Investigative study of Biopolymer contamination in conventional recycling systems

Abstract: The recycling industry which is efficiently functioning now has technical expertise, contented consumers, and resource availability and capital contributors. The potential inflow of new material into this existing system should be able to fulfill all the needs of the stakeholders involved in it. With most of the polymer wastes received from the polyethylene (PE) and polyethylene terephthalate (PET), they are available in abundant crossing the threshold quantity (Cornell, 2007) needed for the recycling process to be carried for every single polymer starting from the individual source separation till the granulation of pellets with active investment for the potential expectancy of returns in the recycling market targeting suitable consumers. Unlike other polymers like polyvinyl chloride and polypropylene (PP), biopolymers fail to fulfill the necessary criteria of being in threshold quantity to carry out the recycling process. With the very small inflow of biopolymers in the recycling industry, standalone recycling units for the same is not highly performed and appreciated. In addition to this, there are possible means and ways of the biopolymers getting infused into the conventional petrochemical polymers either through the mis-throws in manual sorting or in automated sorting. Though the studies so far don't have any substantial threatening effect over the biopolymer infusion, still it has its adversity affecting the industry by other means. The volumes of biopolymers are presently small and contamination of biopolymer in the plastic waste stream is presently not a problem. However, with increasing volumes of biopolymers, this can be a problem. Contamination could then be a future problem. This study investigates that problem and checks the truth to the claims of biopolymer infusion in the conventional post-consumer recycling systems affecting the quality of the recyclates. In order to investigate this, a biodegradable biopolymer (TPS & PHA) will be mixed into a conventional polymer (PE, PP, PET) at various percentages. The mechanical and thermal properties are then measured as a function of the percentage biopolymer. In a second part of the project, the blend of conventional plastics and bioplastic is conditioned in humidity in order to simulate what will happen to a conventional polymer that has been contaminated with a biopolymer in a humid climate.