Ocean Energy Systems Wave Energy Modelling Task: Modelling, Verification and Validation of Wave Energy Converters

Authors

Fabian Wendt
Kim Nielsen
Yi Hsiang Yu
Harry Bingham
Claes Eskilsson
Morten Kramer
Aurélien Babarit
Tim Bunnik
Ronan Costello
Sarah Crowley
Benjamin Gendron
N/A Giorgi
N/A Giorgi
Samuel Girardin
Deborah Greaves, School of Engineering, Computing and Mathematics
Pilar Heras
Johan Hoffman
Hafizul Islam
Ken Robert Jakobsen
Carl Erik Janson
Johan Jansson
N/A Kim
N/A Kim
N/A Kim
Adi Kurniawan
Massimiliano Leoni
Thomas Mathai
Bo Woo Nam
Sewan Park
Krishnakumar Rajagopalan
Edward Ransley
Robert Read
John V. Ringwood
José Miguel Rodrigues
Benjamin Rosenthal
André Roy
Kelley Ruehl
N/A Schofield
Wanan Sheng
Abolfazl Shiri
Sarah Thomas
Imanol Touzon
Imai Yasutaka

ORCID

No ORCIDs Found

Abstract

The International Energy Agency Technology Collaboration Programme for Ocean Energy Systems (OES) initiated the OES Wave Energy Conversion Modelling Task, which focused on the verification and validation of numerical models for simulating wave energy converters (WECs). The long-term goal is to assess the accuracy of and establish confidence in the use of numerical models used in design as well as power performance assessment of WECs. To establish this confidence, the authors used different existing computational modelling tools to simulate given tasks to identify uncertainties related to simulation methodologies: (i) linear potential flow methods; (ii) weakly nonlinear Froude–Krylov methods; and (iii) fully nonlinear methods (fully nonlinear potential flow and Navier–Stokes models). This article summarizes the code-to-code task and code-to-experiment task that have been performed so far in this project, with a focus on investigating the impact of different levels of nonlinearities in the numerical models. Two different WECs were studied and simulated. The first was a heaving semi-submerged sphere, where free-decay tests and both regular and irregular wave cases were investigated in a code-to-code comparison. The second case was a heaving float corresponding to a physical model tested in a wave tank. We considered radiation, diffraction, and regular wave cases and compared quantities, such as the WEC motion, power output and hydrodynamic loading.

DOI

10.3390/jmse7110379

Publication Date

2019-10-25

Publication Title

Journal of Marine Science and Engineering

Volume

7

Issue

11

Embargo Period

2019-11-26

Organisational Unit

School of Engineering, Computing and Mathematics

Recommended Citation

Wendt, F., Nielsen, K., Yu, Y., Bingham, H., Eskilsson, C., Kramer, M., Babarit, A., Bunnik, T., Costello, R., Crowley, S., Gendron, B., Giorgi, N., Giorgi, N., Girardin, S., Greaves, D., Heras, P., Hoffman, J., Islam, H., Jakobsen, K., Janson, C., Jansson, J., Kim, N., Kim, N., Kim, N., Kurniawan, A., Leoni, M., Mathai, T., Nam, B., Park, S., Rajagopalan, K., Ransley, E., Read, R., Ringwood, J., Rodrigues, J., Rosenthal, B., Roy, A., Ruehl, K., Schofield, N., Sheng, W., Shiri, A., Thomas, S., Touzon, I., & Yasutaka, I. (2019) 'Ocean Energy Systems Wave Energy Modelling Task: Modelling, Verification and Validation of Wave Energy Converters', Journal of Marine Science and Engineering, 7(11). Available at: https://doi.org/10.3390/jmse7110379