Advanced study of the atmospheric flow Integrating REal climate conditions to enhance wind farm and wind turbine power production and increase components durability

Climate, Energy & MobilityHORIZON-RIAID: 101083716
EC Contribution
€54,249
Consortium Size
11 orgs
Start Year
2023
Summary

To deliver the future needed renewable energy capacity, wind farm developers will have to use larger turbines, at higher altitudes, explore novel geographical regions and offshore sites. Currently, wind turbines and wind farms are designed and operated considering “just” wind conditions. Consequently, the models do not take into account the physics and aerodynamics of atmospheric wind flows at high altitudes, neither how this is affected by the location, the effect of precipitation and/or sand. This reduces the expected efficiency of wind energy production, and makes hard to estimate the energy outputs, operating costs and lifespan of blades and turbines, increasing variability and the risk to investors and project developers when designing wind farms, reducing the total potential investment. Unless new sites can be identified and designed optimally, the LCOEs will start to rise as developers have to design wind farms that cannot be well predicted with conventional models.The AIRE consortium foresees precipitation and other events (clouds, sand, shear, inflow) that wind brings into the state of play to be the new key parameters for siting of wind turbines, wind farm design, component design and O&M strategies planning. AIRE will investigate solution to assess the potential impact of REAL climate conditions in different terrains, and different altitudes both onshore and offshore, gathering information from 4 experimental sites and 4 commercial wind farms.Specially AIRE will bring together researchers, blade manufacturers and utilities to create an open access knowledge hub of experimental data, develop new numerical models, build tools to design and control wind turbines and wind farms. The effectiveness of the developed tools and models will be validated using data from commercial wind farms

Consortium (11)

Project Results (14)

Source: CORDIS, the EU research results database.

Publications (7)
Copula-based joint distributions of rain and wind for leading edge erosion risk atlas
Renewable Energy· 2025DOI
Jens Visbech, Charlotte Bay Hasager, Tuhfe Göçmen, Pierre-Elouan Réthoré
High-Resolution 3D CFD Simulations of Wind Turbine Aerofoils with 3D Scanned Leading Edge Roughness
AIAA AVIATION FORUM AND ASCEND 2025· 2025DOI
Alexander Meyer Forsting, Niels N. Sørensen, Antariksh Dicholkar, Anders S. Olsen
CFD wind farm evaluation in complex terrain under free and wake induced flow conditions
Journal of Physics: Conference Series· 2024DOI
David Bretos, Guillén Campaña-Alonso, Beatriz Méndez-López, Elena Cantero-Nouqueret
Experimental campaign for the characterization of precipitation in a complex terrain site using high resolution observations
Journal of Physics: Conference Series· 2024DOI
Beatriz Méndez, Ernesto Saenz, Óscar Pires, Elena Cantero, Joan Bech, Francesc Polls, Eric Peinó, Mireia Udina, Albert Garcia-Benadí
Prediction of rain erosion damage progression using disdrometer rain data: The importance of liquid water content
Journal of Physics: Conference Series· 2024DOI
Ásta Hannesdóttir, Ebba Dellwik, Charlotte Bay Hasager
Quality assessment of the GPM IMERG product for lifetime prediction of turbine blades in complex terrain
Journal of Physics: Conference Series· 2024DOI
Krystallia Dimitriadou, Charlotte Bay Hasager, Elena Cantero Nouqueret, Ásta Hannesdóttir
Rain erosion atlas for wind turbine blades based on ERA5 and NORA3 for Scandinavia
Results in Engineering· 2024DOI
Ásta Hannesdóttir, Stephan T. Kral, Joachim Reuder, Charlotte Bay Hasager
Deliverables (6)
Other Results (1)
Periodic Reporting for period 2 - AIRE (Advanced study of the atmospheric flow Integrating REal climate conditions to enhance wind farm and wind turbine power production and increase components durability)