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BATTBOX - BATTeryrecycling Best Operations by X-processes for circular battery ecosystem
In the BATTBOX project, e-mobility traction batteries are analysed for their cycle capability. The design and structure of battery systems are examined and evaluated regarding potential hazards. Based on this, the best possible handling and processing procedures are developed to improve and optimize the product life cycle regarding safety and recyclability.
BitKOIN - CO2-reduced binding agent through thermochemical conversion of mineral wool waste combinations
In the BitKOIN project, conceptual, experimental and model research activities are conducted in order to develop a substitute material for ground-granulated blast furnace slag (GGBS). First, mineral wool waste and other mineral residues, which are required as additives to achieve the desired chemistry, are sampled representatively. The materials are then characterized chemically, mineralogically and physically and are additionally classified according to waste regulations. By thermochemical conditioning of the mineral wool waste, combined with the other waste materials, the "Huettensand 2.0" (GGBS 2.0) is developed. The project aims to develop the "Huettensand 2.0" , a durable GGBS substitute.
CycLR - Paint recycling and utilization of components
The CycLR project aims to implement a circular economy for water-based paints. A recycling process that enables the valorisation of recyclates is being developed, taking into account all parties involved in the value chain.
DeB-AT – Detection and separation of portable batteries from mixed waste using sensor technology and artificial intelligence
The DeB-AT project plans the development of a laboratory or pilot plant demonstrator for the targeted separation of batteries from mixed waste streams. The concept of the demonstrator follows the methodological elaboration of the necessary requirements of optical sensors and the separation technology for AI-supported detection of the general population of batteries.
DiRecT – Direct recycling and upcycling of titanium chips
In the project DiRecT, different new technologies will be developed and evaluated which make it possible to directly recycle the chips generated in the manufacturing process of high-quality titanium products or to produce directly from the chips near-net-shape components or improved semi-finished products (upcycling).
EPSolutely - Development of a circular economy concept in the plastics industry using the example of EPS
In a system-wide cooperation of all relevant actors of the EPS value chain system, concepts, technologies and methods for an EPS circular economy are developed. The integration into an overall concept with optimised logistics and transport systems should enable the transformation of linear EPS value creation systems into a circular economy.
MeteoR – mechanical-thermochemical process combinations for the recycling of fine fractions from waste treatment facilities
In waste treatment plants large quantities of fine fractions are generated. Due to their heterogeneity and properties, these fractions are currently not used although they contain a whole range of materials that represent valuable resources. The aim of the project MeteoR is to enable the utilization of all components (mineral, metallic, and combustible) of fine fractions by combining mechanical and thermochemical processes, to close material cycles and to significantly contribute to the further development of the Austrian circular economy and the reduction of CO2 emissions.
NaKaReMa - Improving the sustainability of cable sheathing through regional, bio-based and recycled materials
The NaKaReMa project takes a holistic approach to cable sheathing for automotive applications and their improvement in terms of sustainability. To this end, various approaches are being investigated - both regional raw material sources to reduce transport routes and bio-based raw materials to reduce dependence on crude oil. The use of recyclates from cable sheathing to close the cycle through recycling is also being investigated.
PET2More - Biotechnological upcycling of PET plastic waste as a contribution to the gradual reduction of petroleum-based raw material dependency
The aim of the PET2More project is to develop a biotechnological process for upcycling PET plastic monomer waste. To this end, previously unknown and unavailable decarboxylase enzymes for the conversion of terephthalic acid and 2,5-furandicarboxylic acid into valuable chemicals such as benzoic acid and furan-2-carboxylic acid are to be identified, characterized and optimized by means of enzyme engineering.
PVReValue – Holistic recycling of photovoltaic modules
The PVReValue research project is pursuing a new approach to the holistic recycling of photovoltaic modules, based on an innovative multi-stage composite separation process that is being developed in the course of the project. The multi-stage separation process and the novel combination of modern treatment processes are expected to achieve a recycling rate of more than 95 wt.-%.
PolyBacTex - Converting mixed textile waste into recycled fibres and cellulose for sustainable production
The project PolyBacTex is developing a solution for recycling of used mixed textiles by chemically separating and biotechnologically upgrading the individual fibre types (cellulose and polyester). This allows cellulose fibres to be recovered and returned to the fibre production process.
Pyrolysis technologies in Europe
Technology overview of medium-fast pyrolysis for decentralised applications, for small and medium-sized enterprises and for the circular economy
Road-to-Road/ Verschränkung neuartiger Methoden zur effizienten „Road-to-Road“ Inwertsetzung von Altasphalt
The planned combination of experimental and model-based methods for assessing/describing the behavior of asphalt shall enable the goal-oriented optimization of the performance/durability of recycled asphalt, with the resulting positive effects (CO2 balance, transport distances, landfill volume) being quantified within the project.
SHyRE - Sulfuric acid and hydrogen production for the electronics industry through innovative recycling
In SHyRE, an innovative process for sulfuric acid recycling is being developed. The aim is to efficiently produce high-purity sulfuric acid and hydrogen by combining novel decomposition processes with electrochemical methods.
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).
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.