Tunable, multi-modal, and multi-directional vibration energy harvester based on three-dimensional architected metastructures
Tunable, multi-modal, and multi-directional vibration energy harvester based on three-dimensional architected metastructures
Conventional vibration energy harvesters based on two-dimensional planar layouts have limited harvesting capacities due to narrow frequency bandwidth and because their vibratory motion is mainly restricted to one plane. Three-dimensional architected structures and advanced materials with multifunctional properties are being developed in a broad range of technological fields. Structural topologies exploiting compressive buckling deformation mechanisms however provide a versatile route to transform planar structures into sophisticated three-dimensional architectures and functional devices. Designed geometries and Kirigami cut patterns defined on planar precursors contribute to the controlled formation of diverse three-dimensional forms. In this work, we propose an energy harvesting system with tunable dynamic properties, where piezoelectric materials are integrated and strategically designed into three-dimensional compliant architected metastructures. This concept enables energy scavenging from vibrations not only in multiple directions but also across a broad frequency bandwidth, thus increasing the energy harvesting efficiency. The proposed system comprises a buckled ribbon with optional Kirigami cuts. This platform enables the induction of vibration modes across a wide range of resonance frequencies and in arbitrary directions, mechanically coupling with four cantilever piezoelectric beams to capture vibrations. The multi-modal and multi-directional harvesting performance of the proposed configurations has been demonstrated in comparison with planar systems. The results suggest this is a facile strategy for the realization of compliant and high-performance energy harvesting and advanced electronics systems based on mechanically assembled platforms.
Energy harvesting, Kirigami, Multi-directional, Multi-modal, Vibration
Sun, Rujie
e3dad16d-6c79-4972-8378-edca28a3babd
Li, Qinyu
f5c152e9-2773-4d5c-aabf-a21b09cee293
Yao, Jianfei
69f8d999-5320-4904-84be-9e2479dde9bc
Scarpa, Fabrizio
684472c3-1a28-478a-a388-5fd896986c1d
Rossiter, Jonathan
64caa0df-19e0-40c8-ab69-7021de665c39
25 February 2020
Sun, Rujie
e3dad16d-6c79-4972-8378-edca28a3babd
Li, Qinyu
f5c152e9-2773-4d5c-aabf-a21b09cee293
Yao, Jianfei
69f8d999-5320-4904-84be-9e2479dde9bc
Scarpa, Fabrizio
684472c3-1a28-478a-a388-5fd896986c1d
Rossiter, Jonathan
64caa0df-19e0-40c8-ab69-7021de665c39
Sun, Rujie, Li, Qinyu, Yao, Jianfei, Scarpa, Fabrizio and Rossiter, Jonathan
(2020)
Tunable, multi-modal, and multi-directional vibration energy harvester based on three-dimensional architected metastructures.
Applied Energy, 264, [114615].
(doi:10.1016/j.apenergy.2020.114615).
Abstract
Conventional vibration energy harvesters based on two-dimensional planar layouts have limited harvesting capacities due to narrow frequency bandwidth and because their vibratory motion is mainly restricted to one plane. Three-dimensional architected structures and advanced materials with multifunctional properties are being developed in a broad range of technological fields. Structural topologies exploiting compressive buckling deformation mechanisms however provide a versatile route to transform planar structures into sophisticated three-dimensional architectures and functional devices. Designed geometries and Kirigami cut patterns defined on planar precursors contribute to the controlled formation of diverse three-dimensional forms. In this work, we propose an energy harvesting system with tunable dynamic properties, where piezoelectric materials are integrated and strategically designed into three-dimensional compliant architected metastructures. This concept enables energy scavenging from vibrations not only in multiple directions but also across a broad frequency bandwidth, thus increasing the energy harvesting efficiency. The proposed system comprises a buckled ribbon with optional Kirigami cuts. This platform enables the induction of vibration modes across a wide range of resonance frequencies and in arbitrary directions, mechanically coupling with four cantilever piezoelectric beams to capture vibrations. The multi-modal and multi-directional harvesting performance of the proposed configurations has been demonstrated in comparison with planar systems. The results suggest this is a facile strategy for the realization of compliant and high-performance energy harvesting and advanced electronics systems based on mechanically assembled platforms.
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More information
Accepted/In Press date: 4 February 2010
e-pub ahead of print date: 25 February 2020
Published date: 25 February 2020
Keywords:
Energy harvesting, Kirigami, Multi-directional, Multi-modal, Vibration
Identifiers
Local EPrints ID: 486772
URI: http://eprints.soton.ac.uk/id/eprint/486772
ISSN: 0306-2619
PURE UUID: 966b7dc2-5be7-4fc5-88bc-a730689cd349
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Date deposited: 06 Feb 2024 17:33
Last modified: 17 Mar 2024 07:24
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Contributors
Author:
Rujie Sun
Author:
Qinyu Li
Author:
Jianfei Yao
Author:
Fabrizio Scarpa
Author:
Jonathan Rossiter
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