Projects

There are 8 results.

Ressourcenwende

AI-driven decontamination technologies for repurpose/recycle to meet food-contact regulations using light (Light-AIClean)

The project aims to develop a chemometrics-assisted decontamination (DC) process for waste plastic with AI-driven quality control and a renewable energy-based DC technology. By utilizing visible light and a reusable catalytic system, it seeks to replace resource-intensive methods like hot water washing and gamma irradiation. AI techniques, including neural networks and reinforcement learning, will optimize efficiency, reducing resource use. The process will be tested in a photoreactor and automated DC setup, benefiting the recycling industry, AI developers, and environmental sustainability while promoting circular economy principles.

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.

Ressourcenwende

CircuPack - Recyclable materials for food packaging with a low ecological footprint

The goal of the project is to develop sustainable and environmentally friendly food packaging with an improved ecological footprint. It is important to develop a new process control that ensures both food compatibility and the sustainability of the resulting product.

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

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.

Ressourcenwende

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.

Ressourcenwende

SLEEVE – Packaging and process optimisation of plastic packaging with sleeves

Development and design of selected and recyclable plastic packaging with sleeves that can be sorted and processed into high-quality recyclates. All the factors along the value chain are considered (design, consumer behaviour, sorting, recycling) in order to optimise the product cycle in the best possible way and maximise recyclate quantities and qualities.

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.