The aim of the project is to develop and implement new technology for water chemical treatment in energy systems in the power industry.
Development of a decision support system to reduce noise emission and improve energy efficiency of fans in important applications: automotive, home appliances, commercial refrigerators and air conditioning.
Research and development of a cost-effective way to re-use the process water of malting plants, in order to reduce the overall water consumption as well as the volume of pollutants, by overcoming the problem of inhibitors.
Homogeneous economic-environmental monitoring methodlogy for the study of complementarities and similarities between alternative processes (bio-methanisation and composting) by means of physical-chemical and agronomic full-scale analyses.
Development of scientifically sound and technically feasible procedures to assess human exposure to electromagnetic radiation next to mobile communications base stations to fulfil the requirements of european directives.
The project focuses on the design and development of novel catalytic composite materials for the abatement of nox produced during the combustion of fossil fuels (natural gas, coal) in stationary devices, and of n2o in nitric acid plant at either high or low temperatures.
Conception and construction of long duration self-contained breathing apparatus for emergency escapes
The long-term stability of s/s waste forms is unknown. Recovered s/s material from europe and the u.S.A. Of different ages will be used to assess stability and to predict long-term behaviour. A risk-management toolbox for improved stakeholder confidence in s/s will be constructed.
Vaccares - recovery of catalyst components from gas refineries.
Design and industrialisation of an innovative water treatment system. The system will not use salt or external chemical elements (such as chlorine), and will be as adaptable as possible and competitively priced.