Optimum parameter search for a slider-crank wave energy converter under regular and irregular wave conditions

Considered as a source of renewable energy, wave is a resource featuring high variability at all time scales. Furthermore wave climate also changes significantly from place to place. Wave energy converters are very often tuned to suit the more frequent significant wave period at the project site. In this paper we show that optimizing the device necessitates accounting for all possible wave conditions weighted by their annual occurrence frequency, as generally given by the classical wave climate scatter diagrams. A generic and very simple wave energy converter is considered here. It is shown how the optimal parameters can be different considering whether all wave conditions are accounted for or not, whether the device is controlled or not, whether the productive motion is limited or not. We also show how they depend on the area where the device is to be deployed, by applying the same method to three sites with very different wave climate.

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Experimental study on the performance of a floating array-point-raft wave energy converter under random wave conditions

Renewable Energy ◽

10.1016/j.renene.2019.02.093 ◽

2019 ◽

Vol 139 ◽

pp. 538-550 ◽

Cited By ~ 5

Author(s):

Shaohui Yang ◽

Hongzhou He ◽

Hu Chen ◽

Yongqing Wang ◽

Hui Li ◽

...

Keyword(s):

Experimental Study ◽

Wave Energy ◽

Wave Energy Converter ◽

Random Wave ◽

Energy Converter ◽

Wave Conditions

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Characterization of Extreme Wave Conditions for Wave Energy Converter Design and Project Risk Assessment

Journal of Marine Science and Engineering ◽

10.3390/jmse8040289 ◽

2020 ◽

Vol 8 (4) ◽

pp. 289 ◽

Cited By ~ 4

Author(s):

Vincent S. Neary ◽

Seongho Ahn ◽

Bibiana E. Seng ◽

Mohammad Nabi Allahdadi ◽

Taiping Wang ◽

...

Keyword(s):

Return Period ◽

Wave Energy ◽

Wave Energy Converter ◽

Extreme Value Analysis ◽

Extreme Wave ◽

Energy Converter ◽

Sea State ◽

Value Analysis ◽

Wave Conditions ◽

Wave Models

Best practices and international standards for determining n-year return period extreme wave (sea states) conditions allow wave energy converter designers and project developers the option to apply simple univariate or more complex bivariate extreme value analysis methods. The present study compares extreme sea state estimates derived from univariate and bivariate methods and investigates the performance of spectral wave models for predicting extreme sea states at buoy locations within several regional wave climates along the US East and West Coasts. Two common third-generation spectral wave models are evaluated, a WAVEWATCH III® model with a grid resolution of 4 arc-minutes (6–7 km), and a Simulating WAves Nearshore model, with a coastal resolution of 200–300 m. Both models are used to generate multi-year hindcasts, from which extreme sea state statistics used for wave conditions characterization can be derived and compared to those based on in-situ observations at National Data Buoy Center stations. Comparison of results using different univariate and bivariate methods from the same data source indicates reasonable agreement on average. Discrepancies are predominantly random. Large discrepancies are common and increase with return period. There is a systematic underbias for extreme significant wave heights derived from model hindcasts compared to those derived from buoy measurements. This underbias is dependent on model spatial resolution. However, simple linear corrections can effectively compensate for this bias. A similar approach is not possible for correcting model-derived environmental contours, but other methods, e.g., machine learning, should be explored.

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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

10.1115/1.0005215v ◽

2021 ◽

Author(s):

Weoncheol Koo ◽

Sung-Jae Kim ◽

Moo-Hyun Kim

Keyword(s):

Wave Energy ◽

Time Domain ◽

Three Dimensional ◽

Wave Energy Converter ◽

Numerical Wave Tank ◽

Time Domain Simulation ◽

Energy Converter ◽

Irregular Wave ◽

Type Wave ◽

Numerical Wave

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Analysis of a Two-Body Floating Wave Energy Converter With Particular Focus on the Effects of Power Take-Off and Mooring Systems on Energy Capture

Journal of Offshore Mechanics and Arctic Engineering ◽

10.1115/1.4023796 ◽

2013 ◽

Vol 135 (3) ◽

Cited By ~ 16

Author(s):

Made Jaya Muliawan ◽

Zhen Gao ◽

Torgeir Moan ◽

Aurelien Babarit

Keyword(s):

Wave Energy ◽

Wave Energy Converter ◽

Energy Converter ◽

Mooring Lines ◽

Energy Capture ◽

Irregular Wave ◽

Power Capture ◽

Actual Operation ◽

Linear Damping ◽

Two Bodies

The present paper summarizes analyses of a two-body floating wave energy converter (WEC) to determine the mooring tension and the effect of the mooring system on energy capture. Also, the effect of the power take-off (PTO) is assessed. An axisymmetric Wavebob-type WEC is chosen as the object of investigation. However, the PTO system is modeled in a simplified manner as ideal linear damping and spring terms that couple the motions of the two bodies. The analysis is performed using SIMO, which is a time domain simulation tool that accommodates the simulation of multibody systems with hydrodynamic interactions. In SIMO, docking cone features between the two bodies allow movement as per actual operation, and fenders are applied to represent end stops. Six alternative mooring configurations are applied to investigate the effect of mooring on power capture. Mooring analysis is performed to determine the necessary capacity of mooring lines for each configuration to carry the tension due to the WEC motion in extreme conditions. Hydrodynamic loads are determined using WAMIT. We assumed that the WEC will be operated to capture wave power at the Yeu site in France. The analysis is performed for several regular and irregular wave conditions according to wave data available for that site. Simulations are performed to study the effect of the PTO system, end stops settings and several mooring configurations on power capture.

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Spatial Environmental Assessment Tool (SEAT): A Modeling Tool to Evaluate Potential Environmental Risks Associated with Wave Energy Converter Deployments

Energies ◽

10.3390/en11082036 ◽

2018 ◽

Vol 11 (8) ◽

pp. 2036 ◽

Cited By ~ 2

Author(s):

Craig Jones ◽

Grace Chang ◽

Kaustubha Raghukumar ◽

Samuel McWilliams ◽

Ann Dallman ◽

...

Keyword(s):

Sediment Transport ◽

Environmental Assessment ◽

Wave Energy ◽

Assessment Tool ◽

Maximum Shear Stress ◽

Sediment Deposition ◽

Wave Energy Converter ◽

Benthic Habitat ◽

Energy Converter ◽

Wave Conditions

Wave energy converter (WEC) arrays deployed in coastal regions may create physical disturbances, potentially resulting in environmental stresses. Presently, limited information is available on the nature of these physical disturbance or the resultant effects. A quantitative Spatial Environmental Assessment Tool (SEAT) for evaluating the potential effects of wave energy converter (WEC) arrays on nearshore hydrodynamics and sediment transport is presented for the central Oregon coast (USA) through coupled numerical model simulations of an array of WECs. Derived climatological wave conditions were used as inputs to the model to allow for the calculation of risk metrics associated with various hydrodynamic and sediment transport variables such as maximum shear stress, bottom velocity, and change in bed elevation. The risk maps provided simple, quantitative, and spatially-resolved means of evaluating physical changes in the vicinity of a hypothetical WEC array in response to varying wave conditions. The near-field risk of sediment mobility was determined to be moderate in the lee of the densely spaced array, where the potential for increased sediment deposition could result in benthic habitat alteration. Modifications to the nearshore sediment deposition and erosion patterns were observed near headlands and topographic features, which could have implications for littoral sediment transport. The results illustrate the benefits of a risk evaluation tool for facilitating coastal resource management at early market marine renewable energy sites.

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Experimental Investigation of Irregular Wave Cancellation Using a Cycloidal Wave Energy Converter

Volume 7: Ocean Space Utilization; Ocean Renewable Energy ◽

10.1115/omae2012-83388 ◽

2012 ◽

Cited By ~ 1

Author(s):

Stefan G. Siegel ◽

Casey Fagley ◽

Marcus Römer ◽

Thomas McLaughlin

Keyword(s):

Wave Energy ◽

Deep Ocean ◽

Ocean Waves ◽

Wave Energy Converter ◽

Irregular Waves ◽

Energy Converter ◽

Irregular Wave ◽

Wave Measurements ◽

Wave Heights ◽

Significant Wave Heights

The ability of a Cycloidal Wave Energy Converter (CycWEC) to cancel irregular deep ocean waves is investigated in a 1:300 scale wave tunnel experiment. A CycWEC consists of one or more hydrofoils attached equidistant to a shaft that is aligned parallel to the incoming waves. The entire device is fully submerged in operation. Wave cancellation requires synchronization of the rotation of the CycWEC with the incoming waves, as well as adjustment of the pitch angle of the blades in proportion to the wave height. The performance of a state estimator and controller that achieve this objective were investigated, using the signal from a resistive wave gage located up-wave of the CycWEC as input. The CycWEC model used for the present investigations features two blades that are adjustable in pitch in real time. The performance of the CycWEC for both a superposition of two harmonic waves, as well as irregular waves following a Bretschneider spectrum is shown. Wave cancellation efficiencies as determined by wave measurements of about 80% for the majority of the cases are achieved, with wave periods varying from 0.4s to 0.75s and significant wave heights of Hs ≈ 20mm. This demonstrates that the CycWEC can efficiently interact with irregular waves, which is in good agreement with earlier results obtained from numerical simulations.

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