The objective of BLATIGUE-2 is to develop fast and efficient fatigue testing methods for large wind turbine blades, to develop smart equipment to excite the blades under such tests and to increase
The purpose of the project is to increase the liability of blades in operation by installing RTZ Solution. Further, the purpose is to reach higher cost efficiency and higher AEP for the wind turbine
Fatigue of fiber rope is crane applications is not well established, why extensive full-scale testing is currently required for using fiber ropes in crane applications. The main objective of this
LERCat enables leading edge roughness (LER) repairs of wind turbine blades at the right time, yielding a 1 bn DKK/year gain across the partners’ turbine fleets. This is achieved by establishing an
The project involves the development and maturement of a drone charging station and a drone system. The combined system should then be capable of conducting autonomous wind turbine inspections and
Managing offshore corrosion is a subject that is heavily regulated and combined with several industry standards that must be followed to ensure the structure integrity of the assets. Yet, whilst, and
The purpose of IDEA is to establish reference site conditions and wind reference wind farm designs for floating wind turbines. The project follows the international IEA project on wind farm design and
The overall objective of this project is to further adapt, improve and expand the existing operational tracking technology that Claviate has developed to cover the entire onshore wind turbine
We aim to demonstrate that a radically new blade technology combining jointed modular blades with advanced tips made with additive manufacturing can enable increased rotor sizes by up to 20% and lead
The annex will give the participants an overview of the technical and environmental assessment challenges encountered in offshore applications and help them to understand the areas of further R and D
The project included the second phase of a process aimed at establishing a platform for wind turbine simulation as a prerequisite for advanced electrical design and optimisation.
The aim of the project is to develop, verify and implement a detailed physical model for the wind field in a wind farm. The model will allow for detailed aeroelastic simulation of wind turbines sited
The overall objective of the project is to ensure the development of an aetoelastic design complex, which can create the basis for the nest generation of wind turbines and make new design trends
This project, HAVDIM2004, aimed primarily at analysing already accessible measurement data from the two Danish offshore wind farms Horns Rev 1 and Nysted Offshore Wind Farm. The project focused on
The project generated results in selected areas of flexible multibody wind turbine modelling. Monte Carlo statistical response simulations and failure probabilities require significantly reduced
In DTU's and LM Wind Power's wind tunnel, the project performed several measurements of the flow behind vortex generators (VG). The project proved that the induced vortices effectively counteract
The project aimed substantially to strenghten the scientific basis for the wind turbine sector in general with particular focus on the Danish sector’s position in offshore wind farms. To meet these
This project demonstrated that further improvement and automation of wind power predictions within a 48-hour horizon is possible if the underlying tools such as WPPT (Wind Power Prediction Tool)