Wingtip vortex structure in the near-field of swept-tapered wings

Wingtip vortices are an important phenomenon in fluid dynamics due to their complex and negative impacts. Despite numerous studies, the current understanding of the inner vortex is very limited; thus, a basis for the design of effective wingtip geometry and vortex manipulation is narrow. This work e...

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Bibliographic Details
Published inPhysics of fluids (1994) Vol. 32; no. 9
Main Authors Skinner, S. N., Green, R. B., Zare-Behtash, H.
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 01.09.2020
Subjects
Aerodynamics
Angle of attack
Commercial aircraft
Diffusion rate
Energy dissipation
Fluid dynamics
Fluid flow
Helicity
Kinetic energy distribution
Reynolds number
Richardson number
Self-similarity
Topology
Trailing vortices
Turbulent diffusion
Velocimetry
Vortices
Vorticity
Wing tip vortices
Wings (aircraft)
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Summary:Wingtip vortices are an important phenomenon in fluid dynamics due to their complex and negative impacts. Despite numerous studies, the current understanding of the inner vortex is very limited; thus, a basis for the design of effective wingtip geometry and vortex manipulation is narrow. This work examines the structure of the trailing vortex shed from a swept-tapered wing, analogous to a commercial aircraft topology. Stereoscopic particle imaging velocimetry has been utilized to compare the vortex structure and development through several angles of attack at various downstream stations for a fixed Reynolds number (Re = 1.5 × 106). After correcting for vortex meander through helicity-based spatial localization of the vortex core, relationships between the vortex core velocity/vorticity fields, core shape, and turbulent properties have been examined. Subsequently, the vortex is found to exhibit a layered structure with slow linear rates of dissipation indicative of laminar diffusion mechanisms, despite being a turbulent vortex. The turbulent kinetic energy distribution in the vortex signals that relaminarization of the inner core occurs. Consideration of the streamline curvature around the core, via examination of the local Richardson number, indicated that a laminar core structure had formed within which large-scale turbulent eddies could not contribute to the turbulent diffusion of vorticity away from the core. The normalized circulation within the vortex core has been shown to exhibit self-similar behavior typical of the fully developed axisymmetric vortices.
ISSN:1070-6631
1089-7666
DOI:10.1063/5.0016353