The goal of the present project was to develop new effective materials for hydrogen storage based on light elements. There are many known hydrides with higher weight percentages of hydrogen; however
The objective of the project has been to develop a compact fuel cell generator using methanol as fuel. The DMFC module will be tested as power generator for internal transport using a Mini Crosser
The purpose of the project is to further develop a Danish natural gas reformer system including optimisation of subsystems and the overall system consisting of a natural gas reformer and fuel cell CHP
The project studied the transportation in a small scale pilot grid at the research centre in Hørsholm, Denmark. The test program included steel pipes from the Danish gas transmission grid and polymer
The project objective was to optimise an LT PEM-based ìCHP and UPS system. Both IRD and Dantherm obtained significant project results. The project results regarding MEA performance, lifetime and stack
MEAs constitute the costliest key component and are also crucial to performance and lifetime of the total system. The project focused on developing basic materials and technologies for MEA improvement
One of the main results in this project is the breakthrough in the development of 2.5G cells, which are now leading in terms of performance and stability. Moreover, increased understanding of the
Methanol and ammonia based on biomass may become highly attractive in a future hydrogen system. Methanol can be produced from biomass with total efficiency of 50%. The same number cannot be reached
The aim of the HYSCENE project is to improve our understanding of the environmental impacts and related socio-cultural and welfare economic impacts of a renewable energy system where hydrogen is an
By studying the chemisorption state of hydrogen binding on the surface of nanostructured materials, the project will investigate whether hydrogen can be stored on carbonaceous materials. Experiments
The project developed a microbial fuel cell (MFC), capable of generating electricity by degrading the organic matter in wastewater. The bacteria absorb energy by extracting electrons and protons from
In the context of the project, new concepts were developed to produce proton-conducting polymer membrane fuel cells for use in a wide temperature interval over 100°C. The project synthesised new super
In this project next generation fuel cells are developed towards commercial applications. The projects is based on efficient and robust metal-based fuel cell technology.
Metal supported solid oxide fuel cells were developed for operation in temperature interval 550 – 650 degrees C. Fabrication techniques suitable for large scale production of half cells comprising of