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
The overall aim of the project was to extend our knowledge on bioethanol production to foreign biomasses which has major potential for export of bioethanol technologies.
The project dealt with many aspects of the interplay between wood burning, user and the environment. It conducted a series of surveys on health effects of firewood smoke particles.
The main goal of the project was to achieve improved understanding of the interaction between cell-wall-degenerating enzymes and lignocellulose at increased solid matter content. Pre-treatment of
The project developed an econometric model capable of predicting car model combination of new car sales, including in particular cars using fuels produced with renewable energy, i.e. electric cars
OPUS will study bio-available carbon in sraw from wheat. The project applies a multidisciplinary structure compriing expertise in molecular biology, plant breeding, 'white biotechnology'
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
The project follows up four previous projects on biofuels and health and safety at work and focuses on: 1. Method development for airborne dust capture to study any health effects of biofuel dust. 2
The project focused on improving the Open Core gasification unit, particularly reducing the daily monitoring jobs and ensuring stable, unmanned unit operation. A subproject focused on gaining better