The evolution of three-dimensionally localized vortices in shear flows. Linear theory

The evolution of a small-amplitude localized vortex disturbance in an unbounded shear flow with the linear velocity profile is investigated. Based on the exact solution of the initial problem for basic flow, a revision is made of the theoretical approach (suggested by Levinski (1991) and subsequentl...

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Bibliographic Details
Published in:arXiv.org 2004-07
Main Authors: Shukhman, I G, Levinski, V B
Format: Article
Language:English
Subjects:
Boundary layer
Evolution
Fluid dynamics
Fluid flow
Horizontal orientation
Horseshoe vortices
Laminar boundary layer
Shear flow
Turbulent boundary layer
Velocity distribution
Vortices
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Summary:The evolution of a small-amplitude localized vortex disturbance in an unbounded shear flow with the linear velocity profile is investigated. Based on the exact solution of the initial problem for basic flow, a revision is made of the theoretical approach (suggested by Levinski (1991) and subsequently further developed in a series of other publications) in which the vortex evolution is described in terms of Fluid Impulse of the vortex "core". Although the theoretical predictions obtained on the basis of this approach were excellently confirmed in subsequent experimental studies, its inconsistency is demonstrated in this study. According to the solution obtained, the localized vortex increases slowly (as power-law with the time) and attains an almost "horizontal" orientation, unlike the previous theory (Levinski, 1991) that predicts the more rapid growth and vortex orientation at the angle of 45 degrees to the flow direction. On the other hand, just the rapid increase and the angle of 45 degrees to the outer flow direction are characteristic for hairpin vortices observed in turbulent boundary layers or artificially synthesized vortices in laminar boundary layers. Thus the issue of adequate theoretical interpretation of the evolution of localized vortices is again on the agenda.
ISSN:2331-8422