Rapid scanning, three-dimensional, hot-wire anemometer surveys for wing tip vortices in the Ames 40- by 80-foot wind tunnel

Detailed grid generated turbulent analysis has been completed using a three-dimensional hot-wire anemometer and traversing mechanism to identify a homogeneous, isotropic flow region downstream of a square mesh. The three-dimensional fluctuating velocity measurements were recorded along the centerline of a wind tunnel test section and spatially over the entire wind tunnel cross section downstream of the square mesh. Turbulent intensities for various grid sizes and Reynolds numbers ranged from a minimum of 0.2 percent to a maximum of 2.2 percent in each of the three principal velocity directions. Spatial homogeneity and isotropy were determined for several turbulent flow conditions and downstream positions using the method of covariances. Covariances, in theory, should approach zero asymptotically; however, in practice, this was not achievable. A subjective judgment is required to determine downstream location where the variance of the three covariances reaches a value close to zero. The average standard deviation provides an estimate for defining the limit or subjective threshold needed to determine the onset of homogeneous, isotropic flow. Implementing this threshold, a quantitative method was developed for predicting the streamwise location for the onset of the homogeneous, isotropic flow region downstream of a 25.4 mm square grid as a function of Reynolds number. A comparison of skewness, determined from one-dimensional hot wire anemometer measurements, and covariances, determined from three dimensional hot wire anemometer measurements, indicates a need for caution when relying solely on one-dimensional measurements for determination of turbulence isotropy. The comprehensive three-dimensional characterization also provides an improved understanding of spatial distribution of fundamental turbulence quantities generated by the grid within a low-speed wind tunnel. [S0098-2202(00)02501-3]

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A Study of Water Surface Deformation Due to Tip Vortices Wing-in-Ground Effect

Journal of Ship Research ◽

10.5957/jsr.2007.51.2.182 ◽

2007 ◽

Vol 51 (02) ◽

pp. 182-186

Author(s):

Tracie J. Barber

Keyword(s):

Water Surface ◽

Surface Deformation ◽

Three Dimensional ◽

Ground Effect ◽

Aerodynamic Performance ◽

The Body ◽

Vehicle Design ◽

Two Dimensional ◽

Tip Vortices ◽

Wing Tip

The accurate prediction of ground effect aerodynamics is an important aspect of wing-in-ground (WIG) effect vehicle design. When WIG vehicles operate over water, the deformation of the nonrigid surface beneath the body may affect the aerodynamic performance of the craft. The likely surface deformation has been considered from a theoretical and numerical position. Both two-dimensional and three-dimensional cases have been considered, and results show that any deformation occurring on the water surface is likely to be caused by the wing tip vortices rather than an increased pressure distribution beneath the wing.

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The aeroacoustics of finite wall-mounted square cylinders

Journal of Fluid Mechanics ◽

10.1017/jfm.2017.682 ◽

2017 ◽

Vol 832 ◽

pp. 287-328 ◽

Cited By ~ 12

Author(s):

Ric Porteous ◽

Danielle J. Moreau ◽

Con J. Doolan

Keyword(s):

Boundary Layer ◽

Experimental Study ◽

Reynolds Number ◽

Wind Tunnel ◽

Three Dimensional ◽

Flow Structures ◽

Hot Wire ◽

Radiated Noise ◽

Aspect Ratios ◽

Square Cylinders

This paper presents the results of an experimental study that relates the flow structures in the wake of a square finite wall-mounted cylinder with the radiated noise. Acoustic and hot-wire measurements were taken in an anechoic wind tunnel. The cylinder was immersed in a near-zero-pressure gradient boundary layer whose thickness was 130 % of the cylinder width, $W$. Aspect ratios were in the range $0.29\leqslant L/W\leqslant 22.9$ (where $L$ is the cylinder span), and the Reynolds number, based on width, was $1.4\times 10^{4}$. Four shedding regimes were identified, namely R0 ($L/W<2$), RI ($2<L/W<10$), RII ($10<L/W<18$) and RIII ($L/W>18$), with each shedding regime displaying an additional acoustic tone as the aspect ratio was increased. At low aspect ratios (R0 and RI), downwash dominated the wake, creating a highly three-dimensional shedding environment with maximum downwash at $L/W\approx 7$. Looping vortex structures were visualised using a phase eduction technique. The principal core of the loops generated the most noise perpendicular to the cylinder. For higher aspect ratios in RII and RIII, the main noise producing structures consisted of a series of inclined vortex filaments, where the angle of inclination varied between vortex cells.

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The Effect of the Source Location on the Acoustic Excitation on Laminar-Turbulent Transition on Swept Wing Boundary Layer

Volume 1: Fora, Parts A and B ◽

10.1115/fedsm2002-31397 ◽

2002 ◽

Author(s):

B. Gu¨lac¸ti ◽

S. Aubrun ◽

A. Seraudie ◽

D. Arnal

Keyword(s):

Wind Tunnel ◽

Test Section ◽

Three Dimensional ◽

Source Location ◽

Sound Level ◽

Acoustic Excitation ◽

Hot Wire ◽

Swept Wing ◽

Turbulent Transition ◽

Laminar Turbulent Transition

The effect of the source location and the direction of the propagation on the laminar-turbulent transition on swept-wing three-dimensional boundary layers are investigated experimentally. Also the crossflow case is handled in detail. The source for the acoustic excitation is placed in four different locations: in front of the wing, on top of the test section, behind the wing and in front of the wind tunnel. Three different experimental cases (streamwise, crossflow and mixed cases) are examined for each location with two different excitation bands. For the most efficient frequency ranges and the highest sound pressure levels an upstream shift of transition motion between 20%–35% of chord length for streamwise case and between 5%–10% for the crossflow case are observed. While in front of the wing and behind the wing are the most efficient loudspeaker positions in the streamwise case, in the crossflow case the most efficient locations are observed to be in front of the wing and on top of the test section. It is concluded that acoustic sound level plays a more important role in the upstream shift of the transition than the source location and placing the loudspeaker in front of the wind tunnel is not an efficient position. For the crossflow instabilities dominated transition the stationary vortices are clearly seen from the velocity contours obtained by the hot-wire. Secondary instabilities couldn’t be observed in the hot-wire spectra. The surface roughness of the wing that is reduced to 0.25µm does not change the transition location in the crossflow case.

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Performance Assessment of Transition Models for Three-Dimensional Flow Over NACA4412 Wings at Low Reynolds Numbers

Journal of Fluids Engineering ◽

10.1115/1.4040228 ◽

2018 ◽

Vol 140 (12) ◽

Cited By ~ 6

Author(s):

İlyas Karasu ◽

Mustafa Özden ◽

Mustafa Serdar Genç

Keyword(s):

Reynolds Number ◽

Secondary Flow ◽

Flow Separation ◽

Three Dimensional ◽

Axial Flow ◽

Reynolds Numbers ◽

3D Flow ◽

Tip Vortices ◽

Transition Models ◽

Wing Tip

The performance of the transition models on three-dimensional (3D) flow of wings with aspect ratios (AR) of 1 and 3 at low Reynolds number was assessed in this study. For experimental work; force measurements, surface oil and smoke-wire flow visualizations were performed over the wings with NACA4412 section at Reynolds numbers of 2.5 × 104, 5 × 104, and 7.5 × 104 and the angles of attack of 8 deg, 12 deg, and 20 deg. Results showed that the AR had significant effects on the 3D flow structure over the wing. According to the experimental and numerical results, the flow over the wing having lower ARs can be defined with wingtip vortices, axial flow, and secondary flow including spiral vortex inside the separated flow. When the angle of attack and Reynolds number was increased, wing-tip vortices were enlarged and interacted with the axial flow. At higher AR, flow separation was dominant, whereas wing-tip vortices suppressed the flow separation over the wing with lower AR. In the numerical results, while there were some inconsistencies in the prediction of lift coefficients, the predictions of drag coefficients for two transition models were noticeably better. The performance of the transition models judged from surface patterns was good, but the k–kL–ω was preferable. Secondary flow including spiral vortices near the surface was predicted accurately by the k–kL–ω. Consequently, in comparison with experiments, the predictions of the k–kL–ω were better than those of the shear stress transport (SST) transition.

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Numerical Calculations of Wing Tip Vortices and Effects of Suction at Wing Tip

Computational Technologies for Fluid/Thermal/Structural/Chemical Systems With Industrial Applications, Volume 1 ◽

10.1115/pvp2002-1589 ◽

2002 ◽

Author(s):

S. Okada ◽

N. Arai ◽

K. Hiraoka

Keyword(s):

Three Dimensional ◽

Turbulence Models ◽

Experimental Results ◽

Numerical Calculations ◽

Analysis Software ◽

Tip Vortices ◽

Fluid Analysis ◽

Induced Drag ◽

Wing Tip ◽

Good Agreement

In three-dimensional wing, the induced drag occurs by wing tip vortices. So it is important to study the characteristics of wing tip vortices in order to reduce the induced drag. In this paper, at first comparing the numerically calculated results of three-dimensional incompressible flow using several turbulence models and the law speed wind tunnel experimental results using a two-dimensional hot wire anemometer, the characteristics of wing tip vortices are studied. In the numerical calculations, the multipurpose fluid analysis software FLUENT and the pre-processor GAMBIT are used on popular PC. The numerical results that were obtained by using the RNG k-ε turbulence model is good agreement with the experimental results. Then controlling the flow near the wing tip by suction, the effects against wing tip vortices are studied by numerically and experimentally. It is shown by numerical calculation and experiment that the strength of wing tip vortices decrease by appropriate suction at the wing tip.

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Wind-Tunnel Tests and Computer Simulations of Buoyant Wing-Tip Vortices

Journal of Aircraft ◽

10.2514/3.58682 ◽

1976 ◽

Vol 13 (7) ◽

pp. 495-499 ◽

Cited By ~ 3

Author(s):

R. C. Costen ◽

R. E. Davidson ◽

G. T. Rogers

Keyword(s):

Wind Tunnel ◽

Computer Simulations ◽

Wind Tunnel Tests ◽

Tip Vortices ◽

Wing Tip

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Experimental investigation of wing tip vortices in the near-field

EPJ Web of Conferences ◽

10.1051/epjconf/201919600025 ◽

2019 ◽

Vol 196 ◽

pp. 00025

Author(s):

Robert Stepanov ◽

Vladimir Pakhov ◽

Andrey Bozhenko ◽

Alexander Kusyumov ◽

Sergey Mikhailov ◽

...

Keyword(s):

Experimental Investigation ◽

Wind Tunnel ◽

Vortex Core ◽

Near Field ◽

Core Radius ◽

Tip Vortices ◽

Wing Tip ◽

Good Agreement

Results of an experimental investigation related to near-field wing tip vortices are presented. The measurements were carried out using a PIV-system in T-1K wind tunnel of KNRTU-KAI. Q-criterion and crosssectional lines method were used to determine vortex core locations, which showed a good agreement. It is shown that the circulation of tip vortices remains constant at low to moderate angles of attack, and decreases in the stream-wise direction for higher angles of attack. It is also shown that the vortex core radius increases in the stream-wise direction, taking larger values at higher angles of attack.

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Permissible three-dimensional testing in a two-dimensional adaptive wall wind tunnel

AIAA Journal ◽

10.2514/3.13578 ◽

1997 ◽

Vol 35 ◽

pp. 749-750

Author(s):

David Sumner ◽

Ewart Brundrett

Keyword(s):

Wind Tunnel ◽

Three Dimensional ◽

Two Dimensional

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