improvements should be made in its

improvements should be made in its properties and analyze
basic parameters needed to attain stability.
As per EN 14112/IS 15602 test method, oxidation stability
is measured by heating at 110 C. In order to study the
trend of oxidation stability of biodiesel from various
resources, the oxidation stability is measured by heating
them at 110 C. It was found that the trend of induction
period had direct correlation with the percentage of saturated
fatty acids. For example, biodiesel from sunflower
oil (BDSU) having only 11.6% saturates, showed induction
period of 1.73 h. On the other hand, the palm oil biodiesel
(BDP) having 43.4% saturates, exhibited induction period
of 13.37 h (Fig. 2).
Another set of study was done to observe the effect of
temperature on biodiesel stability. The oxidation stability
tests were carried out at 100 C and 120 C. As anticipated,
the oxidation process accelerated with increase of temperature.
However, no difference in relative stability was
noticed and biodiesel from the oil having large fraction
of saturated fatty acids like palm was found to be still better
than biodiesel from other oil sources like Jatropha, having
larger fraction of unsaturated fatty acids (Fig. 2). The
reason for good stability of palm oil biodiesel is due to
the resistance to auto-oxidation of saturated fatty acids.
As given in Table 1, Palm oil has maximum proportion
of saturates making it less susceptible towards oxidation.
In Indian scenario, Jatropha is the main feedstock available
for biodiesel production. So, further study has been
concentrated on oxidation stability of Jatropha biodiesel.
Two pronged approach has been adopted for improving
oxidation stability of Jatropha biodiesel. First route deals
with the doping of Jatropha methyl esters with stabilizer
or antioxidants. Among stabilizers utilized in this study
were three phenolic antioxidants; 2,6–ditertiarybutyl
hydroxytoluene (AO-1), bis-2,6-ditertairybutyl phenol
derivative (AO-2), mixed butylated phenol (AO-3), and
aminic antioxidant octylated butylated diphenyl amine
(AO-4).
All four antioxidants were doped at 200 ppm dosage in
Jatropha, Karanjia, Sunflower and Soybean based biodiesel
and tested in Rancimat to observe the effectiveness of
different antioxidants. The results obtained are shown in
Fig. 3. From these experiments, it is observed that the antioxidant
AO-1 is most effective among all the antioxidants
used. Therefore, it is decided to study the effect of dosage
of antioxidant (AO-1) on oxidation stability of Jatropha
biodiesel. The Fig. 4, shows the effect of phenolic antioxidant
AO-1 from 25 ppm dosage to 400 ppm on oxidation
stability. The oxidation stability of Jatropha biodiesel has
been found to increase with increase in dosage of antioxidant.
Finally it is found that dosing of 200 ppm of antioxidant
is the minimum requirement to meet EN 14112
specification for biodiesel oxidative stability.
Although it is found possible to meet the desired EN
specification by using antioxidant, it will have a cost implication,
as antioxidants are costly chemicals. Therefore,
another set of study was undertaken to blend Jatropha