Efficiency analysis of the cycloidal wave energy convertor under real-time dynamic control using a 3D radiation model

Ocean waves provide a vast, uninterrupted resource of renewable energy collocated around large coastal population centers. Clean energy from ocean waves can contribute to the local electrical grid without the need for long-term electrical storage, yet due to the current high cost of energy extractio...
Ausführliche Beschreibung

Gespeichert in:

Autor*in:	Ali Mohtat [verfasserIn] Casey Fagley [verfasserIn] Kedar C. Chitale [verfasserIn] Stefan G. Siegel [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2022

Schlagwörter:	Wave energy conversion, Cycloidal wave energy convertor, Deep-water waves, Wave radiation, irregular waves, short crested waves

Übergeordnetes Werk:	In: International Marine Energy Journal - European Wave and Tidal Energy Conference, 2021, 5(2022), 1
Übergeordnetes Werk:	volume:5 ; year:2022 ; number:1

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.36688/imej.5.45-56

Katalog-ID:	DOAJ043875653

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callnumber-first	T - Technology
author	Ali Mohtat
spellingShingle	Ali Mohtat misc TC1501-1800 misc TJ807-830 misc Wave energy conversion, Cycloidal wave energy convertor, Deep-water waves, Wave radiation, irregular waves, short crested waves misc Ocean engineering misc Renewable energy sources Efficiency analysis of the cycloidal wave energy convertor under real-time dynamic control using a 3D radiation model
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topic_title	TC1501-1800 TJ807-830 Efficiency analysis of the cycloidal wave energy convertor under real-time dynamic control using a 3D radiation model Wave energy conversion, Cycloidal wave energy convertor, Deep-water waves, Wave radiation, irregular waves, short crested waves
topic	misc TC1501-1800 misc TJ807-830 misc Wave energy conversion, Cycloidal wave energy convertor, Deep-water waves, Wave radiation, irregular waves, short crested waves misc Ocean engineering misc Renewable energy sources
topic_unstemmed	misc TC1501-1800 misc TJ807-830 misc Wave energy conversion, Cycloidal wave energy convertor, Deep-water waves, Wave radiation, irregular waves, short crested waves misc Ocean engineering misc Renewable energy sources
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title	Efficiency analysis of the cycloidal wave energy convertor under real-time dynamic control using a 3D radiation model
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title_full	Efficiency analysis of the cycloidal wave energy convertor under real-time dynamic control using a 3D radiation model
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title_sort	efficiency analysis of the cycloidal wave energy convertor under real-time dynamic control using a 3d radiation model
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title_auth	Efficiency analysis of the cycloidal wave energy convertor under real-time dynamic control using a 3D radiation model
abstract	Ocean waves provide a vast, uninterrupted resource of renewable energy collocated around large coastal population centers. Clean energy from ocean waves can contribute to the local electrical grid without the need for long-term electrical storage, yet due to the current high cost of energy extraction from ocean waves, there is no commercial ocean wave farm in operation. One of the wave energy converter (WEC) device classes that show the potential to enable economic energy generation from ocean waves is the class of wave terminators. This work investigates the Cycloidal Wave Energy Converter (CycWEC), which is a one-sided, lift-based wave terminator operating with coupled hydrofoils. The energy that the CycWEC extracted from ocean waves was estimated using a control volume analysis model of the 3D wave field in the presence of the CycWEC. The CycWEC was operated under feedback control to extract the maximum amount of energy possible from the incoming waves, and the interaction with different incoming regular, irregular, and short crested waves was examined.
abstractGer	Ocean waves provide a vast, uninterrupted resource of renewable energy collocated around large coastal population centers. Clean energy from ocean waves can contribute to the local electrical grid without the need for long-term electrical storage, yet due to the current high cost of energy extraction from ocean waves, there is no commercial ocean wave farm in operation. One of the wave energy converter (WEC) device classes that show the potential to enable economic energy generation from ocean waves is the class of wave terminators. This work investigates the Cycloidal Wave Energy Converter (CycWEC), which is a one-sided, lift-based wave terminator operating with coupled hydrofoils. The energy that the CycWEC extracted from ocean waves was estimated using a control volume analysis model of the 3D wave field in the presence of the CycWEC. The CycWEC was operated under feedback control to extract the maximum amount of energy possible from the incoming waves, and the interaction with different incoming regular, irregular, and short crested waves was examined.
abstract_unstemmed	Ocean waves provide a vast, uninterrupted resource of renewable energy collocated around large coastal population centers. Clean energy from ocean waves can contribute to the local electrical grid without the need for long-term electrical storage, yet due to the current high cost of energy extraction from ocean waves, there is no commercial ocean wave farm in operation. One of the wave energy converter (WEC) device classes that show the potential to enable economic energy generation from ocean waves is the class of wave terminators. This work investigates the Cycloidal Wave Energy Converter (CycWEC), which is a one-sided, lift-based wave terminator operating with coupled hydrofoils. The energy that the CycWEC extracted from ocean waves was estimated using a control volume analysis model of the 3D wave field in the presence of the CycWEC. The CycWEC was operated under feedback control to extract the maximum amount of energy possible from the incoming waves, and the interaction with different incoming regular, irregular, and short crested waves was examined.
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title_short	Efficiency analysis of the cycloidal wave energy convertor under real-time dynamic control using a 3D radiation model
url	https://doi.org/10.36688/imej.5.45-56 https://doaj.org/article/d1b116ea022b4dfbabbbe5098c70ebdd http://marineenergyjournal.org/imej/article/view/118 https://doaj.org/toc/2631-5548
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Efficiency analysis of the cycloidal wave energy convertor under real-time dynamic control using a 3D radiation model

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