The Effect of Environmental Contour Selection on Expected Wave Energy Converter Response

A wave energy converter must be designed to both maximize power production and to ensure survivability, which requires the prediction of future sea states. It follows that precision in the prediction of those sea states should be important in determining a final WEC design. One common method used to estimate extreme conditions employs environmental contours of extreme conditions. This report compares five environmental contour methods and their repercussions on the response analysis of Reference Model 3 (RM3). The most extreme power take-off (PTO) force is predicted for the RM3 via each contour and compared to identify the potential difference in WEC response due to contour selection. The analysis provides insight into the relative performance of each of the contour methods and demonstrates the importance of an environmental contour in predicting extreme response. Ideally, over-predictions should be avoided, as they can add to device cost. At the same time, any “exceedances,” that is to say sea states that exceed predictions of the contour, should be avoided so that the device does not fail. For the extreme PTO force response studied here, relatively little sensitivity to the contour method is shown due to the collocation of the device's resonance with a region of agreement between the contours. However, looking at the level of observed exceedances for each contour may still give a higher level of confidence to some methods.

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On the Long-Term Reliability Analysis of a Point Absorber Wave Energy Converter

Volume 10: Ocean Renewable Energy ◽

10.1115/omae2017-62141 ◽

2017 ◽

Cited By ~ 1

Author(s):

Jarred Canning ◽

Phong Nguyen ◽

Lance Manuel ◽

Ryan G. Coe

Keyword(s):

Wave Energy ◽

Reference Model ◽

Wave Energy Converter ◽

Environmental Data ◽

Energy Converter ◽

Short Term ◽

Point Absorber ◽

Extreme Response ◽

Term Response

Of interest in this study is the long-term response and performance of a two-body wave point absorber (“Reference Model 3”), which serves as a wave energy converter (WEC). In a previous study, the short-term uncertainty in this device’s response was studied for an extreme sea state. We now focus on the assessment of the long-term response of the device where we consider all possible sea states at a site of interest. We demonstrate how simulation tools may be used to evaluate the long-term response and consider key performance parameters of the WEC device, which are the heave and surge forces on the power take-off system and the power take-off extension. We employ environmental data at a designated deployment site in Northern California. Metocean information is generated using approximately 15 years of data from this site (National Data Buoy Center site no. 46022). For various sea states, a selected significant wave height and peak period are chosen to describe representative conditions. Then, using a public-domain simulation tool (Wave Energy Converter Simulator or WEC-Sim), we generate various short-term time-domain response measure for these sea states. Distribution fits to extreme response statistics are generated, for each bin that represents a cluster of sea states, using the open-source toolbox, WDRT (WEC Design Response Toolbox). Long-term distributions for each response variable of interest are estimated by weighting short-term distributions by the likelihood of the sea states; from these distributions, the 50-year response can be derived. The 50-year response is also estimated using an approximate but more efficient inverse reliability approach. Comparisons are made between the two approaches.

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A Study on Development of the Performance Analysis Method of the Floating OWC-WEC Using the MPS Method

Volume 6: Ocean Space Utilization ◽

10.1115/omae2015-42049 ◽

2015 ◽

Cited By ~ 1

Author(s):

Yutaro Sasahara ◽

Mitsuhiro Masuda ◽

Kiyokazu Minami

Keyword(s):

Wave Energy ◽

Two Phase Flow ◽

Wave Energy Converter ◽

Response Analysis ◽

Phase Flow ◽

Energy Converter ◽

Wave Impact ◽

Two Phase ◽

Mps Method ◽

Type Wave

When concrete examination towards utilization is needed, it is necessary to estimate the safety and the performance of a floating Oscillation Water Column (OWC)-type wave energy converter under abnormal oceanographic phenomenon such as large waves, wave impact force, deck wetness and complex motion of mooring system. Therefore, to choose a proper numerical method is important. This present paper describes a fundamental study about estimation of safety and performance of floating OWC-type wave energy converter using the two-phase flow MPS method. In this research, firstly, new algorithm is installed in order to solve problems of the two-phase flow MPS method. Secondly, applicability to an response analysis of a wharf installation type OWC-WEC of the improved MPS method is examined by wave pressure acting to the OWC-WEC and response in the air chamber of the OWC-WEC.

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Reference Model 5 (RM5): Oscillating Surge Wave Energy Converter

10.2172/1169778 ◽

2015 ◽

Cited By ~ 2

Author(s):

Y. H. Yu ◽

D. S. Jenne ◽

R. Thresher ◽

A. Copping ◽

S. Geerlofs ◽

...

Keyword(s):

Wave Energy ◽

Reference Model ◽

Wave Energy Converter ◽

Energy Converter

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Design and simulation of point absorber wave energy converter

E3S Web of Conferences ◽

10.1051/e3sconf/202132103003 ◽

2021 ◽

Vol 321 ◽

pp. 03003

Author(s):

Devesh Singh ◽

Anoop Singh ◽

Akshoy Ranjan Paul ◽

Abdus Samad

Keyword(s):

Energy Harvesting ◽

Wave Energy ◽

Wave Energy Converter ◽

Response Analysis ◽

Ocean Energy ◽

Energy Converter ◽

Point Absorber ◽

Time Response Analysis ◽

Floating System ◽

Energy Harvesting System

The paper aims to design and simulation of a wave energy harvesting system commonly known as point absorber for Ennore port located in the coastal area of Chennai, India. The geographical condition of India, which is surrounded by the three sides with seas and ocean, has enormous opportunity for power production through wave energy harvesting system. The wave energy converter device is a two-body floating system and its both parts are connected by power take-off unit which acts as spring mass damper system. In this paper, the hydrodynamic diffraction, stability analysis, frequency, and time response analysis is carried out on ansys-aqwa. The numerical results are compared with the results obtained from the similar experiments for validation of CFD solver. Effects of the properties featuring wave characteristics including wave height and wave period of Ennore port on the energy conversion, Froude-Krylov and diffraction force, response amplitude operator (RAO) are studied. Based on the study, float diameter, draft, geometry, and varying damping coefficient for power generation are optimized. Finally, the optimally designed point absorber is simulated as per Indian ocean energy harvesting standard and mass of the system, heave dimension, diffraction forces, and pressure variations are computed.

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Motion Response Analysis of Floating Wind Turbine Combined with Wave Energy Converter

APAC 2019 ◽

10.1007/978-981-15-0291-0_150 ◽

2019 ◽

pp. 1099-1106

Author(s):

K. Chaitanya Sai ◽

Ajay H. Patil ◽

D. Karmaka

Keyword(s):

Wind Turbine ◽

Wave Energy ◽

Wave Energy Converter ◽

Response Analysis ◽

Energy Converter ◽

Motion Response ◽

Floating Wind Turbine

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Erratum: “Frequency Response Analysis of an Ocean Wave Energy Converter” (Journal of Dynamic Systems, Measurement, and Control, 1983, 105, pp. 30–38)

Journal of Dynamic Systems Measurement and Control ◽

10.1115/1.3140672 ◽

1983 ◽

Vol 105 (4) ◽

pp. 286-286

Author(s):

M. Masubuchi ◽

R. Kawatani

Keyword(s):

Frequency Response ◽

Dynamic Systems ◽

Wave Energy ◽

Wave Energy Converter ◽

Response Analysis ◽

Frequency Response Analysis ◽

Energy Converter ◽

Ocean Wave Energy ◽

And Control ◽

Measurement And Control

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Full long-term design response analysis of a wave energy converter

Renewable Energy ◽

10.1016/j.renene.2017.09.056 ◽

2018 ◽

Vol 116 ◽

pp. 356-366 ◽

Cited By ~ 8

Author(s):

Ryan G. Coe ◽

Carlos Michelen ◽

Aubrey Eckert-Gallup ◽

Cédric Sallaberry

Keyword(s):

Wave Energy ◽

Wave Energy Converter ◽

Response Analysis ◽

Energy Converter

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Experimental Wave Tank Test for Reference Model 3 Floating-Point Absorber Wave Energy Converter Project

10.2172/1169792 ◽

2015 ◽

Cited By ~ 3

Author(s):

Y. H. Yu ◽

M. Lawson ◽

Y. Li ◽

M. Previsic ◽

J. Epler ◽

...

Keyword(s):

Wave Energy ◽

Reference Model ◽

Wave Energy Converter ◽

Floating Point ◽

Energy Converter ◽

Wave Tank ◽

Point Absorber ◽

Tank Test

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Structural Modeling and Analysis of a Wave Energy Converter Applying Dynamical Substructuring Method

Volume 8: Ocean Renewable Energy ◽

10.1115/omae2013-10854 ◽

2013 ◽

Cited By ~ 1

Author(s):

Andrew S. Zurkinden ◽

Lars Damkilde ◽

Zhen Gao ◽

Torgeir Moan

Keyword(s):

Wave Energy ◽

Structural Modeling ◽

Wave Energy Converter ◽

Computational Time ◽

Response Analysis ◽

Fe Model ◽

Wave Loads ◽

Energy Converter ◽

Modeling And Analysis ◽

Survival Mode

This paper deals with structural modeling and analysis of a wave energy converter. The device, called Wavestar, is a bottom fixed structure, located in a shallow water environment at the Danish Northwest coast. The analysis is concentrated on a single float and its structural arm which connects the WEC to a jackup structure. The wave energy converter is characterized by having an operational and survival mode. The survival mode drastically reduces the exposure to waves and therfore to the wave loads. Structural response analysis of the Wavestar arm is carried out in this study. Due to the relative stiff behavior of the arm the calculation can be reduced to a quasi-static analysis. The hydrodynamic and the structural analyses are thus performed separately. In order to reduce the computational time of the finite element calculation the main structure is modeled as a superelement. The structural detail, where the stress analysis is carried out, is connected with the superstructure by interface nodes. The analysis is conducted for two different control situations. Numerical results will be presented which can be further used to carry out fatigue analysis in which a more refined FE model is required to obtain the stress concentration factors.

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Preliminary Verification and Validation of WEC-Sim, an Open-Source Wave Energy Converter Design Tool

Volume 9B: Ocean Renewable Energy ◽

10.1115/omae2014-24312 ◽

2014 ◽

Cited By ~ 10

Author(s):

Kelley Ruehl ◽

Carlos Michelen ◽

Samuel Kanner ◽

Michael Lawson ◽

Yi-Hsiang Yu

Keyword(s):

Wave Energy ◽

Reference Model ◽

Design Tool ◽

Wave Energy Converter ◽

Energy Converter ◽

Point Absorber ◽

Preliminary Validation ◽

Model Project ◽

Converter Design ◽

Source Wave

To promote and support the wave energy industry, a wave energy converter (WEC) design tool, WEC-Sim, is being developed by Sandia National Laboratories and the National Renewable Energy Laboratory. In this paper, the WEC-Sim code is used to model a point absorber WEC designed by the U.S. Department of Energy’s reference model project. Preliminary verification was performed by comparing results of the WEC-Sim simulation through a code-to-code comparison, utilizing the commercial codes ANSYS-AQWA, WaveDyn, and OrcaFlex. A preliminary validation of the code was also performed by comparing WEC-Sim simulation results to experimental wave tank tests.

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