RUNE is short for - Reducing Uncertainty of Near-shore wind resource Estimates using onshore lidars. The key project aim is to reduce the uncertainty of offshore wind resources in Danish near-shore
Solid oxide electrolysis cells (SOECs) are a promising technology for energy storage and synthetic fuel production and it has a unique potential for grid regulation in the Danish power system. This
Power-to-gas (“P2G”) is an innovative and disruptive energy storage solution ideally suited for the Danish energy system. The P2G-BioCat Project is led by a consortium of highly qualified
The SmartMEA project aims to develop the next generation high temperature PEM electrodes for improved durability and performance working under SmartGrid conditions. Focus is on electrode optimization
The purpose of the project is to analyse and develop advanced filter solutions based on combinations of passive filters and active filters in wind power plants. The use of passive filters is almost
Solid oxide fuel cells (SOFCs) are an energy conversion technology that can play a key role during the transition to 100% renewable energy in Denmark. This project aims to enhance the lifetime of
The object of the PROSOFC project is to increase the robustness of the solid oxide fuel cell technology, as this is a key challenge for bringing the technology to the consumers. To achieve this we
MegaBalance is to conduct an assessment of the potential for large scale energy storage & balancing with hydrogen in Denmark in the period 2015-2050. Focus will be on central production and conversion
This project aims at improving the forecast of wind and waves for storm conditions offshore. We explore coupling strategies for the atmospheric, wave and ocean modeling using WRF (WRF-LES), MIKE 21 SW
Solid oxide electrolysis cells (SOECs) are a promising technology for energy storage or synthetic fuel production. The technology has a great potential as a grid modulator in the future Danish
The proposed project deals with the finalization of a computational model to simulate heat and mass transfer processes inside PEMFC that has been developed over the past years at the Aalborg
Proton exchange membrane (PEM) fuel cells will play a significant role in the energy systems of the future. The technology is in the process of being introduced into a number of early markets. The
An improved understanding of the main degradation issues of the PEM FC has been obtained. Single cells have been operated in excess of 10,000 hours, but with unacceptable high degradation rates. The
Solid oxide fuel cells (SOFCs) are a flexible and efficient power production technology well suited to the demands of a Smart Grid. This project will make significant progress towards smart grid ready
SOFCs improve energy usage by providing high efficiency and dynamic operation. The METSAPP project will demonstrate that metal-supported SOFCs enhance robustness and lifetime, as a strategic
Currently, individual wind turbines can estimate their possible power of during down-regulation. For large offshore wind power plants, the sum of those signals is larger than the possible power of the
Alkaline electrolysers provide the potential to store large amounts of electrical energy as hydrogen. RESelyser will enable coupling to renewable energy sources in order to stabilise future Smart
The vision of the project is to develop a durable, efficient and safe fuel cell (FC) technology, which is suitable for larger scale peak shaving systems in relation to wind mills and SMART grid
The project will develop and demonstrate a new full ceramic SOFC cell concept in a joint approach between materials and processing experts closely together with SOFC cell and stack manufacturers. The
This project utilize the wind and wave energy conversion platform, Poseidon37, for pioneering theoretical and experimental work on modeling and understanding combined floating wind and wave energy