2017
DOI: 10.1063/1.5000733
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Effects of an upstream triangular plate on the wing-body junction flow

Abstract: The use of a short triangular leading-edge plate at the base of a wing-body junction is experimentally evaluated as a passive control method to mitigate horseshoe vortices. The impact of the plate geometry on the efficacy of the control is assessed by considering triangular plates that vary in length and thickness. The wing model is a NACA 0020 airfoil. The Reynolds number based on the chord length is varied from Re c = 25, 000 to 75, 000. The incoming boundary layer is laminar. Particle Image Velocimetry is u… Show more

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Cited by 5 publications
(4 citation statements)
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“…Even though the proposed mechanisms for it show some differences, all observations agree the disappearance of the PHV mainly occurs in the region very close to the cylinder surface. The turbulent HV system triggers the local scour process in front of vertical piers on a flat loose bed by significantly amplifying the bed shear stress in this region [6,8,14]. The amplification of the bed shear stress is tightly related to the vertical position, size, and strength of the HVs as its magnitude is determined directly by the wall-normal gradient of the streamwise velocity, ∂U/∂y, induced by the HVs at the bed surface.…”
Section: Disappearance Of Phvmentioning
confidence: 99%
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“…Even though the proposed mechanisms for it show some differences, all observations agree the disappearance of the PHV mainly occurs in the region very close to the cylinder surface. The turbulent HV system triggers the local scour process in front of vertical piers on a flat loose bed by significantly amplifying the bed shear stress in this region [6,8,14]. The amplification of the bed shear stress is tightly related to the vertical position, size, and strength of the HVs as its magnitude is determined directly by the wall-normal gradient of the streamwise velocity, ∂U/∂y, induced by the HVs at the bed surface.…”
Section: Disappearance Of Phvmentioning
confidence: 99%
“…Depending on the regime of the approaching flow at the location of the cylinder, the horseshoe vortex (HV) system appears as a laminar or turbulent system, respectively [7]. The turbulent HV system oscillates randomly in front of the cylinder, inducing highly elevated means and fluctuations in bed shear stress [8]. Therefore, a full understanding of the evolution of the turbulent HV system is necessary for understanding, predicting, and controlling the initial stage of the local scour in front of cylinders.…”
Section: Introductionmentioning
confidence: 99%
“…These vortices include a bound vortex that encircles the small cylinder and two trailing vortices extending from the bound vortex into the wake region. The number of Hs and their oscillation frequency can vary depending on the regime, significantly affecting the wall shear stress 38 . Therefore, gaining a comprehensive understanding of the turbulent H-system is crucial for comprehending, predicting, and controlling the local dynamics in front of cylinders.…”
Section: Resultsmentioning
confidence: 99%
“…The most studied and used solutions are the leading-edge fairing and the whole-body fairing. The former alters the shape of the wing nose in order to reduce the adverse pressure gradient generated by the leading edge, thus suppressing the onset of the horseshoe vortex [14][15][16][17][18][19]. The latter consists in wrapping the entire junction area with a fairing designed to suppress flow separation.…”
Section: Introductionmentioning
confidence: 99%