Hierarchy Modification Effects in Catalytic Cracking of Palm Oil Using HZSM-5 Catalyst
Para-xylene is a petrochemical industry feedstock with a very high selling and demand level. However, in Indonesia, the high demand for para-xylene has not been matched by the high production of it domestically. In addition, para-xylene feedstock is generally still petroleum-based. One kind of gr...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/38393 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Para-xylene is a petrochemical industry feedstock with a very high selling and demand
level. However, in Indonesia, the high demand for para-xylene has not been matched by
the high production of it domestically. In addition, para-xylene feedstock is generally still
petroleum-based. One kind of green and clean way to produce para-xylene is through
catalytic cracking of palm oil using HZSM-5 catalyst. However, without modification,
HZSM-5 still has short lifetime and provides relatively low para-xylene selectivity. One
alternative way to overcome the problems is by modifying the HZSM-5 used to
hierarchical HZSM-5. The presence of the hierarchical structure is expected to prolong
the catalyst lifetime and shift the xylene isomerization equilibrium towards para-xilene.
The aims of this research were to determine the hierarchy modification effects on HZSM-
5 catalyst performances in cracking crude palm oil, especially from its selectivity towards
para-xilene. The hierarchical HZSM-5 catalysts were synthesized by conducting
desilication and dealumination against parent HZSM-5 already available in the TRKK
Laboratory. In each of the run, the catalyst mass used was 2.5 g and the WHSV used was
2.5 h-1. The Si/Al HZSM-5 ratio used were 25, 50, and 80. The catalyst characterisation
was done by conducting N2 isothermal adsorption test and TPD-NH3 test, while the
product testing was done using GC-FID, GC-TCD, and GC-DHA. Coke mass analysis
was done by thermogravimetry method.
The conclusions drawn from this research were that hierarchy modification of HZSM-5
catalyst may prolong the catalyst lifetime, increase the aromatic selectivity stability,
increase para-xilene selectivity (by around 1%), and slow down the coke formation rate
compared to parent HZSM-5 catalyst. However, in its fresh condition, hierarchical
HZSM-5 gave lower aromatic selectivity compared to parent catalyst. Moreover,
hierarchical HZSM-5 also gave more gas product.
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