Interactions of large-scale free-stream turbulence with turbulent boundary layers

Doğan, Eda; Hanson, Ronald; Ganapathisubramani, Bharathram

doi:10.1017/jfm.2016.435

Cited by 52 publications

(171 citation statements)

References 45 publications

(121 reference statements)

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“…5 as a solid line. Previous studies have reported an increase in TBL skin friction under FST (Blair 1983;Hancock and Bradshaw 1989;Stefes and Fernholz 2004;Dogan et al 2016). Figure 3 confirms this trend with increasing FST.…”

Section: Reynolds Dependence and Self-similaritysupporting

confidence: 80%

“…TBL transition was promoted by the addition of a trip wire at the leading edge of the flat plate where the TBL develops. The details of the experimental setup and motor schemes of the active grid can be found in Dogan et al (2016). The superscript + will denote quantities normalised with the friction velocity U , and the kinematic viscosity , as for instance in the wall-normal coordinate y + = yU ∕ , or the mean streamwise velocity U + = U∕U .…”

Section: Measurement Methods and Experimental Setupmentioning

confidence: 99%

“…This study combines the merits of these two measurement techniques to compare the skin-friction coefficient (C f = 2U 2 ∕U 2 ∞ ) obtained from a fitting to the mean velocity profile with a direct and independent measurement technique such as OFI. Furthermore, results are compared with Preston tube measurements from Dogan et al (2016) conducted under similar flow conditions.…”

Section: Measurement Methods and Experimental Setupmentioning

confidence: 99%

“…Contrarily, Rodríguez-López et al (2015) proposed to leave these constants free to adopt the value that best fits the data. In addition, this method does not require to prescribe the extent of the logarithmic layer (which can vary under FST conditions, see Dogan et al 2016) and allows a certain uncertainty in the wall-probe initial position.Abstract This experimental investigation deals with the influence of free-stream turbulence (FST) produced by an active grid on the skin friction of a zero-pressure-gradient turbulent boundary layer. Wall shear stress is obtained by oil-film interferometry.…”

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Skin-friction measurements in a turbulent boundary layer under the influence of free-stream turbulence

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increasing FST is known to increase skin friction and to enhance heat transfer (Hancock and Bradshaw 1989;Blair 1983). However, a large number of previous studies focused on the correlation between the increase of skin friction and heat transfer with FST. Hancock and Bradshaw (1989) showed that the effect of FST in the turbulent boundary layer does not only depend on the turbulence intensity level but on a characteristic scale in the FST, which they defined as the dissipation length scale. However, skin-friction coefficients were deduced from logarithmic plots on the assumption that the universal logarithmic law also applies in the presence of FST. Thole and Bogard (1996) performed extensive research on FST levels up to 20% and presented boundary layer statistics that confirmed the validity of the logarithmic law in the mean profiles of the boundary layer for high turbulence levels by comparing direct measurements of total shear stress with values obtained using a Clauser fit to the log region. Similarly, Stefes and Fernholz (2004) compared skin-friction data obtained from oil-film interferometry (OFI), wall hot wire, and Preston tube at relatively high Reynolds numbers and FST levels up to 13%, showing that all skin-friction data points lied within an error band of approximately 6% on C f .Traditional indirect pressure-based methods, such as the Preston tube, rely on the law of the wall and suffer from limitations arising from its intrusive nature. Velocity profile-based methods such as Clauser chart are also of limited applicability, since they also assume the existence of the law of the wall and require the knowledge of its extent and constants beforehand. Contrarily, Rodríguez-López et al. (2015) proposed to leave these constants free to adopt the value that best fits the data. In addition, this method does not require to prescribe the extent of the logarithmic layer (which can vary under FST conditions, see Dogan et al. 2016) and allows a certain uncertainty in the wall-probe initial position.Abstract This experimental investigation deals with the influence of free-stream turbulence (FST) produced by an active grid on the skin friction of a zero-pressure-gradient turbulent boundary layer. Wall shear stress is obtained by oil-film interferometry. In addition, hot-wire anemometry was performed to obtain wall-normal profiles of streamwise velocity. This enables the skin friction to be deduced from the mean profile. Both methods show remarkable agreement for every test case. Although skin friction is shown to increase with FST, the trend with Reynolds number is found to be similar to cases without FST. Furthermore, once the change in the friction velocity is accounted for, the selfsimilarity of the logarithmic region and below (i.e. law of the wall) appears to hold for all FST cases investigated.

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Section: Reynolds Dependence and Self-similaritysupporting

confidence: 80%

Section: Measurement Methods and Experimental Setupmentioning

confidence: 99%

Section: Measurement Methods and Experimental Setupmentioning

confidence: 99%

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confidence: 99%

mentioning

confidence: 99%

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Skin-friction measurements in a turbulent boundary layer under the influence of free-stream turbulence

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Tailoring incoming shear and turbulence profiles for lab‐scale wind turbines

Hearst

Ganapathisubramani

2017

Wind Energy

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An active grid is used to generate a variety of turbulent shear profiles in a wind tunnel. The vertical bars are set to flap through varying angles across the test-section producing a variation in the perceived solidity, resulting in a mean shear. The horizontal bars are used in a fully random operational mode to set the background turbulence level. It is demonstrated that mean velocity profiles with approximately the same shear can be produced with different turbulence intensities and local turbulent Reynolds numbers based on the Taylor microscale, λ. Conversely, it is also demonstrated that flows can be produced with similar turbulence intensity profiles but different mean shear. It is confirmed that the length scales and dynamics, the latter being assessed through the velocity spectra and probability density functions, do not vary significantly across the investigation domain. Such flows are of particular relevance for studies investigating the effect of inflow conditions on obstacles where these studies wish to decouple the effects of turbulence intensity and mean shear, a feat previously unattainable in experimental facilities. Given that the power output of wind turbines is known to be a function of both mean shear and turbulence intensity, the experimental methodology presented herein is invaluable to the wind turbine model testing community who, at present, cannot exert such control authority over the inflow conditions.

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The Use of Active Grids in Experimental Facilities

Hearst

2019

Springer Proceedings in Physics

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Active grids allow for the turbulence in experimental facilities to be tailored through a broad range of turbulence intensities and Reynolds numbers. This work provides an overview of the active grids that presently exist around the globe as well as advances in turbulence research that are a result of their use. Focus is placed on homogeneous turbulent flows, turbulent boundary layers, and model testing.

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Interactions of large-scale free-stream turbulence with turbulent boundary layers

Cited by 52 publications

References 45 publications

Skin-friction measurements in a turbulent boundary layer under the influence of free-stream turbulence

Skin-friction measurements in a turbulent boundary layer under the influence of free-stream turbulence

Tailoring incoming shear and turbulence profiles for lab‐scale wind turbines

The Use of Active Grids in Experimental Facilities

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