Sunlight-Driven Continuous Flapping-Wing Motion

Flapping-wing flight is a challenging system integration problem for designers due to tight coupling between propulsion and flexible wing subsystems with variable kinematics. High fidelity models that capture all the subsystem interactions are computationally expensive and too complex for design space exploration and optimization studies. A combination of simplified modeling and validation with experimental data offers a more tractable approach to system design and integration, which maintains acceptable accuracy. However, experimental data on flapping-wing aerial vehicles which are collected in a static laboratory test or a wind tunnel test are limited because of the rigid mounting of the vehicle, which alters the natural body response to flapping forces generated. In this study, a flapping-wing aerial vehicle is instrumented to provide in-flight data collection that is unhindered by rigid mounting strategies. The sensor suite includes measurements of attitude, heading, altitude, airspeed, position, wing angle, and voltage and current supplied to the drive motors. This in-flight data are used to setup a modified strip theory aerodynamic model with physically realistic flight conditions. A coupled model that predicts wing motions is then constructed by combining the aerodynamic model with a model of flexible wing twist dynamics and enforcing motor torque and speed bandwidth constraints. Finally, the results of experimental testing are compared to the coupled modeling framework to establish the effectiveness of the proposed approach for improving predictive accuracy by reducing errors in wing motion specification.

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Numerical Simulation Method for 3D Low Speed Micro Flapping-Wing with Complex Kinematics

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.308-310.332 ◽

2011 ◽

Vol 308-310 ◽

pp. 332-335

Author(s):

Wen Qing Yang ◽

Bi Feng Song ◽

Wen Ping Song ◽

Zhan Ke Li ◽

Ya Feng Zhang

Keyword(s):

Numerical Simulation ◽

Numerical Method ◽

Stokes Equations ◽

Simulation Method ◽

Flapping Wing ◽

Design Tool ◽

Navier Stokes ◽

Low Speed ◽

Wing Motion ◽

Numerical Simulation Method

A numerical simulation method is presented in this paper for 3D low speed micro flapping-wing with complex kinematics. The main characteristics for the numerical simulation of Flapping-wing Micro Air Vehicle (FMAV) include: low speed, big range of wing motion, and complex kinematics. The low speed problem is solved by preconditioning method. The big range of wing motion problem is solved by chimera grid system. The problem of complex kinematics is solved by decomposed into three main motions, i.e. plunging, pitching, and swing respectively. The numerical method is solving the Reynolds Averaged Navier-Stokes equations for the viscous flow over micro flapping-wing. The numerical method of this paper is validated by good accordance with experimental results of reference. This method can used to simulate the aerodynamic performance of micro flapping-wing with complex kinematics in low speed and is helpful to the FMAV designers as a design tool.

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Design of “Figure-8” Spherical Motion Flapping Wing for Miniature UAV

Volume 3: ASME/IEEE 2009 International Conference on Mechatronic and Embedded Systems and Applications; 20th Reliability, Stress Analysis, and Failure Prevention Conference ◽

10.1115/detc2009-86151 ◽

2009 ◽

Cited By ~ 1

Author(s):

Zohaib Rehmat ◽

Jesse Roll ◽

Joon S. Lee ◽

Woosoon Yim ◽

Mohamed B. Trabia

Keyword(s):

Experimental Testing ◽

Flapping Wing ◽

Servo Motor ◽

Flapping Motion ◽

Experimental Prototype ◽

Wing Motion ◽

Air Vehicle ◽

Spherical Motion

Hummingbirds and some insects exhibit a “Figure-8” flapping motion, which allows them to undergo variety of maneuvers including hovering. It is therefore desirable to have miniature air vehicle (FWMAV) with this wing motion. This paper presents a design of a flapping-wing for FWMAV that can mimic “Figure-8” motion using a spherical four bar mechanism. In the proposed design, the wing is attached to a coupler point on the mechanism, which is driven by a DC servo motor. A prototype is fabricated to verify that the design objectives are met. Experimental testing was conducted to determine the validity of the design. The results indicate good correlation between model and experimental prototype.

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A Study on Rotational Effect on Flapping Wing Motion

AIAA Atmospheric Flight Mechanics Conference and Exhibit ◽

10.2514/6.2005-6337 ◽

2005 ◽

Cited By ~ 1

Author(s):

Yoon-Joo Kim ◽

Hang-Cheol Choi ◽

Kwang-Ho Kim

Keyword(s):

Flapping Wing ◽

Wing Motion ◽

Rotational Effect

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Effect of Wing Corrugation on the Aerodynamic Efficiency of Two-Dimensional Flapping Wings

Applied Sciences ◽

10.3390/app10207375 ◽

2020 ◽

Vol 10 (20) ◽

pp. 7375

Author(s):

Thanh Tien Dao ◽

Thi Kim Loan Au ◽

Soo Hyung Park ◽

Hoon Cheol Park

Keyword(s):

Three Dimensional ◽

Leading Edge ◽

Aerodynamic Performance ◽

Flapping Wing ◽

Flapping Wings ◽

Two Dimensional ◽

Aerodynamic Efficiency ◽

Insect Wing ◽

Wing Motion ◽

Computational Fluid Dynamics Cfd

Many previous studies have shown that wing corrugation of an insect wing is only structurally beneficial in enhancing the wing’s bending stiffness and does not much help to improve the aerodynamic performance of flapping wings. This study uses two-dimensional computational fluid dynamics (CFD) in aiming to identify a proper wing corrugation that can enhance the aerodynamic performance of the KUBeetle, an insect-like flapping-wing micro air vehicle (MAV), which operates at a Reynolds number of less than 13,000. For this purpose, various two-dimensional corrugated wings were numerically investigated. The two-dimensional flapping wing motion was extracted from the measured three-dimensional wing kinematics of the KUBeetle at spanwise locations of r = (0.375 and 0.75)R. The CFD analysis showed that at both spanwise locations, the corrugations placed over the entire wing were not beneficial for improving aerodynamic efficiency. However, for the two-dimensional flapping wing at the spanwise location of r = 0.375R, where the wing experiences relatively high angles of attack, three specially designed wings with leading-edge corrugation showed higher aerodynamic performance than that of the non-corrugated smooth wing. The improvement is closely related to the flow patterns formed around the wings. Therefore, the proposed leading-edge corrugation is suggested for the inboard wing of the KUBeetle to enhance aerodynamic performance. The corrugation in the inboard wing may also be structurally beneficial.

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Deterministic Global Optimization of Flapping Wing Motion for Micro Air Vehicles

13th AIAA/ISSMO Multidisciplinary Analysis Optimization Conference ◽

10.2514/6.2010-9355 ◽

2010 ◽

Cited By ~ 5

Author(s):

Mehdi Ghommem ◽

Muhammad Hajj ◽

Layne Watson ◽

Dean Mook ◽

Richard Snyder ◽

...

Keyword(s):

Global Optimization ◽

Micro Air Vehicles ◽

Flapping Wing ◽

Deterministic Global Optimization ◽

Wing Motion ◽

Air Vehicles

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Soap Film Flow Visualization of Flapping Wing Motion

10.1201/9780429280436-8 ◽

2021 ◽

pp. 267-282

Author(s):

Lung-Jieh Yang ◽

Balasubramanian Esakki

Keyword(s):

Flow Visualization ◽

Film Flow ◽

Soap Film ◽

Flapping Wing ◽

Wing Motion

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Quasi-Steady versus Navier–Stokes Solutions of Flapping Wing Aerodynamics

Fluids ◽

10.3390/fluids3040081 ◽

2018 ◽

Vol 3 (4) ◽

pp. 81 ◽

Cited By ~ 8

Author(s):

Jeremy Pohly ◽

James Salmon ◽

James Bluman ◽

Kabilan Nedunchezian ◽

Chang-kwon Kang

Keyword(s):

Stokes Equations ◽

Aerodynamic Force ◽

Lift Coefficient ◽

Three Dimensional ◽

Fruit Fly ◽

Flapping Wing ◽

Navier Stokes ◽

Pitching Motion ◽

Navier Stokes Equations ◽

Wing Motion

Various tools have been developed to model the aerodynamics of flapping wings. In particular, quasi-steady models, which are considerably faster and easier to solve than the Navier–Stokes equations, are often utilized in the study of flight dynamics of flapping wing flyers. However, the accuracy of the quasi-steady models has not been properly documented. The objective of this study is to assess the accuracy of a quasi-steady model by comparing the resulting aerodynamic forces against three-dimensional (3D) Navier–Stokes solutions. The same wing motion is prescribed at a fruit fly scale. The pitching amplitude, axis, and duration are varied. Comparison of the aerodynamic force coefficients suggests that the quasi-steady model shows significant discrepancies under extreme pitching motions, i.e., the pitching motion is large, quick, and occurs about the leading or trailing edge. The differences are as large as 1.7 in the cycle-averaged lift coefficient. The quasi-steady model performs well when the kinematics are mild, i.e., the pitching motion is small, long, and occurs near the mid-chord with a small difference in the lift coefficient of 0.01. Our analysis suggests that the main source for the error is the inaccuracy of the rotational lift term and the inability to model the wing-wake interaction in the quasi-steady model.

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