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
The project developed probabilistic methods for optimum operation and planning of contemporary distribution systems, including probabilistic models for wind power, small-scale CHP plants and load. It
During the project, we developed oxygen membranes based on ion-conducting ceramics. They allow pure oxygen to be extracted from air and be used in ceramic processes.
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
It is technically possible to manage and activate the potential for flexible electricity consumption in the segment of large office blocks and public buildings. Practical experiments have shown that
The DK-SOFC b line is targeted towards: 1) decrease of the operation temperature without increasing the area specific resistance, 2) increase of the ro-bustness of the cell, 3) better understanding of
The goal of the project was to develop and demonstrate a 3 kWe DMFC generator aimed for Uninterruptible Power Supply. How-ever, a detailed concept evaluation based on the present Danish DMFC stack and
The goal of the project is to develop and test small (2 kW) reformers for converting natural gas into hydrogen for use in Proton Exchange Membrane (PEM) fuel cell cogen units for single-family houses
The project co-financed Danish participation in a European partnership under the 6th framework programme to test whether gas from thermal biomass gasification can be purified sufficiently to be used
The aim of the work is to participate in the IEA Implementing Agreement on Hydrogen (IAH), in order to stimulate and co-ordinate hydrogen activities in Denmark. The work includes: 1) Participation in
The project co-financed Danish participation in a European partnership under the 6th framework programme to test whether gas from thermal biomass gasification can be purified sufficiently to be used
The main purposes of the project were 1) to develop new catalyst materials by applying ‘flame spray deposition’ (FSD); 2) to optimise state-of-the-art MEA materials and electrode structure; 3) to