Experimental investigations of a new concept of wave energy converter hybridizing piezoelectric and dielectric elastomer generators

Boccalero, Gregorio; Chesné, Simon; Mignot, Emmanuel; Rivière, Nicolas; Jean‐Mistral, Claire

doi:10.1088/1361-665x/ac36af

Cited by 6 publications

(1 citation statement)

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“…This method typically harvests wave energy through the relative displacement of the upper and lower floating bodies, so confinement is more difficult to guarantee, and the connection among components is complex and the energy loss is larger. So, recent studies have mainly focused on parameter optimizations and energy efficiency of non-contact pWEC [35][36][37][38][39][40][41].…”

Section: Introductionmentioning

confidence: 99%

A Contactless Coupled Pendulum and Piezoelectric Wave Energy Harvester: Model and Experiment

Feng,

Chen,

Zou

et al. 2024

Energies

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Wireless monitoring systems for the marine environment are important for rapidly growing subsea developments. The power supply of wireless sensor nodes within the monitoring systems, however, is a major challenge. This study proposes a novel piezoelectric wave energy converter (pWEC) device to power the wireless sensing nodes. Unlike previous studies, the proposed device utilizes contactless pWEC technology in which a spring pendulum provides a two-stage frequency amplification of 3.8 times for low-frequency wave environments. The pWEC device consists of a floating body, inner pendulum, spring pendulum, magnets and piezoelectric sheets. In order to harvest the energy from relatively low frequency ocean waves, the pWEC device is designed to have an enhanced energy-capturing frequency. The effects of internal pendulum mass, spring pendulum weight, pendulum length and spring stiffness on wave energy absorption are investigated using theoretical and numerical analysis combined with laboratory experiments. The slider that drives the motion of the piezoelectric sheet vibrates at up to 3.8 times the wave frequency. To test the piezoelectric generators in the laboratory environment, a mechanical structure is set up to simulate the motion of the external floating body and the internal wave energy converter under the action of waves. When the four piezoelectric plates are arranged horizontally, the average output power per plate is increased by 2.4 times, and a single piezoelectric plate can generate an average of 10 mW of power. The proposed piezoelectric wave energy converter device has the potential to provide long-term energy supply for small ocean monitoring platforms at remote locations with reasonable wave energy resources.

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Section: Introductionmentioning

confidence: 99%

A Contactless Coupled Pendulum and Piezoelectric Wave Energy Harvester: Model and Experiment

Feng,

Chen,

Zou

et al. 2024

Energies

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Dielectric Elastomer Generators: Recent Advances in Materials, Electronic Circuits, and Prototype Developments

Gurjar,

Sadangi,

Kumar

et al. 2024

Adv Energy and Sustain Res

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The ongoing climate crisis requires innovative methods to maximize renewable and sustainable energy resources. There have been advancements in harvesting energy from ambient motions such as wind, ocean waves, and human movements. Dielectric elastomer generators (DEGs) are a promising option for energy harvesting due to their high energy density and compatibility with low‐frequency oscillations. This review provides an in‐depth overview of DEGs, including electroactive materials, electromechanical characterization, electronics for harvesting, interfacing circuits, prototypes, and challenges. DEGs have the potential to play a significant role in decarbonizing energy for both small‐ and large‐scale applications using ambient energy sources.

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Ultra-low frequency vibration energy harvesting: Mechanisms, enhancement techniques, and scaling laws

Sun

Zhou

2023

Energy Conversion and Management

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Experimental investigations of a new concept of wave energy converter hybridizing piezoelectric and dielectric elastomer generators

Cited by 6 publications

References 50 publications

A Contactless Coupled Pendulum and Piezoelectric Wave Energy Harvester: Model and Experiment

A Contactless Coupled Pendulum and Piezoelectric Wave Energy Harvester: Model and Experiment

Dielectric Elastomer Generators: Recent Advances in Materials, Electronic Circuits, and Prototype Developments

Ultra-low frequency vibration energy harvesting: Mechanisms, enhancement techniques, and scaling laws

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