We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Mechanical recycling of printed flexible plastic packaging: The role of binders and pigments
Summary
Researchers investigated how specific ink components, including pigments and binders, affect the quality of mechanically recycled low-density polyethylene flexible packaging. They found that nitrocellulose binder degraded during reprocessing, causing discoloration and releasing potentially odorous compounds, while pigment particles reduced the recycled film's durability. The study highlights that printed inks are a significant barrier to producing high-quality recycled plastic from post-consumer packaging waste.
Low-density polyethylene (LDPE), extensively employed in flexible plastic packaging, often undergoes printing with inks. However, during the mechanical recycling of post-consumer waste, these inks act as contaminants, subsequently compromising the quality and usability of recycled material. To understand better exactly which ink components cause which effects, this study comprehensively assesses the thermal behavior of three organic pigments and two commonly utilised binders, correlated with the impact on the mechanical recycling of LDPE-based flexible plastic packaging. In this regard, the study focuses on four pivotal factors: processability, mechanical properties, aesthetic attributes, and volatile organic compound profiles. The results indicate that nitrocellulose, used as a binder, degrades during reprocessing, resulting in film discoloration and the emission of potentially odorous compounds. Conversely, pigments are found to be dispersed within droplets of polyurethane binder in LDPE recyclates, whilst reprocessing printed samples detrimentally affects film properties, notably dart drop impact resistance, strain at break, and the number of inclusions. Additionally, it is shown that both inks comprise components that emit volatile compounds during reprocessing: non-thermally stable components, nitrocellulose and pigment yellow PY13, as well as low-molecular weight molecules from polyurethane and by-products from wax, plasticisers, and additives.
Sign in to start a discussion.
More Papers Like This
Material Characterizations of the Polymers Reinforced with Recycled Flexible Plastic Blends as Filament for 3D Printing
Researchers characterized polymer blends made from recycled flexible plastics mixed with high-density polyethylene and polypropylene for use as 3D printing filaments. The study found that incorporating recycled plastic into filament materials is technically feasible, offering a potential pathway to reduce plastic waste by converting single-use plastics into useful manufacturing materials.
Towards Sustainable Food Packaging: Mechanical Recycling Effects on Thermochromic Polymers Performance
Researchers examined how mechanical recycling affects the thermochromic properties and structural integrity of food packaging materials, finding that repeated recycling cycles degraded color-change performance and increased microplastic shedding from recycled packaging.
Mechanical Properties of Polymers Recovered from Multilayer Food Packaging by Nitric Acid
This study examined the delamination and polymer recovery process for multilayer food packaging waste using nitric acid, finding that the recovered polymers retained mechanical properties close to virgin material, supporting the technical feasibility of multilayer packaging recycling.
Polypropylene Contamination in Post-Consumer Polyolefin Waste: Characterisation, Consequences and Compatibilisation
Researchers characterized polypropylene contamination in post-consumer polyolefin plastic waste, finding that heterogeneous contaminants significantly compromise recycled material properties and examined compatibilisation strategies to improve recycling outcomes.
Assessment of the Impact of Superficial Contamination and Thermo-Oxidative Degradation on the Properties of Post-Consumer Recycled Polypropylene
This study investigated how surface contamination and thermo-oxidative degradation during repeated use affect the mechanical and chemical properties of post-consumer recycled polypropylene, finding that these degradation processes significantly reduce material quality and pose challenges for achieving high-quality recycled plastic products.