Experimental Studies of an Accelerating, Pitching, Flat-Plate at Low Reynolds Number

Stevens, Prrj; Ford, CW Pitt; Babinsky, Holger

doi:10.2514/6.2013-677

Cited by 11 publications

(5 citation statements)

References 18 publications

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“…The study by [31], where TECS was dynamically actuated from 0 • to 30 • , addressed this particular question and found the transient lift/pitching moment response to be similar, whether the fore element was at an incidence of 0 • or 20 • . Investigations of the effect of actuation rates on the LEV size were also previously carried out by [33][34][35][36][37][38]. In these investigations, it was found that increasing the pitch rate delayed the formation of LEVs on the upper surface and made the LEVs more compact and stronger, thus producing a much larger transient C L .…”

Section: Effect Of Varying Actuation Ratesmentioning

confidence: 98%

Exploring the Impact of Rapidly Actuated Control Surfaces on Drone Aerodynamics

Panta

Marino

Fisher

et al. 2023

Drones

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This study investigates the use of rapidly actuated leading-edge and trailing-edge control surfaces to improve the control authority of small fixed-wing drones. Static and dynamic characteristics were investigated and presented in two separate papers. In this paper, the focus is on the dynamic effects observed from rapidly actuated 30% chord leading- or trailing-edge hinged control surfaces affixed to two flat-plate airfoils. Forces were resolved from surface pressure measurements and are augmented by PIV measurements, smoke flow visualization and analyses. The static study revealed that trailing-edge control surfaces exhibited higher effectiveness in producing time-averaged CL compared to leading-edge control surfaces. However, leading-edge control surfaces exhibit significantly less fluctuation in pressure and lift coefficients at fixed angles of attack and control surface deflections, indicating better stability. Unsteady aerodynamic effects of the airfoil at α=0∘ and “ramp” deflections of trailing- and leading-edge control surfaces from 0∘ to 40∘ with variations in actuation rates showed that CL peaks are approximately three to four times greater than static values for the case of the leading-edge control surface. This has significant implications for fixed-wing drone maneuverability and countering the effects of atmospheric turbulence.

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Section: Effect Of Varying Actuation Ratesmentioning

confidence: 98%

Exploring the Impact of Rapidly Actuated Control Surfaces on Drone Aerodynamics

Panta

Marino

Fisher

et al. 2023

Drones

View full text Add to dashboard Cite

show abstract

“…The system employs a CCD high-speed camera, which has a frame rate capability of more than 5x10 4 Hz, at a resolution of 1024 x 1024 pixels. The frame rate is selected to give a pixel displacement between images of between 2 and 5 pixels.…”

Section: High-speed Piv Systemmentioning

confidence: 99%

“…Stevens et al 4 used a simple kinematic argument to interpret PIV and flow visualisation data. For a wing pitched about the mid-chord, the development of the suction surface flow and the Leading Edge Vortex (LEV) was strongly correlated with the kinematics of the Leading Edge (LE), suggesting that the e↵ective local angle of incidence is of considerable significance in unsteady pitching motions.…”

Section: Introductionmentioning

confidence: 99%

Low Reynolds Number Experimental Studies on Flat Plates

Stevens

Babinsky

2014

52nd Aerospace Sciences Meeting

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This paper analyses experimentally, the influence of the Leading Edge Vortex (LEV) on lift production for a flat plate wing (A = 4) under fast and slow pitch-up motions at Re =10,000 using a combination of dye flow visualisation, PIV and force balance measurements. It is found that a fast pitch over 1c exhibits an attached flow at the end of pitch and this is correlated with higher force coe cients than for the slow pitch case over 6c, where the flow is quasi-steady. The development and convection of the LEV appears to be linear in nature up until the point of LEV eruption.

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“…Study of the vortex dynamics around plates undergoing unsteady motions has been identified as an international research task by the NATO AVT-202 Group and the AIAA Fluid Dynamics Technical Committee's Low Reynolds Number Discussion Group. The identified research task encompasses a wide variety of motions, including pitching 8,9 , rotation 10,11 , various acceleration profiles 12,13 , and the combination thereof 14 .…”

Section: Introductionmentioning

confidence: 99%

Vortex dynamics around pitching plates

et al. 2014

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Vortex dynamics of wakes generated by rectangular aspect-ratio 2 and 4 and twodimensional pitching flat plates in free stream are examined with direct numerical simulation and water tunnel experiments. Evolution of wake vortices comprised of tip, leading-edge and trailing-edge vortices is compared with force history for a range of pitch rates. The plate pivots about its leading edge with reduced frequency from π/8 to π/48, which corresponds to pitching over 1 to 6 chord lengths of travel. Computations have reasonable agreement with experiments, despite large differences in Reynolds number. Computations show that the tip effects are confined initially near the wing tips, but begin to strongly affect the leading-edge vortex as the motion of the plate proceeds, with concomitant effects on lift and drag history. Scaling relations based on reduced frequency are shown to collapse aerodynamic force history for the various pitch rates.

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Experimental Studies of an Accelerating, Pitching, Flat-Plate at Low Reynolds Number

Cited by 11 publications

References 18 publications

Exploring the Impact of Rapidly Actuated Control Surfaces on Drone Aerodynamics

Exploring the Impact of Rapidly Actuated Control Surfaces on Drone Aerodynamics

Low Reynolds Number Experimental Studies on Flat Plates

Vortex dynamics around pitching plates

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