Experimental Study of Owl-Like Airfoil Aerodynamics at Low Reynolds Numbers

Anyoji, Masayuki; Wakui, Shotaro; Hamada, Daiki; Aono, Hikaru

doi:10.4236/jfcmv.2018.63015

Cited by 17 publications

(3 citation statements)

References 16 publications

(16 reference statements)

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“…As for publications considering bio-inspired morphing wings at very low Reynolds numbers [14], they usually refer to micro Unmanned Aerial Vehicles (UAVs) (see Figure 1). Anoyoji et al [15] studied owl-like airfoils for low Reynolds number flights of Micro Air Vehicles (MAVs). The NACA0012 airfoil was compared with a smooth owl-like airfoil for Re = 23,000 − 60,000.…”

Section: Introductionmentioning

confidence: 99%

Aerodynamic Analysis of Variable Camber-Morphing Airfoils with Substantial Camber Deflections

Marciniuk,

Piskur,

Kiszkowiak

et al. 2024

Energies

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In recent years, morphing wings have become not only a concept, but an aerodynamic solution for the aviation industry to take a step forward toward future technologies. However, continuously morphing airfoils became an interesting answer to provide green energy solutions. In this paper, the authors conducted experimental research on a continuously camber-morphing airfoil using the Particle Image Velocimetry (PIV) and Computational Fluid Dynamics (CFD) methods. The main objective of this work was to research a variety of morphing airfoils with different camber deflections. An average velocity distribution and turbulence distribution were compared and are discussed. The two-dimensional PIV results were compared to the CFD simulations to validate the numerical method’s accuracy and obtain the aerodynamic coefficient’s trends. A further comparison revealed that morphing airfoils have better aerodynamic performance than conventional airfoils for very low camber deflections and create substantial amounts of drag for significant camber deflections.

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Section: Introductionmentioning

confidence: 99%

Aerodynamic Analysis of Variable Camber-Morphing Airfoils with Substantial Camber Deflections

Marciniuk,

Piskur,

Kiszkowiak

et al. 2024

Energies

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“…Having studied the low and ultra-low Reynolds number spectrum, researchers tried to visualize the effect that the number had on the turbulence downstream of an airfoil [7,8], or the effect it had on the laminar separation bubble at the leading edge of an airfoil [9]. Others preferred to study the aerodynamics of some birds and insects, such as a dragonfly at Re below 8000 [10], or an owl [11], due to their interest in micro air vehicles with fixed wings. Having studied the behavior of aerodynamic structures (such as airfoils), there was interest in knowing what behavior the flow displays on bluff bodies at low Reynolds numbers [12].…”

Section: Introductionmentioning

confidence: 99%

Flow Study on the Anemometers of the Perseverance Based on Towing Tank Visualization

et al. 2022

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Flow visualization is necessary in fields such as engineering, since it allows us to know what is happening around the element being studied by means of a preliminary method, although it is relatively close to future research and computation methodology. The present project studies the interference at the anemometers of the Mars rover Perseverance, caused by the mast holding one of its cameras. After obtaining the model, manufactured by a 3D printer, it was placed inside a hydrodynamic towing tank, and red dye was added for a visual observation of the interference during the experiment. A comparison was made between the results achieved and those seen in a wind tunnel, realizing the high correlation they have. Finally, this paper promotes the use of the hydrodynamic towing tank in preliminary studies due to its low costs, considering the adequate comparison with other higher precision methodologies.

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“…They concluded that the owl airfoil has a higher lift/drag ratio compared to NACA0002, NACA0012, and the Ishii airfoil. Anyoji et al [19] performed experiments in the wind tunnel with an owl-like airfoil, where they visualized the flow and measured the lift and drag properties. Again, the high cambered airfoil (on the pressure side) showed a better lift/drag ratio compared to NACA0012.…”

Section: Introductionmentioning

confidence: 99%

Aeroacoustic Simulation of an Owl Wing Cross-section Using Computational Fluid Dynamics

YILDIZ¹,

TOKGOZ²

2022

Sakarya University Journal of Science

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In this study, we aim to investigate the low noise flights of owls in terms of aerodynamics. The flow around cross-section of an owl wing, which is known for its nearly silent flight, is numerically analyzed using Computational Fluid Dynamics (CFD). The analysis are based on the parameters of angle of attack and the flight speed. The aerodynamic effects on the acoustic is compared in terms of vorticity and sound pressure level, where the frequency interval for the acoustic data is set to 0-7500Hz. It was seen that the vortical organisations around the airfoils are closely related to the acoustic results. The results show that the increase in both velocity and angle of attack affect the vorticity, thus lead to a rise in sound pressure level. It can be stated that the owl airfoil shape ensures a relatively silent flight.

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Experimental Study of Owl-Like Airfoil Aerodynamics at Low Reynolds Numbers

Cited by 17 publications

References 16 publications

Aerodynamic Analysis of Variable Camber-Morphing Airfoils with Substantial Camber Deflections

Aerodynamic Analysis of Variable Camber-Morphing Airfoils with Substantial Camber Deflections

Flow Study on the Anemometers of the Perseverance Based on Towing Tank Visualization

Aeroacoustic Simulation of an Owl Wing Cross-section Using Computational Fluid Dynamics

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