Bimorph piezoelectric vibration energy harvester with flexible 3D meshed-core structure for low frequency vibration

Bimorph piezoelectric vibration energy harvester with flexible 3D meshed-core structure for low frequency vibration

This paper proposes a bimorph piezoelectric vibration energy harvester (PVEH) with a flexible 3D meshed-core elastic layer for improving the output power while lowering the resonance frequency. Owing to the high void ratio of the 3D meshed-core structure, the bending stiffness of the cantilever can...

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Bibliographic Details
Main Authors: Takuya Tsukamoto, Yohei Umino, Sachie Shiomi, Kou Yamada, Takaaki Suzuki
Format: Article
Language:English
Published: Taylor & Francis Group 2018-12-01
Series:Science and Technology of Advanced Materials
Subjects:
Vibration energy harvester
piezoelectric
PVDF
piezoelectric coupling analysis
low frequency
Online Access:http://dx.doi.org/10.1080/14686996.2018.1508985
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spelling doaj-c304742318c643cfb068bba90590f9dd2020-11-24T21:26:03ZengTaylor & Francis GroupScience and Technology of Advanced Materials1468-69961878-55142018-12-0119166066810.1080/14686996.2018.15089851508985Bimorph piezoelectric vibration energy harvester with flexible 3D meshed-core structure for low frequency vibrationTakuya Tsukamoto0Yohei Umino1Sachie Shiomi2Kou Yamada3Takaaki Suzuki4Gunma UniversityGunma UniversityGunma UniversityGunma UniversityGunma UniversityThis paper proposes a bimorph piezoelectric vibration energy harvester (PVEH) with a flexible 3D meshed-core elastic layer for improving the output power while lowering the resonance frequency. Owing to the high void ratio of the 3D meshed-core structure, the bending stiffness of the cantilever can be lowered. Thus, the deflection of the harvester and the strain in the piezoelectric layer increase. According to vibration tests, the resonance frequency is 15.8% lower and the output power is 68% higher than in the conventional solid-core PVEH. Compared to the solid-core PVEH, the proposed meshed-core PVEH (10 mm × 20 mm × 280 μm) has 1.3 times larger tip deflection and the maximum output power is 24.6 μW under resonance condition at 18.7 Hz and 0.2G acceleration. Hence it can be used as a power supply for low-power-consumption sensor nodes in wireless sensor networks.http://dx.doi.org/10.1080/14686996.2018.1508985Vibration energy harvesterpiezoelectricPVDFpiezoelectric coupling analysislow frequency
collection DOAJ
language English
format Article
sources DOAJ
author Takuya Tsukamoto
Yohei Umino
Sachie Shiomi
Kou Yamada
Takaaki Suzuki
spellingShingle Takuya Tsukamoto
Yohei Umino
Sachie Shiomi
Kou Yamada
Takaaki Suzuki
Bimorph piezoelectric vibration energy harvester with flexible 3D meshed-core structure for low frequency vibration
Science and Technology of Advanced Materials
Vibration energy harvester
piezoelectric
PVDF
piezoelectric coupling analysis
low frequency
author_facet Takuya Tsukamoto
Yohei Umino
Sachie Shiomi
Kou Yamada
Takaaki Suzuki
author_sort Takuya Tsukamoto
title Bimorph piezoelectric vibration energy harvester with flexible 3D meshed-core structure for low frequency vibration
title_short Bimorph piezoelectric vibration energy harvester with flexible 3D meshed-core structure for low frequency vibration
title_full Bimorph piezoelectric vibration energy harvester with flexible 3D meshed-core structure for low frequency vibration
title_fullStr Bimorph piezoelectric vibration energy harvester with flexible 3D meshed-core structure for low frequency vibration
title_full_unstemmed Bimorph piezoelectric vibration energy harvester with flexible 3D meshed-core structure for low frequency vibration
title_sort bimorph piezoelectric vibration energy harvester with flexible 3d meshed-core structure for low frequency vibration
publisher Taylor & Francis Group
series Science and Technology of Advanced Materials
issn 1468-6996
1878-5514
publishDate 2018-12-01
description This paper proposes a bimorph piezoelectric vibration energy harvester (PVEH) with a flexible 3D meshed-core elastic layer for improving the output power while lowering the resonance frequency. Owing to the high void ratio of the 3D meshed-core structure, the bending stiffness of the cantilever can be lowered. Thus, the deflection of the harvester and the strain in the piezoelectric layer increase. According to vibration tests, the resonance frequency is 15.8% lower and the output power is 68% higher than in the conventional solid-core PVEH. Compared to the solid-core PVEH, the proposed meshed-core PVEH (10 mm × 20 mm × 280 μm) has 1.3 times larger tip deflection and the maximum output power is 24.6 μW under resonance condition at 18.7 Hz and 0.2G acceleration. Hence it can be used as a power supply for low-power-consumption sensor nodes in wireless sensor networks.
topic Vibration energy harvester
piezoelectric
PVDF
piezoelectric coupling analysis
low frequency
url http://dx.doi.org/10.1080/14686996.2018.1508985
work_keys_str_mv AT takuyatsukamoto bimorphpiezoelectricvibrationenergyharvesterwithflexible3dmeshedcorestructureforlowfrequencyvibration
AT yoheiumino bimorphpiezoelectricvibrationenergyharvesterwithflexible3dmeshedcorestructureforlowfrequencyvibration
AT sachieshiomi bimorphpiezoelectricvibrationenergyharvesterwithflexible3dmeshedcorestructureforlowfrequencyvibration
AT kouyamada bimorphpiezoelectricvibrationenergyharvesterwithflexible3dmeshedcorestructureforlowfrequencyvibration
AT takaakisuzuki bimorphpiezoelectricvibrationenergyharvesterwithflexible3dmeshedcorestructureforlowfrequencyvibration
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