Rapid flapping and fiber-reinforced membrane wings are key to high-performance bat flight
Rapid flapping and fiber-reinforced membrane wings are key to high-performance bat flight
Bats fly using significantly different wing motions than other fliers, stemming from the complex interplay of their membrane wings’ motion and structural properties. Biological studies show that many bats fly at Strouhal numbers, the ratio of flapping to flight speed, 50-150% above the range typically associated with optimal locomotion. We use high-resolution fluid-structure interaction simulations of a bat wing to independently study the role of kinematics and material/structural properties on aerodynamic performance and show that peak propulsive and lift efficiencies for a bat-like wing motion require flapping 66% faster than for a symmetric motion, agreeing with the increased flapping frequency observed in zoological studies. In addition, we find that reduced membrane stiffness is associated with improved propulsive efficiency until the membrane flutters, but that incorporating microstructural anisotropy arising from biological fiber reinforcement enables a tenfold reduction of the flutter energy whilst maintaining high aerodynamic efficiency. Our results indicate that animals with specialized flapping motions may have correspondingly specialized flapping speeds, in contrast to arguments for a universally efficient Strouhal range. Additionally, our study demonstrates the significant role that the microstructural constitutive properties of the membrane wing of a bat can have on its propulsive performance.
bat flight, simulations, fluid-structure, membrane, fibers
Lauber, Marin
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Weymouth, Gabriel D.
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Limbert, Georges
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Lauber, Marin
c8fa4bb5-81ad-4ccc-b24d-17dcc2d229af
Weymouth, Gabriel D.
f2976de1-6e6f-4e99-b837-87ae33659dc8
Limbert, Georges
a1b88cb4-c5d9-4c6e-b6c9-7f4c4aa1c2ec
Lauber, Marin, Weymouth, Gabriel D. and Limbert, Georges
(2023)
Rapid flapping and fiber-reinforced membrane wings are key to high-performance bat flight.
Journal of the Royal Society Interface.
(In Press)
Abstract
Bats fly using significantly different wing motions than other fliers, stemming from the complex interplay of their membrane wings’ motion and structural properties. Biological studies show that many bats fly at Strouhal numbers, the ratio of flapping to flight speed, 50-150% above the range typically associated with optimal locomotion. We use high-resolution fluid-structure interaction simulations of a bat wing to independently study the role of kinematics and material/structural properties on aerodynamic performance and show that peak propulsive and lift efficiencies for a bat-like wing motion require flapping 66% faster than for a symmetric motion, agreeing with the increased flapping frequency observed in zoological studies. In addition, we find that reduced membrane stiffness is associated with improved propulsive efficiency until the membrane flutters, but that incorporating microstructural anisotropy arising from biological fiber reinforcement enables a tenfold reduction of the flutter energy whilst maintaining high aerodynamic efficiency. Our results indicate that animals with specialized flapping motions may have correspondingly specialized flapping speeds, in contrast to arguments for a universally efficient Strouhal range. Additionally, our study demonstrates the significant role that the microstructural constitutive properties of the membrane wing of a bat can have on its propulsive performance.
Text
JRSI_Lauber_2023
- Accepted Manuscript
More information
Accepted/In Press date: 19 October 2023
Keywords:
bat flight, simulations, fluid-structure, membrane, fibers
Identifiers
Local EPrints ID: 483886
URI: http://eprints.soton.ac.uk/id/eprint/483886
ISSN: 1742-5689
PURE UUID: 678128ae-e320-41aa-9aeb-803aa0015be8
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Date deposited: 07 Nov 2023 18:05
Last modified: 17 Mar 2024 05:22
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Contributors
Author:
Marin Lauber
Author:
Gabriel D. Weymouth
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