In situ observations of the influence of a large onshore wind farm on near-surface temperature, turbulence intensity and wind speed profiles - Figure 1. Craig M Smith R J Barthelmie S C Pryor 10.6084/m9.figshare.1011467.v1 https://iop.figshare.com/articles/figure/In_situ_observations_of_the_influence_of_a_large_onshore_wind_farm_on_near_surface_temperature_turbu/1011467 <p><strong>Figure 1.</strong> Overview of the wind farm, including close-up views of the NE and SW locations, and schematic of the unwaked (#1, black), SW farm-waked (#2, red), SW direct-waked (#3, blue), NE farm-waked (#4, green) and NE direct-waked (#5, magenta) wind direction bins. The frequency with which flow greater than 4 ms<sup>−1</sup> was observed in the five directional sectors during 04/04/2012–05/20/2012 is 6.9, 16.6, 7.9, 14.2 and 1.8%, respectively.</p> <p><strong>Abstract</strong></p> <p>Observations of wakes from individual wind turbines and a multi-megawatt wind energy installation in the Midwestern US indicate that directly downstream of a turbine (at a distance of 190 m, or 2.4 rotor diameters (<em>D</em>)), there is a clear impact on wind speed and turbulence intensity (TI) throughout the rotor swept area. However, at a downwind distance of 2.1 km (26 <em>D</em> downstream of the closest wind turbine) the wake of the whole wind farm is not evident. There is no significant reduction of hub-height wind speed or increase in TI especially during daytime. Thus, in high turbulence regimes even very large wind installations may have only a modest impact on downstream flow fields. No impact is observable in daytime vertical potential temperature gradients at downwind distances of >2 km, but at night the presence of the wind farm does significantly decrease the vertical gradients of potential temperature (though the profile remains stably stratified), largely by increasing the temperature at 2 m.</p> 2013-07-16 00:00:00 ne wind direction bins sw 2.4 rotor diameters ti wind farm Environmental Science