HEMATITE-GAMMA ALUMINA BASED SOLID CATALYST DEVELOPMENT FOR BIODIESEL PRODUCTION FROM PALM OIL
Indonesia is the biggest crude palm oil (CPO) producer in the world, with projected national production reaching 52,3 million tons in 2021. In order to achieve 23% renewable energy mix in 2025, the government has established the B30 policy, where diesel is mixed with fatty acid methyl ester (FAME...
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| Format: | Final Project |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/65540 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Indonesia is the biggest crude palm oil (CPO) producer in the world, with projected
national production reaching 52,3 million tons in 2021. In order to achieve 23%
renewable energy mix in 2025, the government has established the B30 policy, where
diesel is mixed with fatty acid methyl ester (FAME) that is obtained from
transesterification reaction of CPO. Catalyst that is commonly used is homogeneous
catalyst, but free fatty acid content within the feed needs to be minimized because of its
susceptibility to soap formation that could reduce biodiesel yield. Therefore,
heterogeneous catalysts are developed due to its capability in avoiding soap formation
and recyclability for sustainable use. However, several heterogeneous catalysts utilization
needs more methanol, longer reaction time and higher reaction temperature so that other
catalyst options need to be studied for optimal biodiesel production. The aim of this
research is to investigate the performance of Fe2O3/?-Al2O3 catalyst in biodiesel
production from palm oil and the influence of certain factors to catalyst performance.
From the carried out transesterification process, biodiesel in the range of 73,6 – 87,6%
FAME content was obtained according to the determined experimental design. It can be
concluded that the catalyst composition, the methanol-oil ratio, and the catalyst loading
have a significant effect on the FAME content of the biodiesel. Hematite has strong
affinity for fatty acids, so a larger hematite surface area will result in a higher fatty acid
absorption capacity. The addition of excess methanol can shift the equilibrium towards
the product and reduce the contact inhibition between the reactants and the active site of
the catalyst, thereby increasing the conversion of the reaction. On the other hand, a higher
amount of catalyst loading can result in an increase in FAME content when accompanied
by an increase in the hematite content of the catalyst. It can be concluded that the best
variation from this experiment was the hematite content of 16%, the catalyst loading of
6%, and the methanol-oil ratio of 12:1 which resulted in the FAME content of 87,6%. |
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