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
The project will develop fuel cell backup power solutions for use at transformer stations in the electric grid. It will demonstrate the new backup solution in connection with transmission stations and
HyScale is to develop and demonstrate a new 3. gen hydrogen fueling station for Fuel Cell Electric Vehicles. HyScale is to double the fueling capacity and reduce costs with 50% with the aim to make
EEEHy aims to generate the knowledge that will result in the demonstration of a game- changing high temperature and pressure alkaline electrolyzer. The novel materials, electrode architecture, stack
The project continued the activities under the Danish-Canadian project on more cost-efficient second-generation fuel cell systems for the UPS markets and materials handling. In the UPS segment, a 10
Dantherm Power has produced fuel cell systems as emergency power for a large national radio network for emergency preparedness communication. A total of 117 fuel cell systems have been produced on
The project funds Danish participation in two tasks under the IEA's Hydrogen Implementing Agreement, which in addition to the EU member states counts Japan, The USA, Canada and Australia. In Denmark
Optimising the production of SOFC cells and stacks opens up possibilities for testing and demonstrating products in three market segments, distributed electricity production, micro CHP and APU
In this project, tools were developed which offer the possibility of quickly designing layers of fuel cells for various markets and uses. In addition, two reformers were developed which can convert
Experience from the CHP units in phase 2 will be put to use in the final phase of mCHP to test an additional 100 units at the premises of the two project host teams in Sønderborg and Lolland
During phase 2 of mCHP, 13 beta type CHP units with LT-PEMFC, HT-PEMFC and SOFC-type fuel cells will be tested in Sønderborg and Lolland, respectively. The project industrial team will design and
The project develops components with a new composition of materials and more cost-effective production processes for PEM fuel cells to boost performance and reduce costs. The results are demonstrated
The project focuses on developing an SOFC stack technology which is efficient under realistic operating conditions in both small and large facilities. For this purpose, a test facility, for instance