1. Technology developments and R&D landscape:�Research overview from Ris
2. Wind Energy Division - Ris DTU�Technical University of Denmark
3. Wind Energy Roadmap in the EC Communication of Financing Low Carbon Technologies.
4. Research, development and demonstration challenges Danish MEGAVIND strategy
8. Wind Energy Division - Ris DTU�Technical University of Denmark
9. Ris DTU Offshore Wind Energy R&D priorities Marine wind, wave and current conditions
Characterize the geophysical processes,estimate local conditions and develop design basis
Wakes in offshore wind turbine farms
Characterize and model wakes (performance and loads) in relation to interaction between turbines, between farms and large scale climate effects
Installation and maintenance
Methods, models and tools to support installation and maintenance incl. Wind wave prediction, remedial and preventive maintenance and condition monitoring
Integrated design tools
Integrated aero-hydro-servo-elastic tools incl. wave loads,soil-structure and fluid-structure interaction
Offshore wind integration
Models and tools for design and control of offshore grid and clusters
New concepts
10. Offshore Wind Conditions Ocean winds
Lidar observations and modelling
Wind resource mapping using satellite data
Mesoscale modelling
Meteorological mast observations
Wind farms shadow effect
Satellite observations
11. Horns Rev offshore site
12. Wind loads dominated by wake effects
13. Fuga a new, linearized wake model
Solves linearised RANS equations
Closure: mixing length, k-e or simple (nt=ku*z)
Fast, mixed-spectral solver using pre-calculated look-up tables (LUTs)
No computational grid, no numerical diffusion, no spurious mean pressure gradients
Integration with WAsP: import of wind climate and turbine data.
105 times faster than conventional CFD!
14. User friendly GUI
15. Validation: Horns Rev I.
16. Validation: Nysted.
17. Downwind Speed Recovery FUGA - predicts a much slower speed recovery than standard wake models.
For HR rec.distance is about 16 km; somewhat slower than observed 4)
18. Design of offshore wind turbines Offshore wind turbines are not onshore wind turbines!
hydrodynamic loads, sea ice, long periods at standby
Offshore wind turbines are not oil rigs!
wind loads, shallow water, dynamics, unmanned
Marriage of expertise from wind power and offshore engineering industries
Technology Risks
Improve confidence with which offshore wind farms can be financed and implemented
19. Standards for Offshore Wind Turbines Onshore wind turbines
IEC 61400-1, Edition 3
Offshore wind turbines
IEC 61400-3
GL Regulations for Offshore WECS, 1995
DNV, Design of Offshore Wind Turbine Structures, OS-J101, 2007
GL Wind, Guideline for the Certification of Offshore Wind Turbines, 2005
Offshore structures petroleum and natural gas industries
ISO 19900, General Requirements for Offshore Structures, 2002
ISO 19901, Specific Requirements for Offshore Structures, 2003
ISO 19902, Fixed Steel Offshore Structures, 2004 (DIS)
ISO 19903, Fixed Concrete Offshore Structures, 2004 (DIS)
20. Walney Offshore Wind Farm Project
21. EUDP Walney Offshore Wind Farm Project Measurements:
Nacelle mounted LIDAR measuring wind speed at 2.5 rotor diameter in front of turbine.
Wave and current measurements near foundation
22. Benefits from the project and its need Maturity of loads prediction on offshore wind turbines, both on the support structure, as well as rotor nacelle.
Provides offshore turbine loads data for research purposes.
Provides for correlated wind and wave measurements for each load data point.
One of the very few nacelle mounted LIDARs for offshore wind turbines with accurate wind measurements
Cost effective foundations.
Improved accuracy for site specific loads prediction
Estimation of damping of the structure to mitigate fatigue and extreme loads
Long term loads on the foundations
Fatigue and ultimate strength requirement evaluations
Enables improved life prediction
23. DEEPWIND New EU Funded Program
24. Combined floating wind- and wave energy converter Poseidon Experiment
25. Poseidon: Modeling Challenges � Ris Hawc2 Overview Three rotors in one simulation
Structural modeling already possible in the multi-body formulation
Aerodynamic model updated to handle this
Wake from upwind rotors
Already possible with the dynamic wake meandering model in HAWC2
26. The development of offshore wind energy depends not only on industrial development and demonstration but also on medium to long term research
Site conditions very complex the site specific design conditions are derived in an ad-hoc and pragmatic way
Integrated design tools exist but are primarily used to demonstrate conservatism of approach
Limited validation of design loads and response
Deep water (> 30 m) is a challenge
Deep water concepts under way
Offshore wind is just at the beginning all options are open Conclusions
