Effect of Side-Walls on Flapping-Wing Power-Generation: an Experimental Study

Effect of Side-Walls on Flapping-Wing Power-Generation: an Experimental Study

Effect of constrained flow is investigated experimentally for a flapping foil power-generator. The flow structures around and in the near wake of a flat plate placed between two side walls are captured via PIV technique with simultaneous direct force measurements in uniform flow at Re = 10 000. The...

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Veröffentlicht in:Journal of Applied Fluid Mechanics 2016-01, Vol.9 (6), p.2769-2779
Hauptverfasser: Karakas, Ferhat, Fenercioglu, Idil
Format: Artikel
Sprache:eng
Schlagworte:
Aerodynamics
Amplitudes
Constrained flow
Oscillating foil
Flapping wing
Power generation
PIV
Efficiency
Electric power generation
Flapping
Flapping wings
Flat plates
Fluid dynamics
Fluid flow
Foils
Force measurement
Free flow
Power efficiency
Power generation
Shedding
Uniform flow
Vortices
Walls
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description Effect of constrained flow is investigated experimentally for a flapping foil power-generator. The flow structures around and in the near wake of a flat plate placed between two side walls are captured via PIV technique with simultaneous direct force measurements in uniform flow at Re = 10 000. The rectangular flat plate oscillates with periodic non-sinusoidal pitching and plunging motions about its 0.44 chord position with stroke reversal times (DTR) of 0.1 (rapid reversal) to 0.5 (sinusoidal reversal), phase angles of f = 90[degrees] and 110[degrees], plunge amplitude of 1.05 chords and pitch amplitude of 73[degrees] at a constant reduced frequency of k = 0.8. The non-dimensional distances between the side walls and the oscillating flat plate are dw = 0.1, 0.5 and 1.0. Airfoil rotation speed dictates the strength, evolution and timing of shedding of leading and trailing edge vortices; as the stroke reversal time is decreased, earlier shedding of stronger vortices are observed. Increasing the phase angle between the pitching and plunging motions decreases the power generation efficiency for all cases. The highest power extraction coefficient is acquired for the non-sinusoidal case of DTR = 0.4 in free flow. Optimum choice of side-wall distance improves power generation of flapping foils compared to free flow performance, up to 6.52% increase in efficiency is observed for the non-sinusoidal case DTR = 0.4 with dw = 0.5, with remarkable enhancements for the sinusoidal case; 27.85% increase is observed with dw = 0.5 and 43.50% increase with dw = 1.0 where both cases outperform the highest power generation efficiency of the finite flat plate with non-sinusoidal flapping motion.
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The flow structures around and in the near wake of a flat plate placed between two side walls are captured via PIV technique with simultaneous direct force measurements in uniform flow at Re = 10 000. The rectangular flat plate oscillates with periodic non-sinusoidal pitching and plunging motions about its 0.44 chord position with stroke reversal times (DTR) of 0.1 (rapid reversal) to 0.5 (sinusoidal reversal), phase angles of f = 90[degrees] and 110[degrees], plunge amplitude of 1.05 chords and pitch amplitude of 73[degrees] at a constant reduced frequency of k = 0.8. The non-dimensional distances between the side walls and the oscillating flat plate are dw = 0.1, 0.5 and 1.0. Airfoil rotation speed dictates the strength, evolution and timing of shedding of leading and trailing edge vortices; as the stroke reversal time is decreased, earlier shedding of stronger vortices are observed. Increasing the phase angle between the pitching and plunging motions decreases the power generation efficiency for all cases. The highest power extraction coefficient is acquired for the non-sinusoidal case of DTR = 0.4 in free flow. Optimum choice of side-wall distance improves power generation of flapping foils compared to free flow performance, up to 6.52% increase in efficiency is observed for the non-sinusoidal case DTR = 0.4 with dw = 0.5, with remarkable enhancements for the sinusoidal case; 27.85% increase is observed with dw = 0.5 and 43.50% increase with dw = 1.0 where both cases outperform the highest power generation efficiency of the finite flat plate with non-sinusoidal flapping motion.</description><identifier>ISSN: 1735-3572</identifier><identifier>EISSN: 1735-3645</identifier><identifier>DOI: 10.29252/jafm.09.06.25997</identifier><language>eng</language><publisher>Isfahan: Isfahan University of Technology</publisher><subject>Aerodynamics ; Amplitudes ; Constrained flow; Oscillating foil; Flapping wing; Power generation; PIV ; Efficiency ; Electric power generation ; Flapping ; Flapping wings ; Flat plates ; Fluid dynamics ; Fluid flow ; Foils ; Force measurement ; Free flow ; Power efficiency ; Power generation ; Shedding ; Uniform flow ; Vortices ; Walls</subject><ispartof>Journal of Applied Fluid Mechanics, 2016-01, Vol.9 (6), p.2769-2779</ispartof><rights>2016. 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subjects Aerodynamics
Amplitudes
Constrained flow
Oscillating foil
Flapping wing
Power generation
PIV
Efficiency
Electric power generation
Flapping
Flapping wings
Flat plates
Fluid dynamics
Fluid flow
Foils
Force measurement
Free flow
Power efficiency
Power generation
Shedding
Uniform flow
Vortices
Walls
title Effect of Side-Walls on Flapping-Wing Power-Generation: an Experimental Study
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