Megavind continues to support and consolidate the stronghold of the Danish wind industry through a focused and strategic vector apporach to validation, demonstration, research and education. Megavid
The overall objective of the project is to develop a prototype trailing edge flap system for a wind turbine blade. From its present stage of proven functionality under laboratory conditions it is
The objective of this project is to model and explore the influence of atmospheric stability conditions on structural loading and production losses of wind turbines operating in wind farm conditions
The Danish wave power industry has in connection with this application created a partnership that aims to initiate, strengthen and develop cooperation, and develop a comprehensive joint strategy for
The next step in the development of the Wave Dragon technology is the deployment of a full-scale device in open sea. The development of a 1.5 MW Wave Dragon demonstrator will be based on experiences
The purpose of the project is to introduce and implement a new dynamic data analysis method, DDA, in the Danish wind industry. This method is based on fast measured data rather than traditional 10min
The purpose of the project is to strengthen the Danish contribution to the International Energy Agency project 'IEA Annex 30: Offshore Comparison of Dynamic Computer Codes and Models' with an
The purpose of the projekct is to duce cost of energy in the design, production, transport, installation and maintenance of monopile foundations for large offshore wind turbines. The primary goal is
The purpose of the project is to improve and validate newly developed models for simulation and prediction of wind power fluctuations, by integrating the tools with meteorological tools for wind
The objective of this project is on basis of simple measurements on 6 turbine towers in the Rødsand 2 wind farm to identify, model and verify the basic mechanisms driving the increased loading
Establishment of a data base of O&M data for Wave Dragon established in Nissum Bredning. Large uncertainty exists about fatigue impact on single components used in a wave device caused by repeated
Waveenergyfyn v/ Henning Pilgaard
ForskEL
2010
2011
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New command and control mechanisms are to prevent wind power from destabilising the power grid. This is an important prerequisite for meeting the goals of 42 pct. wind share for 2020.
The proposed project will investigate a new wind power system, includiing a direct drive low speed Switched Reluctance Generator (DL-SRG) and a DC network connecting the DL-SRGs. It is expected that
By collaboration between Danish and Chinese experts in wind turbine aerodynamics, optimisation and control, and atmospheric turbulence, aim is to develop an integrated apporach, which provides
The goal of this project is to create a scientific basis for the development of advanced, strong materials for wind blades by optimising their structures at microlevel. This goal is achieved by
Wind turbine components such as gears and naves are exposed to large and very dynamic loads. The typical modes of production have difficulties handling this. REWIND focuses on materials, processes
The project aims to optimise existing solutions to the yaw mechanism for wind turbines, improve properties with regard to noise, fatigue and peak load, wear and service.
DEXA1:5 is a development project which aims to use an innovative, simple and flexible technology to validate wave energy as a cost-effective, competitive source of electrical power. Activities defined