• Title of article

    Properties and printability of compression moulded recycled polyethylene

  • Author/Authors

    Barbara Ti?ler-Korljan، نويسنده , , Diana Gregor-Svetec، نويسنده ,

  • Issue Information
    ماهنامه با شماره پیاپی سال 2014
  • Pages
    8
  • From page
    583
  • To page
    590
  • Abstract
    The goal of the research was the determination of the properties and printability of polymeric materials made from the recycled polymers, low-density polyethylene (LDPE) and high-density polyethylene (HDPE). From the primary (virgin) polymers and secondary (recycled) polymers that were obtained from the separately collected fractions of waste packaging, compression moulded plates were produced. The tensile properties of 1 mm and 2 mm thin plates were correlated with some structural characteristics: melting point, melting enthalpy and crystallinity degree. It was determined that the recycling process changes the melting behaviour, lowers the crystallinity and to some extent influences the tensile properties of plates. LDPE and HDPE compression moulded plates were printed with the UV inks on the large format digital UV inkjet printer Océ Arizona. To investigate the printability of plates made from the recycled materials some of their surface properties were determined. Higher optical density, area of ink coverage and dot gain of the printed HDPE plates compared to the LDPE plates are the consequence of higher roughness, higher surface energy with prevailing part of the polar component. By adding 4% of coloured master batch to the recycled polymer at moulding, the uniformity of colour is improved leading to the higher print quality. The results have shown that the digital UV inkjet printing technique could be applied for printing recycled polyethylene plastic materials, used for disposable low cost packaging products.
  • Keywords
    Polyethylene , Printability , UV inkjet prints , Print quality , Recycling , Tensile properties
  • Journal title
    Materials and Design
  • Serial Year
    2014
  • Journal title
    Materials and Design
  • Record number

    1073952