Projects
There are 25 results.
StraTex ‐ Sorting and processing strategies for used textiles to produce recyclable fractions
In StraTex, suitable, economically viable and holistic strategies for the collection, processing and automated sorting of mixed non‐reusable textiles are being developed and experimentally implemented in order to increase the proportion of marketable fractions for high‐quality material recycling (preferably fibre2fibre).
Sustainable catalyst-coated electrodes for efficient AEM electrolyser production (SAEP)
The SAEP project focuses on the development of anion exchange membrane electrolyzers (AEMEL) for the cost-effective production of green hydrogen through the development of catalysts without platinum group metals. Led by TU Graz, Joanneum Research, and Duramea, the project focuses on roll-to-roll scalable electrode manufacturing with enhanced performance and durability. Innovative pre-/post-treatment and energy-efficient drying methods ensure defect-free, corrosion-resistant electrodes. A life cycle analysis integrates circular economy principles to optimize resource efficiency and minimize waste, fostering sustainable and high-performance AEMEL electrode production in Austria.
UPTextIL - Upcycling cellulose from used textiles into high-strength filaments using spinning technology in ionic liquids
The aim of the project is to develop a process for spinning cellulose from used textiles using ionic liquids, to analyze potential impurities in this recycling material stream, and to develop strategies for their removal or avoidance during the spinning process. The project aims to lay the foundations for closing the material cycle of cellulose from used textiles.
Wastewater cycle. Cascadic recycling of wastewater and organic residue streams in buildings.
Basic research is being conducted for a sustainable cycle-oriented system for the building-integrated recycling of wastewater and food waste. This includes nutrient recovery for a sustainable circulation system (production of plant fertiliser and biochar), electricity production to meet the demand (up to 15 %) of plus-energy buildings, as well as water recovery for irrigation of the building's own or urban greenery and for summer cooling.
circPLAST‐mr Mechanical Recycling of Plastics: Mechanisches Recycling von Kunststoffen: From waste plastics to high‐quality and specification‐compliant recyclates
The flagship project circPLAST‐mr pursues the following 4 main objectives: (1) to identify and explore previously unused potential for mechanical plastics recycling, (2) to define and test key process steps for this on a laboratory/pilot scale, (3) to demonstrate the eco‐efficient marketability of increased recycled plastic volumes, and (4) to demonstrate the scalability of the laboratory/pilot process steps to industrial scale.