Analytical investigation of hydrodynamic performance of a dual pontoon WEC-type breakwater

Analytical investigation of hydrodynamic performance of a dual pontoon WEC-type breakwater

•A dual pontoon WEC-type breakwater, the summation of whose volumes is smaller than that of the original single pontoon, is proposed.•Analytical study on the performance of the dual pontoon WEC-type breakwater is conducted.•The broader effective frequency bandwidth can be achieved by comparing with...

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Veröffentlicht in:Applied ocean research 2017-04, Vol.65, p.102-111
Hauptverfasser: Ning, De-Zhi, Zhao, Xuan-Lie, Zhao, Ming, Hann, Martyn, Kang, Hai-Gui
Format: Artikel
Sprache:eng
Schlagworte:
Breakwaters
Buoys
Coefficients
Conversion
Damping
Effective frequency range
Energy conservation
Floating
Floating breakwaters
Fluid mechanics
Heaving
Hydrodynamics
Linear potential flow theory
Oscillators
Pontoons
Potential flow
Resonant frequency
Studies
Wave energy
Wave energy extraction
Wave power
Wave power devices
Width
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container_end_page 111
container_issue
container_start_page 102
container_title Applied ocean research
container_volume 65
creator Ning, De-Zhi
Zhao, Xuan-Lie
Zhao, Ming
Hann, Martyn
Kang, Hai-Gui
description •A dual pontoon WEC-type breakwater, the summation of whose volumes is smaller than that of the original single pontoon, is proposed.•Analytical study on the performance of the dual pontoon WEC-type breakwater is conducted.•The broader effective frequency bandwidth can be achieved by comparing with that of the single pontoon type. Based on the linear potential flow theory and matching eigen-function expansion technique, an analytical model is developed to investigate the hydrodynamics of two-dimensional dual-pontoon floating breakwaters that also work as oscillating buoy wave energy converters (referred to as the integrated system hereafter). The pontoons are constrained to heave motion independently and the linear power take-off damping is used to calculate the absorbed power. The proposed model is verified by using the energy conservation principle. The effects of the geometrical parameters on the hydrodynamic properties of the integrated system, including the reflection and transmission coefficients and CWR (capture width ratio, which is defined as the ratio of absorbed wave power to the incident wave power in the device width). It is found that the natural frequency of the heave motion and the spacing of the two pontoons are the critical factors affecting the performance of the integrated system. The comparison between the results of the dual-pontoon breakwater and those of the single-pontoon breakwater shows that the effective frequency range (for condition of transmission coefficient KT20%) of the dual-pontoon system is broader than that of the single-pontoon system with the same total volume. For the two-pontoon system, the effective frequency range can be broadened by decreasing the draft of the front pontoon within certain range.
doi_str_mv 10.1016/j.apor.2017.03.012
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Based on the linear potential flow theory and matching eigen-function expansion technique, an analytical model is developed to investigate the hydrodynamics of two-dimensional dual-pontoon floating breakwaters that also work as oscillating buoy wave energy converters (referred to as the integrated system hereafter). The pontoons are constrained to heave motion independently and the linear power take-off damping is used to calculate the absorbed power. The proposed model is verified by using the energy conservation principle. The effects of the geometrical parameters on the hydrodynamic properties of the integrated system, including the reflection and transmission coefficients and CWR (capture width ratio, which is defined as the ratio of absorbed wave power to the incident wave power in the device width). It is found that the natural frequency of the heave motion and the spacing of the two pontoons are the critical factors affecting the performance of the integrated system. The comparison between the results of the dual-pontoon breakwater and those of the single-pontoon breakwater shows that the effective frequency range (for condition of transmission coefficient KT&lt;0.5 and the total capture width ratio ηtotal&gt;20%) of the dual-pontoon system is broader than that of the single-pontoon system with the same total volume. 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Based on the linear potential flow theory and matching eigen-function expansion technique, an analytical model is developed to investigate the hydrodynamics of two-dimensional dual-pontoon floating breakwaters that also work as oscillating buoy wave energy converters (referred to as the integrated system hereafter). The pontoons are constrained to heave motion independently and the linear power take-off damping is used to calculate the absorbed power. The proposed model is verified by using the energy conservation principle. The effects of the geometrical parameters on the hydrodynamic properties of the integrated system, including the reflection and transmission coefficients and CWR (capture width ratio, which is defined as the ratio of absorbed wave power to the incident wave power in the device width). It is found that the natural frequency of the heave motion and the spacing of the two pontoons are the critical factors affecting the performance of the integrated system. The comparison between the results of the dual-pontoon breakwater and those of the single-pontoon breakwater shows that the effective frequency range (for condition of transmission coefficient KT&lt;0.5 and the total capture width ratio ηtotal&gt;20%) of the dual-pontoon system is broader than that of the single-pontoon system with the same total volume. 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Based on the linear potential flow theory and matching eigen-function expansion technique, an analytical model is developed to investigate the hydrodynamics of two-dimensional dual-pontoon floating breakwaters that also work as oscillating buoy wave energy converters (referred to as the integrated system hereafter). The pontoons are constrained to heave motion independently and the linear power take-off damping is used to calculate the absorbed power. The proposed model is verified by using the energy conservation principle. The effects of the geometrical parameters on the hydrodynamic properties of the integrated system, including the reflection and transmission coefficients and CWR (capture width ratio, which is defined as the ratio of absorbed wave power to the incident wave power in the device width). It is found that the natural frequency of the heave motion and the spacing of the two pontoons are the critical factors affecting the performance of the integrated system. 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subjects Breakwaters
Buoys
Coefficients
Conversion
Damping
Effective frequency range
Energy conservation
Floating
Floating breakwaters
Fluid mechanics
Heaving
Hydrodynamics
Linear potential flow theory
Oscillators
Pontoons
Potential flow
Resonant frequency
Studies
Wave energy
Wave energy extraction
Wave power
Wave power devices
Width
title Analytical investigation of hydrodynamic performance of a dual pontoon WEC-type breakwater
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