Optimization of a three-dimensional hybrid system combining a floating breakwater and a wave energy converter array

A three dimensional time-domain model, based on Cummins equation, has been developed for an axisymmetric point absorbing wave energy converter (WEC) with an irregular cross section. This model incorporates a number of nonlinearities to accurately account for the dynamics of the device: hydrostatic restoring, motion constraints, saturation of the power-take-off force, and kinematic nonlinearities. Here, an interpolation model of the hydrostatic restoring reaction is developed and compared with a surface integral based method. The effects of these nonlinear hydrostatic models on device dynamics are explored by comparing predictions against those of a linear model. For the studied WEC, the interpolation model offers a large improvement over a linear model and is roughly two orders-of-magnitude less computationally expensive than the surface integral based method.

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Numerical Simulation of Duck Wave Energy Converter

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.693.484 ◽

2016 ◽

Vol 693 ◽

pp. 484-490

Author(s):

Ying Xue Yao ◽

Hai Long Li ◽

Jin Ming Wu ◽

Liang Zhou

Keyword(s):

Numerical Simulation ◽

Wave Energy ◽

Pitch Angle ◽

Low Cost ◽

Three Dimensional ◽

Angular Frequency ◽

Wave Energy Converter ◽

Linear Wave ◽

Energy Converter ◽

Flow Theories

Duck wave energy converter has the advantages of high conversion efficiency, simple construction, low cost relative to other wave power device. In the paper, the numerical simulation of the response of the converter was calculated by the AQWA software which based on the three dimensional potential flow theories. The results show that the pitch angle appear the peak when the incident wave frequency is 1rad/s and the maximum of the pitch angle come out as the linear wave normally incident the duck body, which means duck wave energy converter can absorb more wave energy in this angular frequency. The above research can provide reference for the design of the duck wave energy converter.

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Nonlinear Time-Domain Simulation of the Heaving-Buoy Type Wave Energy Converter by Using Three-Dimensional Potential Numerical Wave Tank Under Irregular Wave Conditions

Volume 9: Ocean Renewable Energy ◽

10.1115/omae2020-18392 ◽

2020 ◽

Author(s):

Sung-Jae Kim ◽

Weoncheol Koo ◽

Moo-Hyun Kim

Keyword(s):

Wave Energy ◽

Time Domain ◽

Three Dimensional ◽

Wave Energy Converter ◽

Hydrodynamic Performance ◽

Numerical Wave Tank ◽

Energy Converter ◽

Wave Tank ◽

Type Wave ◽

Numerical Wave

Abstract The aim of this paper is to evaluate the hydrodynamic performance of a heaving buoy type wave energy converter (WEC) and power take-off (PTO) system. To simulate the nonlinear behavior of the WEC with PTO system, a three-dimensional potential numerical wave tank (PNWT) was developed. The PNWT is a numerical analysis tool that can accurately reproduce experiments in physical wave tanks. The developed time-domain PNWT utilized the previously developed NWT technique and newly adopted the side wall damping area. The PNWT is based on boundary element method with constant panels. The mixed Eulerian-Lagrangian method (MEL) and acceleration potential approach were adopted to simulate the nonlinear behaviors of free-surface nodes associated with body motions. The PM spectrum as an irregular incident wave condition was applied to the input boundary. A floating or fixed type WEC structure was placed in the center of the computational domain. A hydraulic PTO system composed of a hydraulic cylinder, hydraulic motor and generator was modeled with approximate Coulomb damping force and applied to the WEC system. Using the integrated numerical model of the WEC with PTO system, nonlinear interaction of irregular waves, the WEC structure, and the PTO system were simulated in the time domain. The optimal hydraulic pressure of the PTO condition was predicted. The hydrodynamic performance of the WEC was evaluated by comparing the linear and nonlinear analytical results and highlighted the importance accounting for nonlinear free surfaces.

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A submerged cylinder wave energy converter

Journal of Fluid Mechanics ◽

10.1017/jfm.2012.557 ◽

2013 ◽

Vol 716 ◽

pp. 566-596 ◽

Cited By ~ 9

Author(s):

S. Crowley ◽

R. Porter ◽

D. V. Evans

Keyword(s):

Wave Energy ◽

Three Dimensional ◽

Wave Energy Converter ◽

Wave Crest ◽

Maximum Efficiency ◽

Passive Component ◽

Mooring System ◽

Energy Converter ◽

Rotation Rates ◽

Sea Bed

AbstractA novel design concept for a wave energy converter (WEC) is presented and analysed. Its purpose is to balance the theoretical capacity for power absorption against engineering design issues which plague many existing WEC concepts. The WEC comprises a fully submerged buoyant circular cylinder tethered to the sea bed by a simple mooring system which permits coupled surge and roll motions of the cylinder. Inside the cylinder a mechanical system of pendulums rotate with power generated by the relative rotation rates of the pendulums and the cylinder. The attractive features of this design include: making use of the mooring system as a passive component of the power take off (PTO); using a submerged device to protect it from excessive forces associated with extreme wave conditions; locating the PTO within the device and using a PTO mechanism which does not need to be constrained; exploiting multiple resonances of the system to provide a broad-banded response. A mathematical model is developed which couples the hydrodynamic waves forces on the device with the internal pendulums under a linearized framework. For a cylinder spanning a wave tank (equivalent to a two-dimensional assumption) maximum theoretical power for this WEC device is limited to 50 % maximum efficiency. However, numerical results show that a systematically optimized system can generate theoretical efficiencies of more than 45 % over a 6 s range of wave period containing most of the energy in a typical energy spectrum. Furthermore, three-dimensional results for a cylinder of finite length provide evidence that a cylinder device twice the length of its diameter can produce more than its own length in the power of an equivalent incident wave crest.

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Experimental investigation of a triple pontoon wave energy converter and breakwater hybrid system

IET Renewable Power Generation ◽

10.1049/rpg2.12214 ◽

2021 ◽

Author(s):

Wei Peng ◽

Yingnan Zhang ◽

Qingping Zou ◽

Xueer Yang ◽

Yanjun Liu ◽

...

Keyword(s):

Experimental Investigation ◽

Hybrid System ◽

Wave Energy ◽

Wave Energy Converter ◽

Energy Converter

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Hydrodynamic Performance of a Hybrid System Combining a Fixed Breakwater and a Wave Energy Converter: An Experimental Study

Energies ◽

10.3390/en13215740 ◽

2020 ◽

Vol 13 (21) ◽

pp. 5740

Author(s):

Wei Peng ◽

Yingnan Zhang ◽

Xueer Yang ◽

Jisheng Zhang ◽

Rui He ◽

...

Keyword(s):

Experimental Study ◽

Hybrid System ◽

Wave Energy ◽

Wave Energy Converter ◽

Hydrodynamic Performance ◽

Scale Model ◽

Wave Power ◽

Energy Converter ◽

Power Extraction ◽

Wave Induced

In this paper, a hybrid system integrating a fixed breakwater and an oscillating buoy type wave energy converter (WEC) is introduced. The energy converter is designed to extract the wave power by making use of the wave-induced heave motions of the three floating pontoons in front of the fixed breakwater. A preliminary experimental study is carried out to discuss the hydrodynamic performance of the hybrid system under the action of regular waves. A scale model was built in the laboratory at Hohai University, and the dissipative force from racks and gearboxes and the Ampere force from dynamos were employed as the power take-off (PTO) damping source. During the experiments, variations in numbers of key parameters, including the wave elevation, free response or damped motion of the floating pontoons, and the voltage output of the dynamos were simultaneously measured. Results indicate that the wave overtopping and breaking occurring on the upper surfaces of floating pontoons have a significant influence on the hydrodynamic performance of the system. For moderate and longer waves, the developed system proves to be effective in attenuating the incident energy, with less than 30% of the energy reflected back to the paddle. More importantly, the hydrodynamic efficiency of energy conversion for the present device can achieve approximately 19.6% at the lowest wave steepness in the model tests, implying that although the WEC model harnesses more energy in more energetic seas, the device may be more efficient for wave power extraction in a less energetic sea-state.

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