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Figure 6
Release behaviour of DEHP from PVC film at 27°C.
Figure 6
depicts the release profile of DEHP from PVC films at 27ºC. The
cumulative amount of DEHP increased linearly, showing a constant
release of plasticizer over 72 hours. This release property has an
adverse effect on plastics; as the plastic loses its plasticizer,
flexural performance decreases. Prolonged leaching also poses risk to
human health and the environment.
Figure 7
Weight loss of PVC films after extraction testing.
Figure 7 shows
the weight losses of PVC films by extraction in water. The extraction
from the resin was strongly dependent on the water solubility of the
plasticizer. The diblocks are made soluble by their MePEG components,
while the ECTO and DEHP are highly hydrophobic. Though water solubility
facilitates biodegradation, this property is not suitable for certain
PVC applications such as intravenous tubing.
Figure 8
Dimension change of PVC films at the 40% plasticizer concentration.
Figure 8
depicts dimension change with increased force for PVC plastics
containing 40% by weight of the plasticizer, with unplasticized PVC as
the control group. The unplasticized PVC had minimal dimension change
and was quite brittle. The effect of adding either DEHP, diblocks, or
ECTO was to increase the elasticity and flexibility of the films. This
was most effective by adding ECTO, which showed significant superior
performance to that of DEHP, the commercial product. PLA-MePEG was less
effective but still showed plasticizing effects.
Figure 9
Sample graph generated by TA Universal Analysis showing dimension
change for films with ECTO and DEHP at the 10% concentration.
Figure 9 shows
dimension change for samples with 10% of DEHP and ECTO. At this
concentration, ECTO samples were more flexible than those of DEHP by as
much as 700%.
Figure 10
Glass transition temperature of PVC films.
Figure 10 shows
glass transition temperature (Tg). As a general trend, an increase in
the amount of plasticizer added resulted in a lower Tg. A plastic
assumes its glass phase below its Tg and flexible phase above its Tg,
and thus a lower Tg is desirable. ECTO had the lowest Tg overall and
was the most effective alternative in lowering Tg. PCL-MePEG performed
better than DEHP in samples of 30-40%.
Figure 11
Sample graph generated by TA Universal Analysis showing calculation
of glass transition temperature for unplasticized PVC.
Figure 11 shows
the sample graph generated by the software program TA Universal
Analysis, showing calculation of glass transition temperature for
unplasticized PVC. Glass transition temperatures were derived by
calculating the point at which the slope undergoes the most dramatic
change.
DISCUSSION
Plastic samples
were tested for extraction resistance, dimension change under force,
and glass transition. For extraction resistance, it was found that
samples with ECTO showed the least weight loss after immersion in
water. The two diblocks showed the least resistance to extraction.
These are to be expected as ECTO is hydrophobic, and the two diblocks
have hydrophilic MePEG tails. The two types of plasticizers
(hydrophobic and hydrophilic) can be used in different applications.
For example, intravenous tubing and water transportation pipes require
hydrophobic plasticizers. Hydrophilic plasticizers, however, are
advantageous in that they lend themselves to biodegradation much more
so than a non-water soluble additive.
Dimension
change is likely to be the most significant test, as DEHP is primarily
used to impart flexibility to the otherwise rigid PVC polymer. From our
tests it was found that films with ECTO exhibited the greatest
dimension change, even greater than those of DEHP. Figure 9 shows that
at the 10% concentration at a force of 0.15N, the ECTO plasticized
films exhibited a 700% greater dimension change than the DEHP
plasticized films. A T-test, confirmed that at all concentrations: 10%,
20%, 30%, and 40%, ECTO was of significantly higher performance
than DEHP.
In our 2006
study, we found the unepoxidized Carthamus tinctorius oil to be
an effective plasticizer. Though it appeared to likely be a viable
alternative, it did not reach the same levels of performance as did
DEHP. This year, we opted to chemically alter the oil, in hopes of
raising performance and achieving a dual function of heat
stabilization. Epoxides are known to be good heat stabilizers. We did
this by epoxidizing the oil via a chemo-enzymatic reaction. ECTO has a
high proportion of polar versus non-polar groups and so has greater
solvating power for PVC, enabling it to work as an effective
plasticizer. Epoxidation is achieved by reacting ethane with a peracid
and hydrogen peroxide. For industrial scale production, a peracid,
formed from a short chain fatty acid and hydrogen peroxide under strong
acidic conditions, is used as the oxidizing agent. The problem with
this manufacturing process, however, is that the strong acid used can
cause the formation of unwanted chemical products such as vicinal diols,
estolides, and other dimers. In our study, a safer, more
environmentally-friendly was used. The use of a chemo-enzymatic
reaction for the purposes of epoxidation was first suggested by Warwel
and Klass.8 We used a lipase
to react with the unsaturated fatty acid, linoleic acid (which
comprises 95% of Carthamus tinctorius oil), changing the acid
into a peracid when it is in contact with hydrogen peroxide. The
peracid then loses an oxygen atom which forms an epoxy with its own
double bond. Since linoleic acid has two doubles bonds, it allows a
maximum of two epoxy groups to be formed. The complete epoxidation of
linoleic acid yields 9-10, 12-13-diepoxy stearic acid, while its
incomplete epoxidation results in 9-10-monoepoxy 12-octadecenoic acid
or 12-13-monoepoxy 9-octadecenoic acid. (See diagram below). Such a
lipase mediated reaction is both more efficient and safe than is the
conventional method. Through HPLC, we determined that the percentage of
epoxidized double bonds was approximately 18%.
Camocho, Samuel et al., Eu. J. Lipid Sci. Technol., 2005.
Figure 12
Reaction mechanism of the chemo-enzymatic epoxidation reaction.
Our third
performance test was on the glass transition temperature of our
plastics. Glass transition temperature is indicative of the phase at
which the plastic loses its rigid glass properties and begins to behave
as a flexible plastic. ECTO performed the best overall, while DEHP and
PCL-MePEG showed similar trends. ECTO is effective probably because its
high number of non-polar groups can cause reduction in polar forces
between polymer chains, thus lowering Tg, and improving low temperature
flexibility.
SOURCES OF
ERROR
The epoxidation
reaction was primarily designed for chemically altering pure linoleic
acid. However, since only 95% of Carthamus tinctorius oil is
comprised of unsaturated fatty acid, the chemo-enzymatic reaction we
performed may have chemically altered other substances in the oil. This
could potentially have hindered or improved the plasticizing effects of
ECTO. To improve this, samples with epoxidized linoleic acid could be
compared with those using ECTO.
One problem
with diblock films is that the polymer and the plasticizer did not
appear to be completely miscible by visual examination. This might have
affected the dimension change and the glass transition temperature
results since the films were randomly cut and different sections of the
films had differing amounts of PVC to plasticizer ratios. This causes a
problem because the diblock and the PVC have different physical
properties.
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