Effects of projected wave climate changes on the sizing and performance of OWCs: a focus on the Atlantic North African and European coastal waters

Journal Article

Title: Effects of projected wave climate changes on the sizing and performance of OWCs: a focus on the Atlantic North African and European coastal waters

Author:

Simonetti, I.; Cappietti, L.

Publication Date:

June 6, 2025

Journal:

International Marine Energy Journal

Volume:

Issue:

Pages:

177-186

Publisher:

European Wave and Tidal Energy Conference

Affiliation:

University of Florence

Technology:

Wave, Oscillating Water Column

Resource:

Site Characterization

Engineering:

Performance

Language:

English

Document Access

Website:

External Link

Citation

APA
BibTex
RIS

Simonetti, I.; Cappietti, L. (2025). Effects of projected wave climate changes on the sizing and performance of OWCs: a focus on the Atlantic North African and European coastal waters. International Marine Energy Journal, 8(2), 177-186. https://doi.org/10.36688/imej.8.177-186

@article{Simonetti-2025-24013,
author = {Simonetti, I and Cappietti, L},
title = {Effects of projected wave climate changes on the sizing and performance of OWCs: a focus on the Atlantic North African and European coastal waters},
journal = {International Marine Energy Journal},
year = {2025},
month = {jun},
publisher = {European Wave and Tidal Energy Conference},
volume = {8},
number = {2},
pages = {177--186},
doi = {10.36688/imej.8.177-186},
url = {https://marineenergyjournal.org/imej/article/view/228/114},
keywords = {Wave, Oscillating Water Column, Site Characterization, Performance},
}

Export Citation to BibTex

TY - JOUR
TI - Effects of projected wave climate changes on the sizing and performance of OWCs: a focus on the Atlantic North African and European coastal waters
AU - Simonetti, I
AU - Cappietti, L
T2 - International Marine Energy Journal
AB - Accurate estimates of the annual energy production achievable by a given wave energy converter are essential for a robust assessment of the associated levelized cost of energy, a key factor in investment decision-making. Inaccurate productivity estimates can arise - among other factors - from uncertainties in evaluating the available wave energy resource. The Climate Data Store of the Copernicus Climate Change Service delivers projections of the wave climate along the 20 m bathymetric contours of the whole European coastlines, covering the period 2040-2100, under two Representative Concentration Pathway scenarios(RCP4.5 and RCP8.5). This work addresses the effect of such long-term wave climate changes on the optimal sizing and performances of an Oscillating Water Column wave energy converter intended for installation along the North African and European Atlantic coastline. The capture width ratio of the device under different wave conditions is computed using an empirical model capable of predicting the device performance with acceptable accuracy and limited computational time. The results show that the optimal geometry of the OWC varies significantly in the different geographical locations and that the long-term changes in the wave energy resource could cause a slight modification of the optimal geometry in each potential installation site.
DA - 2025/06//
PY - 2025
PB - European Wave and Tidal Energy Conference
VL - 8
IS - 2
SP - 177
EP - 186
UR - https://marineenergyjournal.org/imej/article/view/228/114
DO - 10.36688/imej.8.177-186
LA - English
KW - Wave
KW - Oscillating Water Column
KW - Site Characterization
KW - Performance
ER -

Export Citation to RIS

Abstract

Accurate estimates of the annual energy production achievable by a given wave energy converter are essential for a robust assessment of the associated levelized cost of energy, a key factor in investment decision-making. Inaccurate productivity estimates can arise - among other factors - from uncertainties in evaluating the available wave energy resource. The Climate Data Store of the Copernicus Climate Change Service delivers projections of the wave climate along the 20 m bathymetric contours of the whole European coastlines, covering the period 2040-2100, under two Representative Concentration Pathway scenarios
(RCP4.5 and RCP8.5). This work addresses the effect of such long-term wave climate changes on the optimal sizing and performances of an Oscillating Water Column wave energy converter intended for installation along the North African and European Atlantic coastline. The capture width ratio of the device under different wave conditions is computed using an empirical model capable of predicting the device performance with acceptable accuracy and limited computational time. The results show that the optimal geometry of the OWC varies significantly in the different geographical locations and that the long-term changes in the wave energy resource could cause a slight modification of the optimal geometry in each potential installation site.

Effects of projected wave climate changes on the sizing and performance of OWCs: a focus on the Atlantic North African and European coastal waters is located in International.