Abstract
The diurnal hourly dynamics of the kinetic energy flux density vector, called the Umov vector, and the mean and turbulent components of the kinetic energy are estimated from minisodar measurements of wind vector components and their variances in the lower 200 m layer of the atmosphere. During a 24 h period of continuous minisodar observations, it was established that the mean kinetic energy density dominated in the surface atmospheric layer at altitudes below ~50 m. At altitudes from 50 to 100 m, the relative contributions of the mean and turbulent wind kinetic energy densities depended on the time of the day and the sounding altitude. At altitudes below 100 m, the contribution of the turbulent kinetic energy component is small, and the ratio of the turbulent to mean wind kinetic energy components was in the range 0.01–10. At altitudes above 100 m, the turbulent kinetic energy density sharply increased, and the ratio reached its maximum equal to 100–1000 at altitudes of 150–200 m. A particular importance of the direction and magnitude of the wind effect, that is, of the direction and magnitude of the Umov vector at different altitudes was established. The diurnal behavior of the Umov vector depended both on the time of the day and the sounding altitude. Three layers were clearly distinguished: a near-surface layer at altitudes of 5–15 m, an intermediate layer at altitudes from 15 m to 150 m, and the layer of enhanced turbulence above. The feasibility is illustrated of detecting times and altitudes of maximal and minimal wing kinetic energy flux densities, that is, time periods and altitude ranges most and least favorable for flights of unmanned aerial vehicles. The proposed novel method of determining the spatiotemporal dynamics of the Umov vector from minisodar measurements can also be used to estimate the effect of wind on high-rise buildings and the energy potential of wind turbines.
Highlights
The feasibility is illustrated of detecting times and altitudes of maximal and minimal wing kinetic energy flux densities, that is, time periods and altitude ranges most and least favorable for flights of unmanned aerial vehicles
The proposed novel method of determining the spatiotemporal dynamics of the Umov vector from minisodar measurements can be used to estimate the effect of wind on high-rise buildings and the energy potential of wind turbines
Knowledge of the wind kinetic energy flux density transferred per unit area per unit time is required for analysis and prediction of the dynamic wind effect on objects
Summary
Knowledge of the wind kinetic energy flux density transferred per unit area per unit time (the Umov vector [1]) is required for analysis and prediction of the dynamic wind effect on objects. The sodar data (long time series of continuous observations of vertical profiles of the wind velocity vector components and their variances) provide high spatial and temporal resolution. The present work analyses the diurnal hourly dynamics of the total kinetic energy flux density vector (the Umov vector) caused by both the mean wind and its turbulent component in the ABL at altitudes z = 5–200 m and detects altitudes and times of the day with the most and least intensive wind effect
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