SYNTHESIS OF REVERSE ESTER ORGANIC TIN THERMAL STABILIZER FOR POLYVINYL CHLORIDE FROM RICE BRAN FATTY ACID
PVC is a polymer with low heat stability, thus requiring heat stabilizers during its processing. One commonly used heat stabilizer is organic tin reverse ester stabilizer (TOEB).Commercially, this stabilizer is produced from pine fatty acids or Tall Oil Fatty Acid (TOFA), which is a byproduct of...
Saved in:
| Main Author: | |
|---|---|
| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/83295 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | PVC is a polymer with low heat stability, thus requiring heat stabilizers during its
processing. One commonly used heat stabilizer is organic tin reverse ester
stabilizer (TOEB).Commercially, this stabilizer is produced from pine fatty acids
or Tall Oil Fatty Acid (TOFA), which is a byproduct of Crude Tall Oil (CTO)
fractionation. The production of CTO is decreasing as it is derived from forest
resources with diminishing raw material availability. Meanwhile, the demand for
CTO is increasing because it is being used as a raw material for biofuel. This
situation necessitates the search for alternative raw materials for producing TOEB
stabilizers.
Indonesia is one of the world's rice producers. Rice is obtained from the milling
process of paddy, which generates a byproduct called rice bran. In Indonesia, the
estimated production of rice bran is about three million tons per year. Rice bran
contains 15–19,7% oil, with the fatty acid content and composition similar to those
in TOFA. Additionally, rice bran contains active lipase enzymes that can convert
triglycerides into free fatty acids. Therefore, rice bran is considered a potential
alternative raw material for producing TOEB.
This study aims to produce TOEB stabilizers from crude rice bran fatty acid
(CRFA) and compare its characteristics and performance with TOEB obtained
from refined rice bran fatty acid (RRFA) and TOFA. The synthesis of TOEB was
conducted in two reaction stages. The first stage involves the reaction between fatty
acids and mercaptoethanol to produce mercaptoethyl fatty acid (MEAL). The
second stage involves the reaction between MEAL and methyl tin chloride (MTC)
to produce TOEB.
To determine the effect of reactant ratios on the characteristics of the resulting
TOEB, the reactant compositions in the TOEB synthesis were varied with MTC to
MEAL ratios of 10% deficit, stoichiometric, and 10% excess. The stabilizer dosage
was varied at 0,25 phr, 0,5 phr, and 1 phr to assess the effect of dosage on PVC
stability. The characteristics of the resulting MEAL and TOEB were tested using
FTIR spectra. MEAL analysis was performed by measuring the thiol content and
free fatty acid content. TOEB analysis was performed by measuring the sulfur and tin content. The stabilizing effect was examined using static testing with DHC and
dynamic testing with a two roll mill.
This study successfully produced TOEB with a sulfur content of 6,0–6,7% and a tin
content of 10,6–11,4%. The purity of the resulting TOEB was estimated to range
between 75–84%. The success of the TOEB synthesis was confirmed by FTIR
spectral testing. CRFA produced TOEB with slightly lower purity, sulfur content,
and tin content compared to TOEB from RRFA and TOFA but did not show
significant performance differences. The difference in raw material purity did not
significantly impact the stabilizing effect. DHC test results with varying stabilizer
dosages indicated that PVC with a 1 phr stabilizer dosage provided the best
induction and stabilization time. Based on sulfur content, tin content, and
stabilizing effect, TOEB synthesized with stoichiometric reactant ratios had better
results compared to excess and deficit TOEB.
The results of this study are expected to contribute to science and technology.
Scientifically, this research adds information and understanding about the
synthesis of TOEB from alternative raw materials and the resulting thermal
stabilization effects. Practically, this research can enhance the sustainability of
TOEB stabilizer production by providing alternative raw materials to substitute the
increasingly limited availability of TOFA. Additionally, this study contributes to
reducing environmental pollution by producing eco-friendly heat stabilizers that
have the potential to replace lead stabilizers. The research also provides new
insights into products that can be derived from rice bran.
|
|---|