Dielectric elastomer wave energy harvester with self-bias voltage of an ancillary wind generator to power for intelligent buoys

AbstractIncreasing demand for self-powered wearable sensors has spurred an urgent need to develop energy harvesting systems that can reliably and sufficiently power these devices. Within the last decade, reverse electrowetting-on-dielectric (REWOD)-based mechanical motion energy harvesting has been developed, where an electrolyte is modulated (repeatedly squeezed) between two dissimilar electrodes under an externally applied mechanical force to generate an AC current. In this work, we explored various combinations of electrolyte concentrations, dielectrics, and dielectric thicknesses to generate maximum output power employing REWOD energy harvester. With the objective of implementing a fully self-powered wearable sensor, a “zero applied-bias-voltage” approach was adopted. Three different concentrations of sodium chloride aqueous solutions (NaCl-0.1 M, NaCl-0.5 M, and NaCl-1.0 M) were used as electrolytes. Likewise, electrodes were fabricated with three different dielectric thicknesses (100 nm, 150 nm, and 200 nm) of Al2O3 and SiO2 with an additional layer of CYTOP for surface hydrophobicity. The REWOD energy harvester and its electrode–electrolyte layers were modeled using lumped components that include a resistor, a capacitor, and a current source representing the harvester. Without using any external bias voltage, AC current generation with a power density of 53.3 nW/cm2 was demonstrated at an external excitation frequency of 3 Hz with an optimal external load. The experimental results were analytically verified using the derived theoretical model. Superior performance of the harvester in terms of the figure-of-merit comparing previously reported works is demonstrated. The novelty of this work lies in the combination of an analytical modeling method and experimental validation that together can be used to increase the REWOD harvested power extensively without requiring any external bias voltage.

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A broadbanded pressure differential wave energy converter based on dielectric elastomer generators

Nonlinear Dynamics ◽

10.1007/s11071-021-06721-8 ◽

2021 ◽

Author(s):

Michele Righi ◽

Giacomo Moretti ◽

David Forehand ◽

Lorenzo Agostini ◽

Rocco Vertechy ◽

...

Keyword(s):

Wave Energy ◽

Large Deformations ◽

Dielectric Elastomer ◽

Wave Energy Converter ◽

Pressure Differential ◽

Design Stage ◽

Small Scale ◽

Energy Converter ◽

Wide Range ◽

The Waves

AbstractDielectric elastomer generators (DEGs) are a promising option for the implementation of affordable and reliable sea wave energy converters (WECs), as they show considerable promise in replacing expensive and inefficient power take-off systems with cheap direct-drive generators. This paper introduces a concept of a pressure differential wave energy converter, equipped with a DEG power take-off operating in direct contact with sea water. The device consists of a closed submerged air chamber, with a fluid-directing duct and a deformable DEG power take-off mounted on its top surface. The DEG is cyclically deformed by wave-induced pressure, thus acting both as the power take-off and as a deformable interface with the waves. This layout allows the partial balancing of the stiffness due to the DEG’s elasticity with the negative hydrostatic stiffness contribution associated with the displacement of the water column on top of the DEG. This feature makes it possible to design devices in which the DEG exhibits large deformations over a wide range of excitation frequencies, potentially achieving large power capture in a wide range of sea states. We propose a modelling approach for the system that relies on potential-flow theory and electroelasticity theory. This model makes it possible to predict the system dynamic response in different operational conditions and it is computationally efficient to perform iterative and repeated simulations, which are required at the design stage of a new WEC. We performed tests on a small-scale prototype in a wave tank with the aim of investigating the fluid–structure interaction between the DEG membrane and the waves in dynamical conditions and validating the numerical model. The experimental results proved that the device exhibits large deformations of the DEG power take-off over a broad range of monochromatic and panchromatic sea states. The proposed model demonstrates good agreement with the experimental data, hence proving its suitability and effectiveness as a design and prediction tool.

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Estimation of Ion Impact Energies and Electrode Self-Bias Voltage in Capacitive RF Discharges

MRS Proceedings ◽

10.1557/proc-98-35 ◽

1987 ◽

Vol 98 ◽

Cited By ~ 2

Author(s):

S. E. Savas

Keyword(s):

Bias Voltage ◽

Capacitively Coupled ◽

Ion Flow ◽

Rf Discharges ◽

Self Bias ◽

Ion Energies ◽

Bias Ratio ◽

Ionization Model ◽

Ion Impact ◽

Impact Energies

ABSTRACTThe dependences of the electrode self-bias voltage and the ratio of ion energies on electrode area ratio are calculated for a model of capacitively coupled rf discharges. It is assumed that concentric spherical elecrodes with fluid-like radial ion flow adequately models the ion motion, that sheath impedances are dominant, and that ionization processes in the glow are due to ohmically heated electrons. Results show that the ratio of ion energies impacting the smaller electrode to those on the larger depends on the ratio of electrode areas in a more complex manner than a power law.The reason for this is that sheath impedances are more resistive or capacitive at different times in the rf cycle. The self-bias ratio is found to depend relatively little on the ionization model or the pressure but differs substantially from the “power law” result. The agreement of measurements with the model is fairly good.

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Hardware-in-the-loop simulation of wave energy converters based on dielectric elastomer generators

Meccanica ◽

10.1007/s11012-021-01320-8 ◽

2021 ◽

Vol 56 (5) ◽

pp. 1223-1237

Author(s):

Giacomo Moretti ◽

Andrea Scialò ◽

Giovanni Malara ◽

Giovanni Gerardo Muscolo ◽

Felice Arena ◽

...

Keyword(s):

Wave Energy ◽

Large Scale ◽

Low Cost ◽

Test Site ◽

Dielectric Elastomer ◽

Operating Conditions ◽

Polymer Materials ◽

Hardware In The Loop ◽

Wave Energy Converters ◽

Energy Converters

AbstractDielectric elastomer generators (DEGs) are soft electrostatic generators based on low-cost electroactive polymer materials. These devices have attracted the attention of the marine energy community as a promising solution to implement economically viable wave energy converters (WECs). This paper introduces a hardware-in-the-loop (HIL) simulation framework for a class of WECs that combines the concept of the oscillating water columns (OWCs) with the DEGs. The proposed HIL system replicates in a laboratory environment the realistic operating conditions of an OWC/DEG plant, while drastically reducing the experimental burden compared to wave tank or sea tests. The HIL simulator is driven by a closed-loop real-time hydrodynamic model that is based on a novel coupling criterion which allows rendering a realistic dynamic response for a diversity of scenarios, including large scale DEG plants, whose dimensions and topologies are largely different from those available in the HIL setup. A case study is also introduced, which simulates the application of DEGs on an OWC plant installed in a mild real sea laboratory test-site. Comparisons with available real sea-test data demonstrated the ability of the HIL setup to effectively replicate a realistic operating scenario. The insights gathered on the promising performance of the analysed OWC/DEG systems pave the way to pursue further sea trials in the future.

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Investigation of a Novel Wave Energy Generator Using Dielectric Elastomer

10.1115/1.0001224v ◽

2021 ◽

Author(s):

Changqing Jiang ◽

SEIKI CHIBA ◽

Mikio Waki ◽

Koji Fujita ◽

Bettar El Moctar

Keyword(s):

Wave Energy ◽

Dielectric Elastomer

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Performance Analysis for a Wave Energy Harvester of Piezoelectric Cantilever Beam

Journal of Coastal Research ◽

10.2112/si83-161.1 ◽

2019 ◽

Vol 83 (sp1) ◽

pp. 976

Author(s):

Ming Liu ◽

Hengxu Liu ◽

Hailong Chen ◽

Yuanchao Chai ◽

Liquan Wang

Keyword(s):

Performance Analysis ◽

Cantilever Beam ◽

Wave Energy ◽

Energy Harvester ◽

Piezoelectric Cantilever

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Microstructural dielectric elastomer actuator with uniaxial in-plane contraction

Journal of Intelligent Material Systems and Structures ◽

10.1177/1045389x12451193 ◽

2012 ◽

Vol 24 (3) ◽

pp. 347-356 ◽

Cited By ~ 3

Author(s):

Shih-Chieh Lin ◽

Wen-Pin Shih ◽

Pen-Zen Chang

Keyword(s):

Bias Voltage ◽

Electrostatic Force ◽

Dielectric Elastomer ◽

Dielectric Elastomer Actuator

A micromachined dielectric elastomer actuator with uniaxial in-plane contraction was proposed. The modeling, fabrication, and testing of the actuator were carried out. When a bias voltage was applied, the resulting electrostatic force compressed the dielectric elastomer that then shrank in area due to its embedded microstructures. The proposed dielectric elastomer actuator consisted of two electrode layers, two flexible layers, and a microstructural layer. The microstructural layer possessed the grating patterns that served as the spacers to define the gap between the top and bottom flexible layers. The grating patterns also determined the direction of the in-plane contraction. When the applied electrostatic force pulled together the bottom and top flexible layers, these two layers bent inwardly and shortened the distance between the spacers. The design of the bending actuation was demonstrated utilizing the asymmetric thickness design of the flexible layers.

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