Generating an artificially thickened boundary layer to simulate the neutral atmospheric boundary layer

We aim to generate an artificially thickened boundary layer in a wind tunnel with properties similar to the neutral atmospheric boundary layer. We implement a variant of Counihan's technique which uses a combination of a castellated barrier, elliptical vortex generators, and surface roughness t...

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Bibliographic Details
Published in:Journal of wind engineering and industrial aerodynamics 2015-10, Vol.145, p.1-16
Main Authors: Hohman, T.C., Buren, T. Van, Martinelli, L., Smits, A.J.
Format: Article
Language:English
Subjects:
Atmospheric boundary layer
Boundary layer
Constants
Density
Spectra
Turbulence intensity
Vortex generators
Wind tunnels
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Summary:We aim to generate an artificially thickened boundary layer in a wind tunnel with properties similar to the neutral atmospheric boundary layer. We implement a variant of Counihan's technique which uses a combination of a castellated barrier, elliptical vortex generators, and surface roughness to create a thick boundary layer in a relatively short wind tunnel. We demonstrate an improved spanwise uniformity when compared to Counihan's original design by using a tighter vortex generator spacing with a smaller wedge angle which keeps the frontal area approximately constant while keeping the turbulence intensity and power spectral density unchanged. With this arrangement we were able to generate a 1:1000 scale atmospheric boundary layer at Reθ∼106 displaying logarithmic mean velocity behavior, a constant stress region, and turbulence intensities consistent with atmospheric boundary layer measurements and high Reynolds number laboratory rough-wall boundary layers. In addition, the power spectral density of the longitudinal velocity fluctuations agrees well with von Kármán's model spectrum, and the turbulence integral length scale agrees well with data from atmospheric boundary layer measurements. •Simulation of a 1:1000 scale neutral atmospheric boundary layer profile over rural terrain for vertical axis wind turbine studies.•Tighter vortex generator spacing achieves greater spanwise uniformity.•Increased spanwise uniformity decreases required formation distances.•Turbulence spectra and longitudinal integral length scale, Lux, unaffected by vortex generator spacing.•Profile validated with Engineering Science Data Unit 74031 and high Reynolds number laboratory boundary layers.
ISSN:0167-6105
1872-8197
DOI:10.1016/j.jweia.2015.05.012