A hybrid piezo-dielectric wind energy harvester for high-performance vortex-induced vibration energy harvesting
A hybrid piezo-dielectric wind energy harvester for high-performance vortex-induced vibration energy harvesting
This paper proposes a novel hybrid piezo-dielectric (PD) wind energy harvester, to efficiently harvest the vortex-induced vibration (VIV) energy from low-speed wind. The hybrid PD harvester brings together the following two electromechanical transduction mechanisms: piezoelectric ceramic (PZT) sheets and a vibro-impact (VI) dielectric elastomer generator (DEG). The PZT sheets directly transduce the beam’s vibration into electricity, whereas the VI DEG transduces the impacts between the inner ball and the dielectric elastomer membranes resulting from the bluff body’s vibration into electricity. The theoretical model of the hybrid PD harvester subjected to VIV is formulated. Wind tunnel experiments are performed to validate the aerodynamic part of the theoretical model and identify the aerodynamic coefficients. Afterward, based on the theoretical model, the numerical investigation of the hybrid PD harvester is conducted, which uncovers the insights of the conjunction of the PZT and VI DEG for VIV energy harvesting enhancement. It is seen that in the lock-in region of the VIV, where both the PZT and VI DEG can effectively harvest the VIV energy, the VI DEG can generate much higher power. This demonstrates the superiority of the hybrid PD harvester. Parametrical studies show that the smaller mass, higher stiffness and larger diameter of the bluff body are beneficial designs, which broadens the working wind range and enhances the generate power.
Vortex-induced vibration, Energy harvesting, Piezoelectric, Dielectric elastomer generator, Vibro-impact
Lai, Zhihui
c7420c67-2b8f-4cb1-800a-7e02501111c1
Wang, Shuaibo
30c1fb67-3261-4fe1-b4ca-5e34ca722e39
Zhu, Likuan
b1f29f36-b1d3-4f51-824f-1964b359486e
Zhang, Guoqing
8658299d-6bf7-40d5-af00-a0b75dbeac68
Wang, Junlei
7afcea11-129b-4a82-b572-95b443c2c643
Yang, Kai
69334916-7444-46dd-b919-4aa56658f34e
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Lai, Zhihui
c7420c67-2b8f-4cb1-800a-7e02501111c1
Wang, Shuaibo
30c1fb67-3261-4fe1-b4ca-5e34ca722e39
Zhu, Likuan
b1f29f36-b1d3-4f51-824f-1964b359486e
Zhang, Guoqing
8658299d-6bf7-40d5-af00-a0b75dbeac68
Wang, Junlei
7afcea11-129b-4a82-b572-95b443c2c643
Yang, Kai
69334916-7444-46dd-b919-4aa56658f34e
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Lai, Zhihui, Wang, Shuaibo, Zhu, Likuan, Zhang, Guoqing, Wang, Junlei, Yang, Kai and Yurchenko, Daniil
(2020)
A hybrid piezo-dielectric wind energy harvester for high-performance vortex-induced vibration energy harvesting.
Mechanical Systems and Signal Processing, 150, [107212].
(doi:10.1016/j.ymssp.2020.107212).
Abstract
This paper proposes a novel hybrid piezo-dielectric (PD) wind energy harvester, to efficiently harvest the vortex-induced vibration (VIV) energy from low-speed wind. The hybrid PD harvester brings together the following two electromechanical transduction mechanisms: piezoelectric ceramic (PZT) sheets and a vibro-impact (VI) dielectric elastomer generator (DEG). The PZT sheets directly transduce the beam’s vibration into electricity, whereas the VI DEG transduces the impacts between the inner ball and the dielectric elastomer membranes resulting from the bluff body’s vibration into electricity. The theoretical model of the hybrid PD harvester subjected to VIV is formulated. Wind tunnel experiments are performed to validate the aerodynamic part of the theoretical model and identify the aerodynamic coefficients. Afterward, based on the theoretical model, the numerical investigation of the hybrid PD harvester is conducted, which uncovers the insights of the conjunction of the PZT and VI DEG for VIV energy harvesting enhancement. It is seen that in the lock-in region of the VIV, where both the PZT and VI DEG can effectively harvest the VIV energy, the VI DEG can generate much higher power. This demonstrates the superiority of the hybrid PD harvester. Parametrical studies show that the smaller mass, higher stiffness and larger diameter of the bluff body are beneficial designs, which broadens the working wind range and enhances the generate power.
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Accepted/In Press date: 10 August 2020
e-pub ahead of print date: 17 September 2020
Keywords:
Vortex-induced vibration, Energy harvesting, Piezoelectric, Dielectric elastomer generator, Vibro-impact
Identifiers
Local EPrints ID: 468150
URI: http://eprints.soton.ac.uk/id/eprint/468150
ISSN: 0888-3270
PURE UUID: 580f9f70-6193-43e3-bb62-45deac696334
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Date deposited: 04 Aug 2022 16:31
Last modified: 17 Mar 2024 04:11
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Contributors
Author:
Zhihui Lai
Author:
Shuaibo Wang
Author:
Likuan Zhu
Author:
Guoqing Zhang
Author:
Junlei Wang
Author:
Kai Yang
Author:
Daniil Yurchenko
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