is pooling its activities for circular plastics in a global program. As part of the transition to a circular economy, the company offers its customers solutions for all stages in the polymer value chain. Additives and technologies from Evonik make mechanical and
more efficient thus improving the availability of circular plastics.
Evonik will also increase the use of sustainable raw materials from circular sources in its own production processes. Overall, the company expects its global circular plastics program to generate additional sales of more than €350 million a year by 2030.
Harald Schwager, deputy chairman of Evonik's executive board, who is responsible for the innovation, said: “We have the innovative capability to create new materials cycles with fewer fossil-based feedstocks and more circular ones. We intend to utilize that potential.
Improving Recycling Efficiencies
Evonik experts are working to help recyclers significantly improve the efficiency and quality of mechanical recycling processes. For example, customized surfactants are used to make sure labels can be removed quickly without leaving residues, while defoamers simplify washing processes and dewatering agents save energy and time in subsequent drying.
Another focus is minimizing the odor of the recyclate. Specialty additives from Evonik can increase the amount of high-quality re-usable recyclate obtained by about 5 percent. Evonik aims to offer such solutions for about 400,000 metric tons of recyclable plastics by 2025.
Evonik is also working on various chemical recycling technologies for plastic waste that cannot be recycled mechanically. For example, Evonik is currently developing a process to facilitate recycling of heavily contaminated polyethylene terephthalate (PET) waste. New molecules for high-end applications can be obtained via methanolysis.
Another method of chemical recycling is controlled incineration of plastic waste to produce pyrolysis oils or synthesis gases. Evonik offers modern technologies that play a part in making these processes more efficient. Examples are additives, catalysts, and membranes for the treatment of gas. These pyrolysis oils and synthesis gases can be used as raw materials for the production of plastics.
All of these processes have one thing in common: The goal is to replace fossil-based resources such as oil wherever possible, avoid waste, and minimize carbon dioxide emissions.