The objective of this project is to demonstrate that a system for biological cleaning industrial wastewater placed on the seabed is technically, operationally and economically viable to achieve zero
The aim of the project is to participate in IEA Hydrogen TCP, in order to stimulate hydrogen R&D activities in Denmark and to co-ordinate Danish and international scientific work on hydrogen and
SaltPower will partielpate in IEA Hydrogen TCP Task 42 with knowledge about energy efficiency in building new caverns for storage of hydrogen in the future. We will work with ether partners to develop
The overall objective of the eSAF-AAL project is to fast-track the development and demonstration of a very promising technology that converts raw e-methanol (undistilled) to Sustainable Aviation Fuel
The overall objective of the H2-BOOST project is to improve the efficiency of alkaline electrolyser technologies by min. 10%. By using a novel patent-pending in-situ electrode activation method, it
The purpose of the project is to conduct a field demonstration of a 0.15 MW dynamic electrolyser unit. The demonstration will be used for further scaling DynElectro’s dynamic electrolyser technology
The goal of the FC-COGEN project is to demonstrate e methanol-based fuel cell system that can generate both heat and electricity for residential and industrial application. The solution will ulti
Hydrogen is envisioned to become a key enabler and energy carrier in the future 100% renewable energy system with predicted applications within transportation, grid stability, industry, re
HT-PEMFC with Danish industry in the lead is on the threshold of market entry and consortium partners are committed to establish a production line of cell components at a production rate of 1
Hydrogen is envisioned to become a key energy carrier in the future 100% renewable energy system with predicted applications within transportation, grid stability, industry, re
The starting point of the project is DTU’s development of a phosphate solid hydrogen ion conducting membrane which is “ionic-protonic-superconducting” in the temperature range 230 – 350 °C
The scope of the project is to recycle high value precious metal catalyst and polymer components from HT-PEMFC MEAs, implement inhouse MEA production using alternative components and test the
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