Qualitative changes in bifurcation structure for soft vs hard impact models of a vibro-impact energy harvester
Qualitative changes in bifurcation structure for soft vs hard impact models of a vibro-impact energy harvester
Vibro-impact phenomena in engineering systems, considered an adverse effect in some settings, are an intrinsic part of the mechanism in others. In energy harvesting, a vibro-impact component is often intentionally introduced to increase the power output or the system’s bandwidth. The impacts can be treated as “hard” for instantaneous impacts or “soft” for compliant materials. Since both types of models exhibit complex dynamics, a comparison is non-trivial. We develop a soft impact model for a vibro-impact energy harvester, calibrating it with the relevant hard impact model for large stiffness, and systematically compare the different phenomena and dynamics in various compliant regimes. Numerical results are used in two different parametric analyses, considering the bifurcation diagrams in terms of device size and external forcing parameters. Varying the natural frequency of the membranes that form the impact boundaries, we observe shifts in the bifurcation structure that promote period-1 orbits for increased softness parameters, often generating higher power output, but also introducing parameter sensitivities for increased softness. Complementary analytical results reveal unstable periodic orbits and co-existing behaviors, potentially missed by computational methods, that can influence the bifurcation structure and in turn the energy output. A non-dimensional formulation highlights the significance of ratios of external and natural frequencies in delineating soft and hard impact scenarios parametrically. The soft impact model exhibits new symmetry breaking bifurcations related to key quantities that characterize the soft impact dynamics, such as the effective restitution coefficients, the impact phase, and the contact time interval, not captured by hard impact models.
Costa, Dimitri
62a106ed-d947-4663-a73e-d22af7503cc6
Kuske, Rachel
eb2504e2-25b3-4838-8c59-8fe8eaecf443
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Costa, Dimitri
62a106ed-d947-4663-a73e-d22af7503cc6
Kuske, Rachel
eb2504e2-25b3-4838-8c59-8fe8eaecf443
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Costa, Dimitri, Kuske, Rachel and Yurchenko, Daniil
(2022)
Qualitative changes in bifurcation structure for soft vs hard impact models of a vibro-impact energy harvester.
Chaos, 32 (10), [103120].
(doi:10.1063/5.0101050).
Abstract
Vibro-impact phenomena in engineering systems, considered an adverse effect in some settings, are an intrinsic part of the mechanism in others. In energy harvesting, a vibro-impact component is often intentionally introduced to increase the power output or the system’s bandwidth. The impacts can be treated as “hard” for instantaneous impacts or “soft” for compliant materials. Since both types of models exhibit complex dynamics, a comparison is non-trivial. We develop a soft impact model for a vibro-impact energy harvester, calibrating it with the relevant hard impact model for large stiffness, and systematically compare the different phenomena and dynamics in various compliant regimes. Numerical results are used in two different parametric analyses, considering the bifurcation diagrams in terms of device size and external forcing parameters. Varying the natural frequency of the membranes that form the impact boundaries, we observe shifts in the bifurcation structure that promote period-1 orbits for increased softness parameters, often generating higher power output, but also introducing parameter sensitivities for increased softness. Complementary analytical results reveal unstable periodic orbits and co-existing behaviors, potentially missed by computational methods, that can influence the bifurcation structure and in turn the energy output. A non-dimensional formulation highlights the significance of ratios of external and natural frequencies in delineating soft and hard impact scenarios parametrically. The soft impact model exhibits new symmetry breaking bifurcations related to key quantities that characterize the soft impact dynamics, such as the effective restitution coefficients, the impact phase, and the contact time interval, not captured by hard impact models.
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Accepted/In Press date: 21 September 2022
e-pub ahead of print date: 27 October 2022
Identifiers
Local EPrints ID: 484902
URI: http://eprints.soton.ac.uk/id/eprint/484902
ISSN: 1054-1500
PURE UUID: 07cb5a8f-5393-4ad1-b35f-847e11edb29c
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Date deposited: 24 Nov 2023 17:33
Last modified: 18 Mar 2024 04:04
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Author:
Dimitri Costa
Author:
Rachel Kuske
Author:
Daniil Yurchenko
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