Abstract
Scanning LiDARs can be used to obtain three-dimensional wind measurements in and beyond the atmospheric surface layer. In this work, metrics characterizing wind turbine wakes are derived from LiDAR observations and from large-eddy simulation (LES) data, which are used to recreate the LiDAR scanning geometry. The metrics are calculated for two-dimensional planes in the vertical and cross-stream directions at discrete distances downstream of a turbine under single-wake conditions. The simulation data are used to estimate the uncertainty when mean wake characteristics are quantified from scanning LiDAR measurements, which are temporally disjunct due to the time that the instrument takes to probe a large volume of air. Based on LES output, we determine that wind speeds sampled with the synthetic LiDAR are within 10% of the actual mean values and that the disjunct nature of the scan does not compromise the spatial variation of wind speeds within the planes. We propose scanning geometry density and coverage indices, which quantify the spatial distribution of the sampled points in the area of interest and are valuable to design LiDAR measurement campaigns for wake characterization. We find that scanning geometry coverage is important for estimates of the wake center, orientation and length scales, while density is more important when seeking to characterize the velocity deficit distribution.
Highlights
In order to improve the efficiency of wind farms, it is necessary to maximize their overall power production and to minimize the fatigue loads experienced by each turbine
This subsection quantifies how the wind speed retrieved from each scanned value (ŮL ) compares to both the mean (U L ) and instantaneous (UL ) values for the synthetic scans obtained from an large-eddy simulation (LES)
This serves as an estimate of the level of uncertainty when large volumes of wind turbine wake data probed by a pulsed scanning LiDAR are assumed to be representative of mean or instantaneous conditions
Summary
In order to improve the efficiency of wind farms, it is necessary to maximize their overall power production and to minimize the fatigue loads experienced by each turbine. This in turn relies on a quantitative understanding of the flow that meets each wind turbine and its interaction with the tower and rotor. The upwind turbines experience undisturbed (i.e., free stream) conditions, where turbulence is determined by atmospheric stability and topographic characteristics As they extract energy from the wind, turbines disturb the flow that moves through them generating a wake [1]. Integrating measurements and models offers the potential to advance quantitative analyses of wake characteristics and atmospheric flows to determine optimal wind farm layout and enable efficient wind turbine control strategies
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