Description du projet
Améliorer les méthodes de recyclage du plastique
Le pacte vert pour l’Europe s’est fixé pour objectif de recycler 55 % des déchets d’emballages plastiques d’ici à 2030. Actuellement, seul un tiers environ est recyclé. L’un des défis du recyclage du plastique est qu’il aboutit généralement à des produits secondaires de faible qualité en raison de la cristallisation qui se produit pendant le refroidissement. En outre, la plupart des déchets plastiques contiennent des additifs, ce qui complique la détermination du gradient de température correct pour éviter la cristallisation. Financé par le programme Actions Marie Skłodowska-Curie, le projet CPW vise à étudier le processus de cristallisation en utilisant la thermographie infrarouge pour capturer le profil de température des déchets plastiques pendant l’impression 3D. À l’aide d’un logiciel mathématique, CPW analysera ce profil pour déterminer la température précise de formation des cristallites, qui pourra ensuite être régulée pendant l’impression 3D.
Objectif
Nowadays, the issue of plastic recycling has become one of the major issues of environmental protection and waste management. Since 1950, humans have produced more than 8 billion tons of plastic, of which more than half was discarded into landfills and only 9% was recycled. The majority of plastic waste stemmed from semi-crystalline polymers such PE, PP and PET. When recycled, the properties of these polymers deteriorated due to shrinkage and warpage issues related to the crystallisation process that occurred during the cooling process. The temperature gradient during cooling is able to control the crystallisation growth. However, determining the crystallization process of plastic waste during processing is difficult as generally plastic waste contains additives. Therefore, CPW uses IR thermal imaging technique as it can capture the temperature profile of plastic waste during 3D printing to study the temperature-crystallisation relationship. The existing techniques, such as hot-stage microscopy, X-ray synchrotron and in-situ light scattering, have several restrictions. Among them are non-simultaneous processes, expensive, and requiring high energy radiation sources. Furthermore, these techniques can only be applied to virgin plastic and are limited to transparent polymers that are free from additives and contamination. The captured temperature profile will be analysed using MATLAB to examine the crystallite structure at precise temperature, thus could control their properties through the processing temperature of the 3D printer. An innovative approach through experimental setup and technique used to investigate the crystallisation process will be the novelty of CPW. This research will contribute to at least four research papers with two ISI journals and two conference papers, and a patent application. The implementation of the MSCA will benefit and impact the recycling of plastic wastes in the world, and this is in line with EU’s strategy for the SDG 12 and SDG13.
Champ scientifique
- engineering and technologyenvironmental engineeringwaste managementwaste treatment processesrecycling
- natural sciencesearth and related environmental sciencesgeologymineralogycrystallography
- natural scienceschemical sciencespolymer sciences
- natural sciencesphysical sciencesopticsmicroscopy
- engineering and technologymechanical engineeringmanufacturing engineeringadditive manufacturing
Programme(s)
- HORIZON.1.2 - Marie Skłodowska-Curie Actions (MSCA) Main Programme
Régime de financement
HORIZON-TMA-MSCA-PF-EF - HORIZON TMA MSCA Postdoctoral Fellowships - European FellowshipsCoordinateur
2080 MSIDA
Malte