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Vortex-induced piezoelectric cantilever beam vibration for ocean wave energy harvesting via airflow from the orifice of oscillation water column chamber

Vortex-induced piezoelectric cantilever beam vibration for ocean wave energy harvesting via airflow from the orifice of oscillation water column chamber
Vortex-induced piezoelectric cantilever beam vibration for ocean wave energy harvesting via airflow from the orifice of oscillation water column chamber
Micro piezoelectric generators have attracted immense interest to convert mechanical vibrations into electric energy for ultralow power wireless sensors. Herein, an ocean wave vortex-induced vibration piezoelectric energy harvester(Wave-VIVPEH) is proposed to extract wave energy. The renewable and sustainable ocean environment energy harvesting device consists of an oscillating water column(OWC) air chamber, wind tunnel, and piezoelectric energy converter. A fixed bluff body in the vent tunnel induces airflow vortexes and excites the piezoelectric cantilever vibration converting up the ultralow frequency of ocean waves. The novel Wave-VIVPEH is a complex multi-physics system requiring feasible methodologies to enhance its performance. The theoretical models are derived to systematically investigate and optimize the operation. The flume and wind tunnel experiments and the related fluid-solid electric coupling simulations are carried out to verify the concept's feasibility. The aerodynamic kinetic performance in the OWC chamber is characterized by the models. The instantaneous maximum exhalation airspeed reaches 16.55 m/s with the air pressure of 349.97 Pa and the wave period of T=2.5 s. In this wave condition, the results are well agreed with the simulation values of wind speed of 17.96 m/s, and air pressure of 382.55 Pa. The output power characteristics of the piezoelectric energy harvester are analyzed for the distance of the vortex wake between the piezoelectric cantilever beam and the bluff body. With the bluff body diameter of 25 mm and distance of d/dD=4, the theoretical results on the maximum peak voltage and output power are 10.46 V, 3.26mW agree with the simulation optimized values of the maximum peak voltage of 10.85V and the output power of 3.55 mW. When the wind speed is 15 m/s, the theoretical voltage of 8.62 V approaches the experimental result of 8.47 V. Especially, the comparisons of the theoretical power and voltage to experimental and simulational results indicate that the ingenious Wave-VIVPEH has great potential in ocean wave energy harvesting applications to supply power for intelligent buoys.
Piezoelectric energy harvesting(PEH), Ocean wave energy, Oscillating water column (OWC), Vortex-induced vibration(VIV), Bluff body, Intelligent buoy
2211-2855
Du, Xiaozhen
3bf1fccc-9e14-4262-bd1a-baa61ea5c548
Wang, Yu
6d2a1ba4-6455-40a5-a1f9-514aff2274c9
Chen, Haixiang
4c85d979-78a5-42ba-945b-158d0f34eea8
Li, Chicheng
deae9d01-e324-4b27-81ad-425671a15194
Han, Yi
bac5865b-931d-48b3-a407-0f448e1bc90b
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Wang, Junlei
d55dc6d0-734d-46e1-bedd-5ecc18df8702
Yu, Hong
e07ff234-b5fc-4813-9550-e0acc96a646c
Du, Xiaozhen
3bf1fccc-9e14-4262-bd1a-baa61ea5c548
Wang, Yu
6d2a1ba4-6455-40a5-a1f9-514aff2274c9
Chen, Haixiang
4c85d979-78a5-42ba-945b-158d0f34eea8
Li, Chicheng
deae9d01-e324-4b27-81ad-425671a15194
Han, Yi
bac5865b-931d-48b3-a407-0f448e1bc90b
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Wang, Junlei
d55dc6d0-734d-46e1-bedd-5ecc18df8702
Yu, Hong
e07ff234-b5fc-4813-9550-e0acc96a646c

Du, Xiaozhen, Wang, Yu, Chen, Haixiang, Li, Chicheng, Han, Yi, Yurchenko, Daniil, Wang, Junlei and Yu, Hong (2022) Vortex-induced piezoelectric cantilever beam vibration for ocean wave energy harvesting via airflow from the orifice of oscillation water column chamber. Nano Energy, 104, [107870]. (doi:10.1016/j.nanoen.2022.107870).

Record type: Article

Abstract

Micro piezoelectric generators have attracted immense interest to convert mechanical vibrations into electric energy for ultralow power wireless sensors. Herein, an ocean wave vortex-induced vibration piezoelectric energy harvester(Wave-VIVPEH) is proposed to extract wave energy. The renewable and sustainable ocean environment energy harvesting device consists of an oscillating water column(OWC) air chamber, wind tunnel, and piezoelectric energy converter. A fixed bluff body in the vent tunnel induces airflow vortexes and excites the piezoelectric cantilever vibration converting up the ultralow frequency of ocean waves. The novel Wave-VIVPEH is a complex multi-physics system requiring feasible methodologies to enhance its performance. The theoretical models are derived to systematically investigate and optimize the operation. The flume and wind tunnel experiments and the related fluid-solid electric coupling simulations are carried out to verify the concept's feasibility. The aerodynamic kinetic performance in the OWC chamber is characterized by the models. The instantaneous maximum exhalation airspeed reaches 16.55 m/s with the air pressure of 349.97 Pa and the wave period of T=2.5 s. In this wave condition, the results are well agreed with the simulation values of wind speed of 17.96 m/s, and air pressure of 382.55 Pa. The output power characteristics of the piezoelectric energy harvester are analyzed for the distance of the vortex wake between the piezoelectric cantilever beam and the bluff body. With the bluff body diameter of 25 mm and distance of d/dD=4, the theoretical results on the maximum peak voltage and output power are 10.46 V, 3.26mW agree with the simulation optimized values of the maximum peak voltage of 10.85V and the output power of 3.55 mW. When the wind speed is 15 m/s, the theoretical voltage of 8.62 V approaches the experimental result of 8.47 V. Especially, the comparisons of the theoretical power and voltage to experimental and simulational results indicate that the ingenious Wave-VIVPEH has great potential in ocean wave energy harvesting applications to supply power for intelligent buoys.

Text
Vortex-induced piezoelectric cantilever beam vibration for - Accepted Manuscript
Restricted to Repository staff only until 4 October 2024.
Available under License Creative Commons Attribution Non-commercial No Derivatives.
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More information

Accepted/In Press date: 30 September 2022
e-pub ahead of print date: 4 October 2022
Published date: 12 October 2022
Keywords: Piezoelectric energy harvesting(PEH), Ocean wave energy, Oscillating water column (OWC), Vortex-induced vibration(VIV), Bluff body, Intelligent buoy

Identifiers

Local EPrints ID: 475964
URI: http://eprints.soton.ac.uk/id/eprint/475964
DOI: doi:10.1016/j.nanoen.2022.107870
ISSN: 2211-2855
PURE UUID: de64637a-31e8-48d3-b19b-06b6e7c848c9
ORCID for Daniil Yurchenko: ORCID iD orcid.org/0000-0002-4989-3634

Catalogue record

Date deposited: 03 Apr 2023 16:36
Last modified: 17 Mar 2024 04:11

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Contributors

Author: Xiaozhen Du
Author: Yu Wang
Author: Haixiang Chen
Author: Chicheng Li
Author: Yi Han
Author: Daniil Yurchenko ORCID iD
Author: Junlei Wang
Author: Hong Yu

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