Aircraft Vortices in Stably Stratified and Weakly Turbulent Atmospheres: Simulation and Modeling

This study investigates the influence, on aircraft wake vortex behavior, of atmospheres that are stably stratified (neutral to very strong) and weakly turbulent, by means of large-eddy simulations at very high Reynolds number and on relatively fine grids. The atmospheric fields are first generated u...

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Veröffentlicht in:	AIAA journal 2013-03, Vol.51 (3), p.551-566
Hauptverfasser:	De Visscher, I, Bricteux, L, Winckelmans, G
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Sprache:	eng
Schlagworte:	Aerodynamics Air transportation and traffic Aircraft Applied sciences Atmosphere Computational fluid dynamics Decay Deformation Exact sciences and technology Fluid flow Ground, air and sea transportation, marine construction Large eddy simulation Reynolds number Simulation Turbulence Turbulence models Turbulent flow Vortices
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creator	De Visscher, I Bricteux, L Winckelmans, G
description	This study investigates the influence, on aircraft wake vortex behavior, of atmospheres that are stably stratified (neutral to very strong) and weakly turbulent, by means of large-eddy simulations at very high Reynolds number and on relatively fine grids. The atmospheric fields are first generated using large-eddy simulations of forced and stratified turbulence reaching a statistically stationary state. The obtained fields are shown to be realistic and consistent with the literature. A pair of counter-rotating vortices, with relatively tight cores, is then put in the obtained fields and evolved. The evolution of the wake vortex topology, transport, and decay is analyzed in depth by measuring the wake vortex characteristics in all cross planes. The vortex transport and deformation are related to the stratification and turbulence levels. Stratification combined with weak turbulence is seen to strongly affect the Crow instability development. Different decay mechanisms are identified, related to the interactions with the turbulence, the turbulent baroclinic vorticity, and/or between the vortices themselves. Finally, improved simplified models of vortex altitude evolution and of vortex decay (with two phases) are proposed and calibrated on the present results. They yield good agreement with the large-eddy simulation results and are usefully integrated in our operational models.
doi_str_mv	10.2514/1.J051742
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Finally, improved simplified models of vortex altitude evolution and of vortex decay (with two phases) are proposed and calibrated on the present results. They yield good agreement with the large-eddy simulation results and are usefully integrated in our operational models.</abstract><cop>Reston, VA</cop><pub>American Institute of Aeronautics and Astronautics</pub><doi>10.2514/1.J051742</doi><tpages>16</tpages></addata></record>
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subjects	Aerodynamics Air transportation and traffic Aircraft Applied sciences Atmosphere Computational fluid dynamics Decay Deformation Exact sciences and technology Fluid flow Ground, air and sea transportation, marine construction Large eddy simulation Reynolds number Simulation Turbulence Turbulence models Turbulent flow Vortices
title	Aircraft Vortices in Stably Stratified and Weakly Turbulent Atmospheres: Simulation and Modeling
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