European Scalable Complementary Offshore Renewable Energy Sources

In the H-2020 green deal project EU-SCORES three key challenges are addressed via the demonstration of the combination of offshore wind with wave- and offshore solar energy.

1) Challenge to maintain a reliable energy system: The main challenge for a 100% renewable energy system is to balance supply and demand at all times to ensure security of power delivery.
2) Challenge to deal with limitations in space: Some of the best locations for onshore wind and onshore solar installations in Europe are already taken or are under high competition. The required increase in offshore capacity will lead to more pressure on other stakeholders and environmental protected areas, endangering public acceptance and the health of Europe’s oceans.
3) Challenge to maintain favourable business cases for renewable energy: Future business cases are less favourable as costs for bulk energy storage are high, negative prices during peak wind times are expected and the best locations are occupied or are shadowing each other. Other offshore renewables (wave, offshore solar and tidal) are not yet being deployed on a larger scale because of technical and financial risks based on the current TRL.

Offshore solar and wave energy converters are demonstrated on a MW scale. The obtained data is used to give advice to policy makers and design credible business cases for the upscaling of those technologies inside offshore wind parks. This allows for removing technical, financial and regulatory risks. Altogether this will pave the way for bankable offshore multi-source energy parks across Europe by 2025 and beyond. These multi-source parks will use offshore space more efficiently and balance the electricity grid to achieve a resilient and cost-effective 100% renewable energy system.

- Kick-off of 100% (47/47) of the project tasks and submission of 68% (52/77) of EU-SCORES deliverables throughout the project (first to third reporting periods).
- Consortium-wide GO decision after RP1 and agreement to extend the project by 18 months
- Laying the foundations on the technical and financial engineering for multi-source parks (basic Operation & Maintenance model, Financial Design model, Park output model, Resource model, Market price models).
- Proving CPO’s ocean cycle: Deploying CPO’s first full-scale WEC C4 in Agucadoura and proven survivability in four major storms between August and November 2023. Successful decommissioning, planned maintenance and redeployment.
- OOE receiving DNV’s Statement of Conformity for the Basis of Design of their offshore solar solution.
- In-port deployment of OOE’s offshore solar platform for 9 months and successful decommissioning.
- Increase in ambition by changing deployment site for offshore solar demonstrator from the Blue Accelerator test site to the Belwind operational wind farm in Belgium.
- Publication of 21 EU-SCORES scientific articles, 12 conference papers and several posters.
- Received media attention in Offshore-Biz, National Geographic Portugal, Der Spiegel, Portugal’s “Rádio e Televisão de Portugal”, Germany’s radio station Deutschlandfunk a.o.
- Presenting the project in more than 93 events.
- Set up interactive experiences to showcase the benefits of multi-source energy parks to various stakeholders: VR glasses, ‘water tank’ showing a multi-source energy park. Three stakeholder events including Policy Summits were held, with EU and national policymakers representation.
- Successful meetings with policy makers in various countries on multi-source parks (CL, US, NO, NL, DE, IT, DK, PT, BE, IE).

Impact I - reliable and low-cost energy system.
A case study of the planned Dutch wind farm Ten Noorden van de Waddeneilanden, which was modelled as a multi-source park with offshore wind, wave and offshore solar energy, results in an increase of 21% of exported electricity. Compared to a wind-only scenario, the multi-source park could shorten the longest period of exported electricity below 20% of the export cable capacity from 6 consecutive days to 1.5 days. A continuous power output makes it possible to match supply and demand at any time, thereby providing a higher value for industrial processes, energy service providers and the production of green hydrogen. A case study of a combined wind-wave farm off the Portuguese coast shows that 42-56% reduction in LCOH could be observed. Energy system analyses of the EU showed that electricity storage requirements could be decreased by 2.3% in a best-policy scenario with high ORE. For Iberia, the effect was even stronger reaching a reduction in electricity storage requirements of 11% by 2050. The combined deployment of ORE reduces reliance on large-scale energy storage and grid reinforcement by smoothing temporal and spatial variability in electricity generation. Increased electricity availability throughout the year implies less reliance on long-term fuel storage and balance, reduced operational uncertainties, and increased security of supply in a system dominated by variable renewable energy. Learning rate models show that the LCOE of ORE could decrease substantially until 2050 given an expansion of deployed capacity. This makes the EU energy system more reliable and affordable.

Impact II - efficient and sustainable use of available offshore space.
During the three Policy Summits about maritime spatial planning, permitting, and subsidies that took place in January 2023 (The Hague), July 2024 (Brussels) and July 2025 (Porto), and other (bilateral) consultations, DG ENER, DG ENV, DG MARE and DG RTD and ministries and policymakers from the following countries were reached: Belgium, Ireland, Germany, France, Portugal, Spain, Netherlands, UK. Advisory guidelines for 8 countries (BE, IE, IT, DE, FR, NL, PT, UK) have been published about optimal tender design and permitting processes and documents about MSP and subsidies are close to completion.
Combining offshore wind with offshore solar and wave energy can increase the extracted energy density by 22%, as demonstrated in a case study in the Dutch North Sea. To achieve the same annual exported electricity as the wind-only farm, the multi-source farm would require about 18% less space. Environmental impact assessments at the demonstration sites are evaluating the impact of offshore solar and wave energy systems co-located with offshore wind on the natural habitats.

Impact III - improved business case and increased investment incentive.
OOE achieved the first DNV Statement of Conformity for an offshore solar system and installed a monitored PV-system in the Port of Ostend in May 2024. The system has been operational for 9 months.
CPO demonstrated its first complete ocean cycle, from installation and commissioning over testing to retrieval and on-land upgrades. The deployment of the first full-scale C4 showed better than expected performance data increasing the theoretical annual expected electricity production per next generation device.
A study on the techno-financials of a planned Dutch wind park provides insights in the cost reductions for a North Sea specific case. It shows CAPEX reductions per MW 7-29% when integrating both offshore solar and wave energy.
Based on a future electricity market model for the Netherlands, revenues in 2030 for offshore solar-wave-wind parks are expected to increase by 31%. In 2050, the increase in revenue will be slightly slower at 28%.