Wave Energy Extraction by Flexible Floaters

Simone Michele; Federica Buriani; Emiliano Renzi; Rooij M van; Bayu Jayawardhana; Antonis I. Vakis

doi:10.3390/en13236167

Wave Energy Extraction by Flexible Floaters

Simone Michele, Federica Buriani, Emiliano Renzi^*, Rooij M van, Bayu Jayawardhana, Antonis I. Vakis

^*Corresponding author for this work

School of Engineering, Computing and Mathematics

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Abstract

We present a novel mathematical model to investigate the extraction of wave power by flexible floaters. The model is based on the method of dry modes, coupled with a matched eigenfunction expansion. Our model results compare satisfactorily with preliminary data obtained from a demonstrator device, developed at the University of Groningen. We show that the role of elasticity is to increase the number of resonant frequencies with respect to a rigid body, which has a positive effect on wave power output. The mathematical model is then extended to irregular incident waves, described by a JONSWAP spectrum. Our results show that the peak capture factors decrease in irregular waves, as compared to the monochromatic case. However, the system becomes more efficient at non-resonant frequencies. This work highlights the need to scale-up experimental investigations on flexible wave energy converters, which are still a small minority, compared to those on rigid converters.

Original language	English
Pages (from-to)	6167-6167
Number of pages	0
Journal	Energies
Volume	13
Issue number	23
Early online date	24 Nov 2020
DOIs	https://doi.org/10.3390/en13236167
Publication status	Published - 24 Nov 2020

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Michele et al 2020Licence: CC BY

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title = "Wave Energy Extraction by Flexible Floaters",

abstract = "We present a novel mathematical model to investigate the extraction of wave power by flexible floaters. The model is based on the method of dry modes, coupled with a matched eigenfunction expansion. Our model results compare satisfactorily with preliminary data obtained from a demonstrator device, developed at the University of Groningen. We show that the role of elasticity is to increase the number of resonant frequencies with respect to a rigid body, which has a positive effect on wave power output. The mathematical model is then extended to irregular incident waves, described by a JONSWAP spectrum. Our results show that the peak capture factors decrease in irregular waves, as compared to the monochromatic case. However, the system becomes more efficient at non-resonant frequencies. This work highlights the need to scale-up experimental investigations on flexible wave energy converters, which are still a small minority, compared to those on rigid converters.",

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doi = "10.3390/en13236167",

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T1 - Wave Energy Extraction by Flexible Floaters

AU - Michele, Simone

AU - Buriani, Federica

AU - Renzi, Emiliano

AU - van, Rooij M

AU - Jayawardhana, Bayu

AU - Vakis, Antonis I.

PY - 2020/11/24

Y1 - 2020/11/24

N2 - We present a novel mathematical model to investigate the extraction of wave power by flexible floaters. The model is based on the method of dry modes, coupled with a matched eigenfunction expansion. Our model results compare satisfactorily with preliminary data obtained from a demonstrator device, developed at the University of Groningen. We show that the role of elasticity is to increase the number of resonant frequencies with respect to a rigid body, which has a positive effect on wave power output. The mathematical model is then extended to irregular incident waves, described by a JONSWAP spectrum. Our results show that the peak capture factors decrease in irregular waves, as compared to the monochromatic case. However, the system becomes more efficient at non-resonant frequencies. This work highlights the need to scale-up experimental investigations on flexible wave energy converters, which are still a small minority, compared to those on rigid converters.

AB - We present a novel mathematical model to investigate the extraction of wave power by flexible floaters. The model is based on the method of dry modes, coupled with a matched eigenfunction expansion. Our model results compare satisfactorily with preliminary data obtained from a demonstrator device, developed at the University of Groningen. We show that the role of elasticity is to increase the number of resonant frequencies with respect to a rigid body, which has a positive effect on wave power output. The mathematical model is then extended to irregular incident waves, described by a JONSWAP spectrum. Our results show that the peak capture factors decrease in irregular waves, as compared to the monochromatic case. However, the system becomes more efficient at non-resonant frequencies. This work highlights the need to scale-up experimental investigations on flexible wave energy converters, which are still a small minority, compared to those on rigid converters.

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DO - 10.3390/en13236167

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JO - Energies

JF - Energies

IS - 23

ER -

Wave Energy Extraction by Flexible Floaters

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