Kinetic study of crude oil-to-chemicals via steam-enhanced catalytic cracking in a fixed-bed reactor

This study presents new experimental results on the direct conversion of crude oil to chemicals via steam-enhanced catalytic cracking. We have organized the experimental results with a kinetics model using crude oil and steam co-feed in a fixed-bed flow reactor at reaction temperatures of 625, 650, and 675 degrees C over the Ce-Fe/ZSM-5 catalyst. The model let us find optimum conditions for crude oil conversion, and the order of the steam cracking reaction was 2.0 for heavy oil fractions and 1.0 for light oil fractions. The estimated activation energies for the steam cracking reactions ranged between 20 and 200 kJ/mol. Interestingly, the results from kinetic modelling helped in identifying a maximum yield of light olefins at an optimized residence time in the reactor at each temperature level. An equal propylene and ethylene yield was observed between 650 and 670 degrees C, indicating a transition from dominating catalytic cracking at a lower temperature to a dominating thermal cracking at a higher temperature. The results illustrate that steam-enhanced catalytic cracking can be utilized to effectively convert crude oil into basic chemicals (52.1% C2-C4 light olefins and naphtha) at a moderate severity (650 degrees C) as compared to the conventional high-temperature steam cracking process.

Automated summary

This study presents new experimental results on the direct conversion of crude oil to chemicals via steam-enhanced catalytic cracking. The experimental results were organized using a kinetics model and showed that the steam cracking reaction of heavy oil fractions had an order of 2.0, while the reaction of light oil fractions had an order of 1.0. The estimated activation energies for the steam cracking reactions ranged between 20 and 200 kJ/mol. The study also found that an equal yield of propylene and ethylene was observed between 650 and 670 degrees C, indicating a transition from catalytic cracking to thermal cracking at higher temperatures.