Novel two-stage piezoelectric-based ocean wave energy harvesters for moored or unmoored buoys

Murray, R.; Rastegar, J.

doi:10.1117/12.815852

Cited by 55 publications

(39 citation statements)

References 8 publications

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“…Thus, to have a meaningful and useful energy conversion system, this challenge has to be overcome in the design. Murray and Rastegar (2009) developed a design with the goal of overcoming this challenge. The authors proposed a two-stage energy harvesting process, introduced by Rastegar et al (2006), for a heaving buoy.…”

Section: Heaving and Pitching Bodiesmentioning

confidence: 99%

Piezoelectric devices for ocean energy: a brief survey

Jbaily

Yeung

2014

J. Ocean Eng. Mar. Energy

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Piezoelectric materials directly convert strain energy into electric energy and vice versa and are commonly used in sensing and actuating applications. They have been employed in mediums frequently undergoing vibrations, allowing harnessing of power at a small scale. Ideas of using the piezoelectric effect as a power take-off mechanism for ocean energy emerged in the 1970s and are still at a developing stage. This article overviews recent development on the application of the piezoelectric processes to the ocean field and provides a building block for future research work of ocean engineers who are interested in such possibilities. A brief discussion on the selection of the piezoelectric materials for different ocean-engineering applications is presented. Significant research projects on ocean-energy extraction through the use of these materials are then described and discussed with special scrutiny on the viability of proposed designs and their experimental or numerical validation. Various harvesting techniques in an ocean environment are categorized and compared. The challenges ahead and the outlook for success in this area are outlined.

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Section: Heaving and Pitching Bodiesmentioning

confidence: 99%

Piezoelectric devices for ocean energy: a brief survey

Jbaily

Yeung

2014

J. Ocean Eng. Mar. Energy

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“…Different from a strip that primarily deforms along its axis, an annular geometry deforms in two-dimensions, thus offering a further degree of freedom for design of energy harvesting devices [23,25,45]. The possibility of harvesting energy from the base excitation of annular IPMCs may aid in the design of miniature selfpowered devices for installation in instrumented buoys that could extract energy from the up-and-down movements of the ocean [46,51].…”

Section: Introductionmentioning

confidence: 99%

Energy harvesting from underwater vibration of an annular ionic polymer metal composite

2015

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In this paper, we study underwater energy harvesting from bending vibrations of an annular ionic polymer metal composite (IPMC). The IPMC is clamped to a moving base, which harmonically excites the IPMC to vibrate along its fundamental axisymmetric mode shape. We model the IPMC as a thin plate, and the interaction with the surrounding fluid is described through a distributed hydrodynamic loading which is responsible for a marked reduction of the resonance spectrum through added mass effect. IPMC sensing is described though a lumped circuit model, comprising a resistor, a capacitor, a Warburg impedance, and a voltage source controlled by the mechanical curvature. In a series of experiments, the IPMC electrodes are shunted with a resistor, which is parametrically varied together with the excitation frequency to elucidate power harvesting. We also assess the effect of the IPMC geometry on power harvesting, by systematically varying the inner radius of the annulus to encompass five different configurations. Experimental results suggest that IPMC geometry has a primary role on its vibrations, whereby increasing the inner radius results into a significant increase of the resonance frequency. Such an increase does, in turn, produce a robust improvement in power harvesting that increases of two orders of magnitude as the ratio between the inner and the outer radius varies from 0.23 to 0.5.

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“…A similar concept has been pursued by Tieck et al (2006), consisting of a rack placed transversely near the tip of the beam that would periodically pluck the beam as it vibrated. Other concepts utilizing mechanical rectification have been proposed for harvesting energy from buoy motion (Murray and Rastegar, 2009) and low-frequency, rotating machinery (Rastegar and Murray, 2008).…”

Section: Introductionmentioning

confidence: 99%

Analysis of Energy Harvesting Using Frequency Up-Conversion by Analytic Approximations

Wickenheiser¹

2012

Small-Scale Energy Harvesting

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Novel two-stage piezoelectric-based ocean wave energy harvesters for moored or unmoored buoys

Cited by 55 publications

References 8 publications

Piezoelectric devices for ocean energy: a brief survey

Piezoelectric devices for ocean energy: a brief survey

Energy harvesting from underwater vibration of an annular ionic polymer metal composite

Analysis of Energy Harvesting Using Frequency Up-Conversion by Analytic Approximations

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