The power-capture of a nearshore, modular, flap-type wave energy converter in regular waves

Laurie Wilkinson; Trevor Whittaker; Philipp R. Thies; Alexander Day; David Ingram

doi:10.1016/j.oceaneng.2017.04.016

The power-capture of a nearshore, modular, flap-type wave energy converter in regular waves

Laurie Wilkinson, Trevor Whittaker, Philipp R. Thies, Alexander Day, David Ingram

School of Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Bottom-hinged, nearshore flap-type wave energy converters (WECs), have several advantages, such as high power conversion efficiency and survivability. They typically comprise a single flap spanning their full width. However, a potentially beneficial design change would be to split the flap into multiple modules, to make a ‘Modular Flap’. This could provide improvements, such as increased power-capture, reduced foundation loads and lower manufacturing and installation costs. Assessed in this work is the hydrodynamic power-capture of this device, based on physical modelling. Comparisons are made to an equivalent ‘Rigid Flap’. Tests are conducted in regular, head-on and off-angle waves. The simplest control strategy, of damping each module equally, is employed.

The results show that, for head-on waves, the power increases towards the centre of the device, with the central modules generating 68% of the total power. Phase differences are also present. Consequently, the total power produced by the Modular Flap is, on average, 23% more smooth than that generated by the Rigid Flap.

The Modular Flap has 3% and 1% lower average power-capture than the Rigid Flap in head-on and off-angle waves, respectively. The advantages of the modular concept may therefore be exploited without significantly compromising the power-capture of the flap-type WEC.

Original language	English
Journal	Ocean Engineering
Early online date	21 Apr 2017
DOIs	https://doi.org/10.1016/j.oceaneng.2017.04.016
Publication status	E-pub ahead of print - 21 Apr 2017

Keywords

Wave energy converter
Power
Modular Flap

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10.1016/j.oceaneng.2017.04.016Licence: Creative Commons: Attribution (CC-BY)

1-s2.0-S0029801817302019-mainFinal published version, 1.38 MBLicence: CC BY

Extension of UKCMER Core Research, Industry and International Engagement
Wallace, R., Ingram, D. & Kiprakis, A.
EPSRC
1/01/15 → 31/12/17
Project: Research

Cite this

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title = "The power-capture of a nearshore, modular, flap-type wave energy converter in regular waves",

abstract = "Bottom-hinged, nearshore flap-type wave energy converters (WECs), have several advantages, such as high power conversion efficiency and survivability. They typically comprise a single flap spanning their full width. However, a potentially beneficial design change would be to split the flap into multiple modules, to make a {\textquoteleft}Modular Flap{\textquoteright}. This could provide improvements, such as increased power-capture, reduced foundation loads and lower manufacturing and installation costs. Assessed in this work is the hydrodynamic power-capture of this device, based on physical modelling. Comparisons are made to an equivalent {\textquoteleft}Rigid Flap{\textquoteright}. Tests are conducted in regular, head-on and off-angle waves. The simplest control strategy, of damping each module equally, is employed.The results show that, for head-on waves, the power increases towards the centre of the device, with the central modules generating 68% of the total power. Phase differences are also present. Consequently, the total power produced by the Modular Flap is, on average, 23% more smooth than that generated by the Rigid Flap.The Modular Flap has 3% and 1% lower average power-capture than the Rigid Flap in head-on and off-angle waves, respectively. The advantages of the modular concept may therefore be exploited without significantly compromising the power-capture of the flap-type WEC.",

keywords = "Wave energy converter, Power, Modular Flap",

author = "Laurie Wilkinson and Trevor Whittaker and Thies, {Philipp R.} and Alexander Day and David Ingram",

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AU - Wilkinson, Laurie

AU - Whittaker, Trevor

AU - Thies, Philipp R.

AU - Day, Alexander

AU - Ingram, David

PY - 2017/4/21

Y1 - 2017/4/21

N2 - Bottom-hinged, nearshore flap-type wave energy converters (WECs), have several advantages, such as high power conversion efficiency and survivability. They typically comprise a single flap spanning their full width. However, a potentially beneficial design change would be to split the flap into multiple modules, to make a ‘Modular Flap’. This could provide improvements, such as increased power-capture, reduced foundation loads and lower manufacturing and installation costs. Assessed in this work is the hydrodynamic power-capture of this device, based on physical modelling. Comparisons are made to an equivalent ‘Rigid Flap’. Tests are conducted in regular, head-on and off-angle waves. The simplest control strategy, of damping each module equally, is employed.The results show that, for head-on waves, the power increases towards the centre of the device, with the central modules generating 68% of the total power. Phase differences are also present. Consequently, the total power produced by the Modular Flap is, on average, 23% more smooth than that generated by the Rigid Flap.The Modular Flap has 3% and 1% lower average power-capture than the Rigid Flap in head-on and off-angle waves, respectively. The advantages of the modular concept may therefore be exploited without significantly compromising the power-capture of the flap-type WEC.

AB - Bottom-hinged, nearshore flap-type wave energy converters (WECs), have several advantages, such as high power conversion efficiency and survivability. They typically comprise a single flap spanning their full width. However, a potentially beneficial design change would be to split the flap into multiple modules, to make a ‘Modular Flap’. This could provide improvements, such as increased power-capture, reduced foundation loads and lower manufacturing and installation costs. Assessed in this work is the hydrodynamic power-capture of this device, based on physical modelling. Comparisons are made to an equivalent ‘Rigid Flap’. Tests are conducted in regular, head-on and off-angle waves. The simplest control strategy, of damping each module equally, is employed.The results show that, for head-on waves, the power increases towards the centre of the device, with the central modules generating 68% of the total power. Phase differences are also present. Consequently, the total power produced by the Modular Flap is, on average, 23% more smooth than that generated by the Rigid Flap.The Modular Flap has 3% and 1% lower average power-capture than the Rigid Flap in head-on and off-angle waves, respectively. The advantages of the modular concept may therefore be exploited without significantly compromising the power-capture of the flap-type WEC.

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KW - Power

KW - Modular Flap

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DO - 10.1016/j.oceaneng.2017.04.016

M3 - Article

JO - Ocean Engineering

JF - Ocean Engineering

SN - 0029-8018

ER -

The power-capture of a nearshore, modular, flap-type wave energy converter in regular waves

Abstract

Keywords

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Extension of UKCMER Core Research, Industry and International Engagement

Cite this