Tailoring the bending pattern of non-uniformly flexible pitching hydrofoils enhances propulsive efficiency
Tailoring the bending pattern of non-uniformly flexible pitching hydrofoils enhances propulsive efficiency
We present new measurements of non-uniformly flexible pitching foils fabricated with a rigid leading section joined to a flexible trailing section. This construction enables us to vary the bending pattern and resonance condition of the foils independently. A novel effective flexibility, defined as the ratio of added mass forces to elastic forces, is proposed and shown to provide a scaling for the natural frequencies of the fluid-structural system. Foils with very flexible trailing sections of EI < 1.81 × 10−5 N m2 do not show a detectable resonance and are classified as 'non-resonating' as opposed to 'resonating' foils. Moreover, the non-resonating foils exhibit a novel bending pattern where the foil has a discontinuous hinge-like deflection instead of the smooth beam-like deflection of the resonating foils. Performance measurements reveal that both resonating and non-resonating foils can achieve high propulsive efficiencies of around 50% or more. It is discovered that non-uniformly flexible foils outperform their rigid and uniformly flexible counterparts, and that there is an optimal flexion ratio from 0.4 ⩽ λ ⩽ 0.7 that maximizes the efficiency. Furthermore, this optimal range coincides with the flexion ratios observed in nature. Performance is also compared under the same dimensionless flexural rigidity, R*, which highlights that at the same flexion ratio more flexible foils achieve higher peak efficiencies. Overall, to achieve high propulsive efficiency non-uniformly flexible hydrofoils should (1) oscillate above their first natural frequency, (2) have a flexion ratio in the range of 0.4 ⩽ λ ⩽ 0.7 and (3) have a small dimensionless rigidity at their optimal flexion ratio. Scaling laws for rigid pitching foils are found to be valid for non-uniformly flexible foils as long as the measured amplitude response is used and the deflection angle of the trailing section β is < 45°. This work provides guidance for the development of high-performance underwater vehicles using simple purely pitching bio-inspired propulsive drives.
065003
Han, Tianjun
a8def36c-e810-40b6-a2fd-73448f391ef2
Mivehchi, Amin
e3cd21f8-2efd-4b02-9c02-c0fe320e3d24
Kurt, Melike
15dea522-b5e5-4360-8b03-7a68e543c873
Moored, Keith W
9c89d06c-a49a-4ff0-bd32-37d9d143d39a
1 November 2022
Han, Tianjun
a8def36c-e810-40b6-a2fd-73448f391ef2
Mivehchi, Amin
e3cd21f8-2efd-4b02-9c02-c0fe320e3d24
Kurt, Melike
15dea522-b5e5-4360-8b03-7a68e543c873
Moored, Keith W
9c89d06c-a49a-4ff0-bd32-37d9d143d39a
Han, Tianjun, Mivehchi, Amin, Kurt, Melike and Moored, Keith W
(2022)
Tailoring the bending pattern of non-uniformly flexible pitching hydrofoils enhances propulsive efficiency.
Bioinspiration & Biomimetics, 17 (6), .
(doi:10.1088/1748-3190/ac7f70).
Abstract
We present new measurements of non-uniformly flexible pitching foils fabricated with a rigid leading section joined to a flexible trailing section. This construction enables us to vary the bending pattern and resonance condition of the foils independently. A novel effective flexibility, defined as the ratio of added mass forces to elastic forces, is proposed and shown to provide a scaling for the natural frequencies of the fluid-structural system. Foils with very flexible trailing sections of EI < 1.81 × 10−5 N m2 do not show a detectable resonance and are classified as 'non-resonating' as opposed to 'resonating' foils. Moreover, the non-resonating foils exhibit a novel bending pattern where the foil has a discontinuous hinge-like deflection instead of the smooth beam-like deflection of the resonating foils. Performance measurements reveal that both resonating and non-resonating foils can achieve high propulsive efficiencies of around 50% or more. It is discovered that non-uniformly flexible foils outperform their rigid and uniformly flexible counterparts, and that there is an optimal flexion ratio from 0.4 ⩽ λ ⩽ 0.7 that maximizes the efficiency. Furthermore, this optimal range coincides with the flexion ratios observed in nature. Performance is also compared under the same dimensionless flexural rigidity, R*, which highlights that at the same flexion ratio more flexible foils achieve higher peak efficiencies. Overall, to achieve high propulsive efficiency non-uniformly flexible hydrofoils should (1) oscillate above their first natural frequency, (2) have a flexion ratio in the range of 0.4 ⩽ λ ⩽ 0.7 and (3) have a small dimensionless rigidity at their optimal flexion ratio. Scaling laws for rigid pitching foils are found to be valid for non-uniformly flexible foils as long as the measured amplitude response is used and the deflection angle of the trailing section β is < 45°. This work provides guidance for the development of high-performance underwater vehicles using simple purely pitching bio-inspired propulsive drives.
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Accepted/In Press date: 7 July 2022
e-pub ahead of print date: 7 September 2022
Published date: 1 November 2022
Identifiers
Local EPrints ID: 474761
URI: http://eprints.soton.ac.uk/id/eprint/474761
ISSN: 1748-3182
PURE UUID: 357d54f9-77d0-478d-9145-bb6b3ba0fccf
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Date deposited: 02 Mar 2023 17:43
Last modified: 17 Mar 2024 04:05
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Author:
Tianjun Han
Author:
Amin Mivehchi
Author:
Melike Kurt
Author:
Keith W Moored
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