbulence measurements over a forest of heterogeneous density is assessed. Measurements are obtained from an experimental campaign with a continuous wave lidar mounted on the nacelle of a wind turbine (not considered in this work) that scans over a cone in the upstream direction.
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