Among the chemical degradation rout

Among the chemical degradation routes mentioned above, the
glycolysis has been widely used due to the mild conditions of the
digestion process (George and Kurian, 2014; Colomines et al.,2005; Pardal and Tersac, 2007), and the variety of monomers and
oligomers that can be obtained. One of the potential applications
of the oligoester products derived from the PET glycolysis, is their
use as plasticizers in poly(vinyl chloride) (PVC) formulations Kilinç
et al., 2005. The migration or leaching out of the conventional low
molecular weight plasticizers during the service-life of the PVC-based articles poses a huge problem; in particular, for children-care articles, biomedical and food contact packaging applications.
Thus, the oligoesters derived from PET glycolysis can partially sub-stitute the primary and/or the secondary plasticizer in a flexible
PVC formulation with the aim to reduce the migration issue thanks
to their higher compatibility with the PVC resin, thus providing an
eco-friendly material with better processing characteristic.
Several attempts have been reported in literature related with
the use of products obtained through different chemical degrada-tion routes of post-consumer PET, as secondary plasticizers for
the preparation of PVC plastisol (Kilinç et al., 2005; Íyim et al.,
2005; Soni et al., 2009; Dutt and Soni, 2013; More et al., 2014).
The general trend of reported results suggests that the use of 20%
by wt. of PET derivatives together with DEHP produces the best
performance in terms of mechanical and migrating features
(Kilinç et al., 2005) even when the derivatives obtained have not
been fully characterized to provide evidences about their physical
state (liquid or solid), chemical composition and plasticizing main
characteristics. Moreover, the performed migration test was qual-itative and without assessing the nature of migrating species.
Íyim et al. (2005) reported that the products obtained through
the alcoholysis of PET by using trimethylol propane and zinc acet-ate as catalyst are suitable as secondary plasticizer for PVC plasti-sol, although the chemical characterization of the products has not
been discussed. The degraded PET product can be used up to 40%
with respect to di-isononyl phthalate (DINP) (Íyim et al., 2005 ). A
similar application was proposed by Soni et al. (2009): hydrazine
monohydrate has been used in order to chemically degrade PET
through aminolysis in really mild conditions. A more flexible mate-rial by using 5% by wt. of terephthalic dihydrazine has been
obtained; however, the migration test has not been performed
(Soni et al., 2009). Recently, Dutt and Soni (2013) and More et al.
(2014) synthesized degraded PET products through alcoholysis
and aminolysis, respectively. The obtained plasticizers have been
characterized and their plasticization effect evaluated by mechan-ical and Differential scanning calorimetry (DSC); nevertheless,
migration test has not been performed.
The present research deals with the use of products, obtained
through controlled melt glycolysis of post-consumer PET with
diethylene glycol (DEG), as secondary plasticizers for flexible PVC
compounds. Very high PET/DEG ratios have been pursued in order
to reduce the amount of DEG (and thus to avoid an excess of
unreacted species suppressing any further and not eco-friendly
purification steps) and aiming to achieve a shorter reaction time
compatible with the use of the melt mixer machine. The degraded
post-consumer PET products have been fully characterized in
terms of chemical composition and thermal features; the one
with the most suitable characteristics has been combined with
DEHP in the PVC formulations. The final materials have been char-acterized through the main methods to assess the flexible PVC
compounds: hardness, thermal properties and migration feature
of the plasticizer.