Projects in the Thematic Area

There are 54 results.

Ressourcenwende

LightCycle

Fiber-reinforced thermoplastic composite components with low weight, so-called lightweight components for transport and mobility, lead to significant CO2 savings. Despite established production technologies and weight savings, further progress in lightweight construction is increasingly difficult because the sustainability of these products is currently not given due to the unresolved recycling problem, although the regulations require, among other things, 85 % recycling of an end-of-life vehicle.

Ressourcenwende

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.

Ressourcenwende

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.

Ressourcenwende

BuildReUse ‐ 100 percent re‐use and recycling in buildings with short usage cycles

Some buildings, such as supermarkets or office buildings, are often demolished and rebuilt after a few years or at least have their interiors changed, turning large quantities of building components into waste. The BuildReUse project aims to develop circular economy concepts for these buildings and to promote the necessary change in the construction industry.

Ressourcenwende

QB3R – Quality controlled high‐performance components consisting of 100% bio‐based resins with high potential in repair and recycling

The QB3R project aims to develop an epoxy resin system having a 100% bio‐based carbon content. The QB3R resin will be processable with various different manufacturing techniques resulting in high performance components for long‐lasting material goods.

Ressourcenwende

Business model innovations for rental and service models in the manufacturing sector

The project aims to contribute to a better understanding of the economic and ecological potentials of an implementation of lending and service models in the manufacturing sector in Austria and to show which changes and R&D efforts are necessary so that these can be realized by suitable business models.

Ressourcenwende

IRONER - Potential for innovative and sustainable recycling of steel

Within the framework of the IRONER project, open questions were identified and the necessary innovations for increased steel recycling were developed. In addition to a material flow analysis, stakeholder interviews and ecological and economic considerations, the influences of increased steel recycling on metallurgical processes and material properties of steel products were examined.

Ressourcenwende

CE4ALL – Circular economy for all – Incentives, enablers and inhibitors for sustainable consumption

Based on an analysis of current milieu-specific consumption behavior, the CE4ALL project aims to identify sector-specific incentives and enablers for strengthening the circular economy and to uncover inhibitors. Another focus of this work is the consideration of inclusion aspects. CE4ALL is working on a consumption-centered investigation beyond the previously production-oriented considerations of the circular economy.

Ressourcenwende

DigiTech4CE - Digital key technologies for circular production

DigitTech4CE analysed industrial cycles in discrete, digitalised production; their participants, advantages/disadvantages and framework conditions, as well as the key digital technologies required. Fields of action were developed, according to the needs of Austrian industry. Recommendations for action serve the development of sustainable, Austrian production that builds and expands competitiveness through circular innovations.

Ressourcenwende

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.

Nachhaltig Wirtschaften

Scenarios for the Biobased Industry in Austria

In order to support the implementation of the Austrian Bioeconomy Strategy, three scenarios for the bio-based industry in Austria were developed. The present study is intended to serve as a solid overview and as a starting point for further detailed studies by other researchers.

Nachhaltig Wirtschaften

Secondary Phosphorus as Raw Material for the Chemical Industry

Recycling of Phosphorus as Contribution to the Security of Supply of Bioeconomy

Nachhaltig Wirtschaften

Biobased Plastics Scenario 2050 - plastics made from renewable resources

A “2050 scenario - plastics made from renewable resources (bio-based plastics)” has been developed. The hypothetical target of this scenario is for bio-based plastics to have a 100 % market share of product manufacturing in the EU. The scenario provides the basis for further national RTI activities and for recommendations for regulation.

Nachhaltig Wirtschaften

Bio-based substitution of fossil raw materials and products

To support the bio-based substitution of fossil raw materials and products, the fossil material flows in Austria for the reference year 2015 were collected and analysed. Furthermore, a broad bio-based technology research was part of the present study.