Stability of Low-Reynolds-Number Separated Flow Around an Airfoil Near a Wavy Ground

He, Wei; Guan, Yu; Theofilis, Vassilios; Li, Larry K.B.

doi:10.2514/1.j057544

Cited by 21 publications

(6 citation statements)

References 40 publications

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“…After that, in [ 8 ] CFD simulation cycles where used to gain understanding on aerodynamics of small scale WIG ships, and flight test performed afterwards to validate those numerical results. In [ 9 ] authors present a thorough study of the aerodynamic behavior of a WIG craft by using CFD simulations, introducing some findings concerning the periodicity of the aerodynamic forces as the craft proceed on a wavy surface; in the same direction, in [ 10 ] authors generalize this study to three qualitative different surface undulation amplitudes to determine how they affect to the aerodynamic behaviour of the craft. Close to these works, in [ 11 ] authors explore the effects of varying the angle of attack when overflying a wavy ground.…”

Section: Previous Workmentioning

confidence: 99%

Nonlinear Control Strategies for an Autonomous Wing-In-Ground-Effect Vehicle

Patria

Rossi

Fernández

et al. 2021

Sensors

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Autonomous vehicles are nowadays one of the most important technologies that will be incorporated to every day life in the next few years. One of the most promising kind of vehicles in terms of efficiency and sustainability are those known as Wing-in-Ground crafts, or WIG crafts, a family of vehicles that seize the proximity of ground to achieve a flight with low drag and high lift. However, this kind of crafts lacks of a sound theory of flight that can lead to robust control solutions that guarantees safe autonomous operation in all the cruising phases.In this paper we address the problem of controlling a WIG craft in different scenarios and using different control strategies in order to compare their performance. The tested scenarios include obstacle avoidance by fly over and recovering from a random disturbance in vehicle attitude. MPC (Model Predictive Control) is tested on the complete nonlinear model, while PID, used as baseline controller, LQR (Linear Quadratic Regulator) and adaptive LQR are tested on top of a partial feedback linearization. Results show that LQR has got the best overall performance, although it is seen that different design specifications could lead to the selection of one controller or another.

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Section: Previous Workmentioning

confidence: 99%

Nonlinear Control Strategies for an Autonomous Wing-In-Ground-Effect Vehicle

Patria

Rossi

Fernández

et al. 2021

Sensors

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“…They observed that at low angles of attacks a steady shock on the lower surface of the airfoil, also at small airfoil distance from the surface, the small angle of attack and high Mach numbers exists a new coupling between the shock buffets on the lower and the upper surface of the airfoil [12]. Other related studies include the studies conducted by Wei He et al [13] studied a numerical-theoretical of the steady massively separated flow around a NACA 4415 airfoil at a low Reynolds number and a high angle of attack near the wavy ground, this research provided new insight into the stability of airfoil-ground flow systems at a low Reynolds number and a high angle of attack [13,14].…”

Section: Introductionmentioning

confidence: 95%

Effect of airfoil distance to water surface on static stall

Azargoon

Djavareshkian

Esmaeilifar

2020

JMES

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In this study, viscous, turbulent, and steady flow around an airfoil near the water surface has been simulated through a numerical method. In this simulation, Navier-Stokes equations have been solved using the finite volume method with a discretized second-order accuracy and PIMPLE algorithm. The Volume of Fraction (VOF) method has been employed to predict the free surface flow. A part of the simulation results has been validated through numerical and experimental data. Besides considering the style of flow separation in the angles of numerous attacks and airfoil static stall near the surface of the water. For this purpose, the airfoil simulation has been processed airfoil in the 68,000 Reynolds number, angle of attack of 2.5 to 11 degree and different distances from the water surface ( h/c = 0.5, 1, ). In a larger angle of attacks, flow is initially separated from the leading edge of the surface, and then it attaches to the surface at a lower point. This reattachment leads to an increase in adverse pressure gradient and the formation of a larger separation in the downstream of the airfoil. The pressure gradient dramatically increases, and the flow gets separated from the upstream of the airfoil. Upon lowering distance from the surface, static stall takes place at a higher point and a lower angle of attack, respectively.

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“…At Re = 800 and 1000 these authors identified two oscillatory unstable modes corresponding to near-wake and far-wake instabilities, alongside a stationary unstable mode, whereas only one unstable mode was found at the lower Re = 400 and 600. Ground-proximity effects on the stability of separated flow over NACA 4415 at low Reynolds numbers were studied using two-dimensional global (BiGlobal) theory with consideration of both flat (He et al 2019c) and wavy ground surfaces (He et al 2019b). Finally, Rossi et al (2018) considered incompressible flow over a NACA 0010 airfoil and a narrow ellipse of the same thickness at a large α of 30 • (100 ≤ Re ≤ 3000) documenting multiple bifurcations.…”

Section: Introductionmentioning

confidence: 99%

Linear modal instabilities around post-stall swept finite wings at low Reynolds numbers

Burtsev

Zhang

et al. 2022

J. Fluid Mech.

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Linear modal instabilities of flow over untapered wings with aspect ratios $AR=4$ and 8, based on the NACA 0015 profile, have been investigated numerically over a range of angles of attack, $\alpha$ , and angles of sweep, $\varLambda$ , at chord Reynolds numbers $100\le Re\le 400$ . Laminar base flows have been generated using direct numerical simulation and selective frequency damping, as appropriate. Several families of unstable three-dimensional linear global (TriGlobal) eigenmodes have been identified and their dependence on geometric parameters has been examined in detail at $Re=400$ . The leading global mode A is associated with the peak recirculation in the three-dimensional laminar separation bubble formed on the wing and becomes unstable when recirculation reaches $\textit {O}(10\,\%)$ . On unswept wings, this mode peaks in the midspan region of the wake and moves towards the wing tip with increasing $\varLambda$ , following the displacement of peak recirculation; its linear amplification leads to wake unsteadiness. Additional amplified modes exist at nearly the same and higher frequencies compared to mode A. The critical $Re$ has been identified and it is shown that amplification increases with increasing sweep, up to $\varLambda \approx 10^\circ$ . At higher $\varLambda$ , all global modes become less amplified and are ultimately stable at $\varLambda =30^\circ$ . An increase in amplification of the leading mode with sweep was not observed over the $AR=4$ wing, where tip vortex effects were shown to dominate.

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Stability of Low-Reynolds-Number Separated Flow Around an Airfoil Near a Wavy Ground

Cited by 21 publications

References 40 publications

Nonlinear Control Strategies for an Autonomous Wing-In-Ground-Effect Vehicle

Nonlinear Control Strategies for an Autonomous Wing-In-Ground-Effect Vehicle

Effect of airfoil distance to water surface on static stall

Linear modal instabilities around post-stall swept finite wings at low Reynolds numbers

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