The mission of the project is to radically improve integration of wind energy in the power grid through effective coordination of both electricity generation and consumption. Specifically, the project
In this project, an integrated biorefinery concept will be developed for conversion of two carefully selected (based on their sugar and amino acid composition) candidates of brown macroalgae, into
Sustainable production promoting jobs, growth, improved environment and less pollution – new technology aims at the markets for advanced processing and supply of biomass to fuels and chemicals.
Ammonia can be used for cleaning the exhaust from diesel cars as well as fuel for fuel cells. Safe storage of the ammonia is important in both applications.
A new ceramic membrane that can desalinate seawater, can solve lack of drinking water. The ceramic membrane is robust and energy efficient and provides high-efficient filtration.
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 power and other variable production constitute a significant share of a future renewable energy system. This requires flexible and intelligent solutions. IPOWER focuses on flexible electricity
We propose to further the availability of high quality bio-oils for transportation and energy use. The focus is on locally available biomass resources, in Denmark and China, and the selection of
Maritime diesel engines emit vast amounts of harmful substances. A reduction takes better knowledge of emission formation inside engines. RADIADE advances further the theoretical models of large