Abstract
Micrometeorological observations from a tower, an eddy-covariance (EC) station and an unmanned aircraft system (UAS) at the WINSENT test-site are used to validate a computational fluid dynamics (CFD) model, driven by a mesoscale model. The observation site is characterised by a forested escarpment in a complex terrain. A two-day measurement campaign with a flow almost perpendicular to the escarpment is analysed. The first day is dominated by high wind speeds, while, on the second one, calm wind conditions are present. Despite some minor differences, the flow structure, analysed in terms of horizontal wind speeds, wind direction and inclination angles shows similarities for both days. A real-time strategy is used for the CFD validation with the UAS measurement, where the model follows spatially and temporally the aircraft. This strategy has proved to be successful. Stability indices such as the potential temperature and the bulk Richardson number are calculated to diagnose atmospheric boundary layer (ABL) characteristics up to the highest flight level. The calculated bulk Richardson values indicate a dynamically unstable region behind the escarpment and near the ground for both days. At higher altitudes, the ABL is returning to a near neutral state. The same characteristics are found in the model but only for the first day. The second day, where shear instabilities are more dominant, is not well simulated. UAS proves its great value for sensing the flow over complex terrains at high altitudes and we demonstrate the usefulness of UAS for validating and improving models.
Highlights
To achieve the objective of making the European Union climate-neutral by 2050, it will be necessary to maximize the deployment of renewable energy in the years to come [1]
Station, and an unmanned aircraft system are used for the numerical validation
The dataset provided by the airborne measurements demonstrates how an unmanned aircraft system (UAS) system can be helpful for the atmospheric boundary layer (ABL) investigation by providing a high spatial resolution of the airflow near the escarpment
Summary
To achieve the objective of making the European Union climate-neutral by 2050, it will be necessary to maximize the deployment of renewable energy in the years to come [1]. The clean energy transition involves encouraging high levels of renewable energy penetrations. Harvesting power from wind power is one of the fastest-growing renewable energy methods. To meet the climate-neutral target, more wind energy capacity will be installed in the coming years. Independent of the exact number of new installations, most of them will be onshore [2].
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