DEVELOPMENT OF ULTRA LOW SULPHUR DIESEL PRODUCTION CATALYST
One of the commercially sold petroleum refinery fractions is diesel fuel, which is more efficient than gasoline, making it more economical for vehicle use. This efficiency makes diesel popular in the market, although sulfur emissions in the form of SOx are a significant concern. Currently, diesel...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/85913 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | One of the commercially sold petroleum refinery fractions is diesel fuel, which is more
efficient than gasoline, making it more economical for vehicle use. This efficiency makes
diesel popular in the market, although sulfur emissions in the form of SOx are a
significant concern. Currently, diesel fuels such as Pertamina Dex and Dexlite have sulfur
content ranging from 300-2000 ppm. However, the Director General of ESDM has
decreed that by 2026 the maximum sulfur content in diesel should be 50 ppm. In Europe,
the implementation of EURO V regulations with sulfur content not exceeding 10 ppm has
already begun. Sulfur removal in refineries is carried out through the hydrotreating
process, which heavily depends on the catalyst used, specifically NiMo/?-Al2O3. The
performance of a catalyst is could be seen through its kinetic parameters. This study aims
to determine the kinetic data of the hydrodesulfurization (HDS) reaction catalyzed by
NiMo/?-Al2O3-P and NiMo/?-Al2O3-P-MgO catalysts. Both catalysts are tested in HDS
reactions using a Light Cycle Gas Oil feed in a batch reactor at a pressure of 32 bar and
temperatures ranging from 310-330°C. The results of the study showed that increasing
temperature increased the reaction kinetics, indicated by an increase in the reaction rate
constant and conversion, both from experiments and ASPEN HYSYS simulations.
Variations in operating condition parameters such as LHSV, temperature, and H2/HC
ratio also affected the kinetics and conversion of sulfur. A higher LHSV decreased the
conversion, while the H2/HC ratio was directly proportional to the conversion. To meet
the sulfur specifications according to EURO V regulations and field condition limitations
at the refinery (Pertamina RU-II), the optimum operating conditions obtained were LHSV
1.35 h-1, temperature 330°C, and H2/HC of 400 Nm3/m3. These optimum conditions
were achieved using HDS 1 catalyst with an Ea value of 40,665.44 J/mol which had better
kinetic results than HDS 2 which had an Ea value of 77511.2 J/mol. |
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