Dynamic and distributed ammonia plants can create new markets and demand whilst bolstering demand for existing products including turbines, ammonia plants and subsequently creating jobs for the Danish
The objective of the BlueDolphin project is to develop and demonstrate a scalable high-temperature proton-exchange membrane fuel cell range-extender platform for smaller electric marine vessels such
The project develops and demonstrates a new sensor solution for process monitoring of hydrogen in applications such as electrolysis plants. The benefits of this new sensor type include long-term
The project will demonstrate the eSmr-MeOH technology in an industrial relevant siza to enable commercialization after the project. Combined with techno economic evaluations, this will elucidate how
The goal of 3R is to develop an efficient process for environmentally friendly recovery of precious metals to make them available for reuse in fuel cells and electrolysers, which will be in great
The purpose of the project is to demonstrate how energy production from offshore wind can be utilized to produce renewable hydrogen through electrolysis in an integrated system, where the hydrogen
Decarbonization of the maritime sector is a political topic shaping regulations and restrictions for vessel emissions at sea and in ports. The political initiatives focus on CO2, SOx, NOx and particle
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
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
Danish participation in Task 32 will open new possibilities for international collaboration and access to the newest results within energy storage as hydrogen. Development of a new energy system in
The objective of the project (SIMBA) is to accelerate volume production of small environmentally friendly and energy efficient stationary fuel cell (FC) systems. With the help of reformers the SIMBA
The HighPEM project is to develop and test a high pressurized PEM electrolyser at a Hydrogen Refuelling Station in Denmark. Based on the results a R&D & commercialization Roadmap is to be formulated