Newly funded M-ERA.NET project InnoCoat4Plasma from Wood K plus

BioNanoNet Association member Wood K plus is proud to join forces with INMOLD A/S (DNK), bionic surface technologies GmbH (AUT), LIST (LUX) and Peak Emulsions ApS (DNK) in the exciting project InnoCoat4Plasma.

The aim of the InnoCoat4Plasma project is to develop bio-based coatings with functional fillers that are applied using atmospheric pressure plasma technologies and improve the technological and antimicrobial properties of imprinted thermoplastic foils for microfluidic and riblet applications. The solutions are evaluated and optimized using multiscale modelling.

Fluid dynamic surfaces and coatings are in high demand in various industries such as food, cosmetics and paper production. While flow optimization is achieved by bio-mimicking structured surfaces, durable antimicrobial and hydrophilic/hydrophobic properties can only be achieved through additional coatings. This poses the challenge of addressing the sophisticated functionality of the surface appropriate to the end-use while reducing raw material use and saving energy for its application. The substitution of fossil resources, energy-efficient use and recyclability of the end products are also goals of sustainable development, the circular economy, and the European Green Deal.

InnoCoat4Plasma is based on the concept of combining bio-based coatings, recycled thermoplastic foils with imprinted micro- to nanostructures and an environmentally friendly application process with low chemical by-products and less energy consumption. Bio-based pre-polymers (e.g. from vegetable oils) and fillers from plant extracts are used to develop non-hazardous coatings. An innovative target is the plasma functionalization of particulate fillers to improve their dispersibility and compatibility to the matrix polymer. Research is being intensified by multiscale modelling of plasma processes (plasma-surface interaction, thin film formation), new nozzle designs for selective microstructuring using plasma techniques and simulation of structured surfaces in contact with various liquid media. To evaluate the potential of the developed coatings for industrial use, application trials using atmospheric pressure plasma and characterizations of the coatings are being carried out, supplemented by the production of two demonstrators.

 

The project InnoCoat4Plasma is funded as part of the funding programme Advanced Materials, M-ERA.NET Call 2024, and gratefully supported by the Austrian Research Promotion Agency (FFG-No. FO999924622), the Luxembourg National Research Fund (FNR) and the Innovation Fund Denmark (IFD).