Leading edge vortex formation and detachment on a flat plate undergoing simultaneous pitching and plunging motion: Experimental and computational study

A Numerical Analysis is conducted to investigate the Leading Edge Vortex (LEV) dynamics of an elliptic flat plate undergoing 2 dimensional symmetric flapping motion in hover. The plate is modeled with an aspect ratio of 3 and a flapping trajectory resulting in Reynolds number 225 is studied. The leading edge vortex stability is analyzed as a function of the non dimensional formation number and a vorticity transport analysis is carried to understand the flux budgets present. The LEV formation number is found to be 2.6. The results of vorticity analysis show the highly three dimensional nature of the LEV growth for an elliptic geometry.

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Vortex formation and shedding from a cyber-physical pitching plate

Journal of Fluid Mechanics ◽

10.1017/jfm.2016.134 ◽

2016 ◽

Vol 793 ◽

pp. 229-247 ◽

Cited By ~ 28

Author(s):

Kyohei Onoue ◽

Kenneth S. Breuer

Keyword(s):

Flat Plate ◽

Physical System ◽

Vortex Formation ◽

Leading Edge ◽

Cyber Physical System ◽

Leading Edge Vortex ◽

Unsteady Aerodynamic ◽

Wide Range ◽

Edge Vortex ◽

Aerodynamic Torque

We report on the dynamics of the formation and growth of the leading-edge vortex and the corresponding unsteady aerodynamic torque induced by large-scale flow-induced oscillations of an elastically mounted flat plate. All experiments are performed using a high-bandwidth cyber-physical system, which enables the user to access a wide range of structural dynamics using a feedback control system. A series of two-dimensional particle image velocimetry measurements are carried out to characterize the behaviour of the separated flow structures and its relation to the plate kinematics and unsteady aerodynamic torque generation. By modulating the structural properties of the cyber-physical system, we systematically analyse the formation, strength and separation of the leading-edge vortex, and the dependence on kinematic parameters. We demonstrate that the leading-edge vortex growth and strength scale with the characteristic feeding shear-layer velocity and that a potential flow model using the measured vortex circulation and position can, when coupled with the steady moment of the flat plate, accurately predict the net aerodynamic torque on the plate. Connections to previous results on optimal vortex formation time are also discussed.

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Video: Leading edge vortex formation in aquatic swimming

10.1103/aps.dfd.2014.gfm.v0071 ◽

2014 ◽

Author(s):

Mohsen Daghooghi ◽

Richard G. Bottom ◽

Iman Borazjani

Keyword(s):

Vortex Formation ◽

Leading Edge ◽

Leading Edge Vortex ◽

Edge Vortex

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Initiation of Leading-Edge-Vortex Formation on Finite Wings in Unsteady Flow

53rd AIAA Aerospace Sciences Meeting ◽

10.2514/6.2015-0546 ◽

2015 ◽

Cited By ~ 3

Author(s):

Yoshikazu Hirato ◽

Minao Shen ◽

Sachin Aggarwal ◽

Ashok Gopalarathnam ◽

Jack R. Edwards

Keyword(s):

Unsteady Flow ◽

Vortex Formation ◽

Leading Edge ◽

Leading Edge Vortex ◽

Edge Vortex

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Experimental investigation on the leading-edge vortex formation and detachment mechanism of a pitching and plunging plate

Journal of Fluid Mechanics ◽

10.1017/jfm.2020.509 ◽

2020 ◽

Vol 901 ◽

Cited By ~ 2

Author(s):

Zhen-Yao Li ◽

Li-Hao Feng ◽

Johannes Kissing ◽

Cameron Tropea ◽

Jin-Jun Wang

Keyword(s):

Experimental Investigation ◽

Vortex Formation ◽

Leading Edge ◽

Leading Edge Vortex ◽

Edge Vortex ◽

Image Position

Abstract

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Parameter Variation and the Leading-Edge Vortex of a Rotating Flat Plate

AIAA Journal ◽

10.2514/1.j052381 ◽

2014 ◽

Vol 52 (2) ◽

pp. 348-357 ◽

Cited By ~ 18

Author(s):

Craig J. Wojcik ◽

James H. J. Buchholz

Keyword(s):

Flat Plate ◽

Leading Edge ◽

Parameter Variation ◽

Leading Edge Vortex ◽

Edge Vortex

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Effects of Reynolds number on leading-edge vortex formation dynamics and stability in revolving wings

Journal of Fluid Mechanics ◽

10.1017/jfm.2021.950 ◽

2021 ◽

Vol 931 ◽

Author(s):

Long Chen ◽

Luyao Wang ◽

Chao Zhou ◽

Jianghao Wu ◽

Bo Cheng

Keyword(s):

Reynolds Number ◽

Steady State ◽

Numerical Methods ◽

Vortex Formation ◽

Leading Edge ◽

Leading Edge Vortex ◽

Formation Dynamics ◽

Edge Vortex ◽

Vorticity Balance ◽

Vortex Compression

The mechanisms of leading-edge vortex (LEV) formation and its stable attachment to revolving wings depend highly on Reynolds number ( $\textit {Re}$ ). In this study, using numerical methods, we examined the $\textit {Re}$ dependence of LEV formation dynamics and stability on revolving wings with $\textit {Re}$ ranging from 10 to 5000. Our results show that the duration of the LEV formation period and its steady-state intensity both reduce significantly as $\textit {Re}$ decreases from 1000 to 10. Moreover, the primary mechanisms contributing to LEV stability can vary at different $\textit {Re}$ levels. At $\textit {Re} <200$ , the LEV stability is mainly driven by viscous diffusion. At $200<\textit {Re} <1000$ , the LEV is maintained by two distinct vortex-tilting-based mechanisms, i.e. the planetary vorticity tilting and the radial–tangential vorticity balance. At $\textit {Re}>1000$ , the radial–tangential vorticity balance becomes the primary contributor to LEV stability, in addition to secondary contributions from tip-ward vorticity convection, vortex compression and planetary vorticity tilting. It is further shown that the regions of tip-ward vorticity convection and tip-ward pressure gradient almost overlap at high $\textit {Re}$ . In addition, the contribution of planetary vorticity tilting in LEV stability is $\textit {Re}$ -independent. This work provides novel insights into the various mechanisms, in particular those of vortex tilting, in driving the LEV formation and stability on low- $\textit {Re}$ revolving wings.

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