Quantifying the System Benefits of Ocean Energy in the Context of Variability: A UK Example

Quantifying the System Benefits of Ocean Energy in the Context of Variability: A UK Example

Recent studies have shown benefits of using tidal stream and wave energy in the electricity generation mix to improve supply–demand balancing on annual/subannual timeframes. This paper investigates this further by considering the variability of solar photovoltaic, onshore and offshore wind, wave, an...

Full description

Saved in:
Bibliographic Details
Main Authors: Donald R. Noble, Shona Pennock, Daniel Coles, Timur Delahaye, Henry Jeffrey
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Energies
Subjects:
power system modelling
annual variability
input data sensitivity
renewable energy
wave energy
tidal stream energy
Online Access:https://www.mdpi.com/1996-1073/18/14/3717
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Recent studies have shown benefits of using tidal stream and wave energy in the electricity generation mix to improve supply–demand balancing on annual/subannual timeframes. This paper investigates this further by considering the variability of solar photovoltaic, onshore and offshore wind, wave, and tidal stream over multiple years. It also considers their ability to match with electricity demand when combined. Variability of demand and generation can have a significant impact on results. Over the sample of five years considered (2015–2019), demand varied by around 3%, and the availability of each renewable technology differed by up to 9%. This highlights the importance of considering multiple years of input data when assessing power system impacts, instead of relying on an ‘average’ year. It is also key that weather related correlations between renewable resources and with demand can be maintained in the data. Results from an economic dispatch model of Great Britain’s power system in 2030 are even more sensitive to the input data year, with costs and carbon emissions varying by up to 21% and 45%, respectively. Using wave or tidal stream as part of the future energy mix was seen to have a positive impact in all cases considered; 1 GW of wave and tidal (0.57% of total capacity) reduces annual dispatch cost by 0.2–1.3% and annual carbon emissions by 2.3–3.5%. These results lead to recommended best practises for modelling high renewable power systems, and will be of interest to modellers and policy makers.
ISSN:1996-1073

Similar Items