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      Unsteady Lift Produced by a Flat-Plate Wing Translating Past Finite Obstacles

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          Abstract

          The unsteady lift of a high-angle-of-attack, flat-plate wing encountering finite-length obstacles is studied using towing-tank force measurements and flow visualization. The wing translates from rest and at 1 chord traveled interacts with a rectangular channel, ceiling, or ground. The angle of attack, obstacle length, and height to the obstacle are varied. As the channel gap height decreases, circulatory-lift peaks attributed to leading-edge vortices (LEVs) become larger, and for the second peak onward occur earlier, from wing blockage enhancing the flow speed. Larger and earlier LEVs are visualized, supporting this, as are secondary vortices off the channel. The lift reduces while exiting a channel, being lowest afterward if exiting during a lift peak. For ceilings, the first circulatory-lift peak increases for smaller LE-to-ceiling gaps, but for 0.5 chord gaps or less, later maxima are below the no-obstacle case yet still earlier. For grounds, with lower wing height the first circulatory-lift peak is larger but the second peak’s behavior varies with angle of attack, and lift decreases near the ground end. Grounds affect peak timing the least, indicating less influence on the LEV. The lift rises slightly ahead of channels and ceilings, and often lowers before channels and grounds end, providing warnings.

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          PIV uncertainty quantification from correlation statistics

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            UNSTEADY AERODYNAMIC PERFORMANCE OF MODEL WINGS AT LOW REYNOLDS NUMBERS

            The synthesis of a comprehensive theory of force production in insect flight is hindered in part by the lack of precise knowledge of unsteady forces produced by wings. Data are especially sparse in the intermediate Reynolds number regime (10<Re<1000) appropriate for the flight of small insects. This paper attempts to fill this deficit by quantifying the time-dependence of aerodynamic forces for a simple yet important motion, rapid acceleration from rest to a constant velocity at a fixed angle of attack. The study couples the measurement of lift and drag on a two-dimensional model with simultaneous flow visualization. The results of these experiments are summarized below. 1. At angles of attack below 13.5°, there was virtually no evidence of a delay in the generation of lift, in contrast to similar studies made at higher Reynolds numbers. 2. At angles of attack above 13.5°, impulsive movement resulted in the production of a leading edge vortex that stayed attached to the wing for the first 2 chord lengths of travel, resulting in an 80 % increase in lift compared to the performance measured 5 chord lengths later. It is argued that this increase is due to the process of detached vortex lift, analogous to the method of force production in delta-wing aircraft. 3. As the initial leading edge vortex is shed from the wing, a second vortex of opposite vorticity develops from the trailing edge of the wing, correlating with a decrease in lift production. This pattern of alternating leading and trailing edge vortices generates a von Karman street, which is stable for at least 7.5 chord lengths of travel. 4. Throughout the first 7.5 chords of travel the model wing exhibits a broad lift plateau at angles of attack up to 54°, which is not significantly altered by the addition of wing camber or surface projections. 5. Taken together, these results indicate how the unsteady process of vortex generation at large angles of attack might contribute to the production of aerodynamic forces in insect flight. Because the fly wing typically moves only 2–4 chord lengths each half-stroke, the complex dynamic behavior of impulsively started wing profiles is more appropriate for models of insect flight than are steady-state approximations.
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              Insect normal hovering flight in ground effect

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                Author and article information

                Contributors
                Journal
                aiaaj
                AIAA Journal
                AIAA Journal
                American Institute of Aeronautics and Astronautics
                1533-385X
                19 March 2024
                June 2024
                : 62
                : 6
                : 2222-2234
                Affiliations
                University at Buffalo, The State University of New York , Buffalo, New York 14260
                Author notes
                [*]

                Former M.S. Student, Department of Mechanical and Aerospace Engineering, 211 Bell Hall.

                [†]

                Associate Professor, Department of Mechanical and Aerospace Engineering, 211 Bell Hall; ringum@ 123456buffalo.edu . Associate Fellow AIAA (Corresponding Author).

                Article
                J063404 J063404
                10.2514/1.J063404
                e36c54d3-6d14-414b-b6d2-26b1c971d050
                Copyright © 2024 by the authors. Published by the American Institute of Aeronautics and Astronautics, Inc., with permission. All requests for copying and permission to reprint should be submitted to CCC at www.copyright.com; employ the eISSN 1533-385X to initiate your request. See also AIAA Rights and Permissions www.aiaa.org/randp.
                History
                : 23 July 2023
                : 12 January 2024
                : 19 January 2024
                Page count
                Figures: 12, Tables: 2
                Funding
                Funded by: Air Force Office of Scientific Researchhttp://dx.doi.org/10.13039/100000181
                Award ID: FA9550-23-1-0170
                Categories
                p2263, Fluid Dynamics
                p1973, Vortex Dynamics
                p20543, Aerodynamic Performance
                p1804, Aerodynamics
                p1975, Boundary Layers
                p16684, Velocimetry
                p2030, Wind Tunnels
                p1976, Flow Regimes
                p2132, Aircraft Operations and Technology
                p2572, Aircraft Wing Design
                Regular Articles

                Engineering,Physics,Mechanical engineering,Space Physics
                Free Streamline,Karman Vortex Street,Aircraft Wing Design,Aerodynamic Performance,Pressure Coefficient,Boundary Layers,Particle Image Velocimetry,Wing Planforms,Wind Tunnels,Incompressible Flow

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