Development of new materials for hardfacing against abrasion and hydro-abrasion with longer life and better environmental conditions than those of currently used materials.
Research and development into process arrangements to reduce the environmental impact of chemicals production.
Development of a forging and rolling technology for nickel-based alloys. Small and large crankshaft forging technologies will be optimized using numerical simulation support.
Design, develop and test an innovative integrated system to neutralise mined areas. This system will enable the position and kind of mines used to be determined with a 99% accuracy rate.
Determine the optimal use of the superconductive quantum interference device (squid)/mri in low-field nmr. The technical advantages are a simpler magnet, a convenient, low cost magnet system for use in interventional procedures.
Ledeburitic steels prepared using the rapid solidification effect, as well as those with the addition of ceramic particles, will be developed. The coating of final steel and hard materials will be investigated.
Investigation into pulsatory forming technology including generator of pulses development and description of the influence of pulses on material will be provided. This technology will be applied to industrial production.
The aim is to upgrade conventional cultivation techniques for the mass production of bacterial communities. The microorganisms will perform a cost-effective aerobic biodegradation of target xenobiotics and organic pollutants.
Creation of a platform to stimulate r&d/technology transfer dealing with laser/optics technologies/their applications, e.G. In processing industries, in order to initiate projects emphasizing cooperation between industry/r & d instititions.
Development of new antibacterial additives, fibres and textile materials designed for protection of humans against pathogenic microorganisms.