Optimization of operating conditions in oxidation of dibenzothiophene in the light hydrocarbon model

• Main Authors: Akbari Azam, Omidkhah Mohammadreza, Towfighi Darian Jafar
• Format: Article
• Language: English
• Published: Association of the Chemical Engineers of Serbia 2014-01-01
• Series: Chemical Industry and Chemical Engineering Quarterly
• Subjects: oxidative desulfurization; response surface methodology; central composite design; dibeznothiophene; light hydrocarbon
• Online Access: http://www.doiserbia.nb.rs/img/doi/1451-9372/2014/1451-93721300013A.pdf
• ISSN: 1451-9372; 2217-7434

In this research, the effects of process variables on the efficiency and mechanism of dibenzothiophene oxidation in formicacid/H2O2 system for deep desulfurization of a light hydrocarbon model were systematically studied by statistical modelling and optimization using response surface methodology and implementing the central composite design. A quadratic regression model was developed to predict the yield of sulfur oxidation as the model response. The model indicated that temperature was the most significant effective factor and suggested an important interaction between temperature and H2O2/sulfur ratio; at temperatures above 56°C, more excess oxidant was necessary because of instability of active peroxo intermediates and loss of H2O2 due to thermal decomposition. In contrast, the water hindrance effect of H2O2 aqueous solution in desulfurization progress was more significant at temperatures bellow 56°C. In the optimization process, minimizing H2O2/sulfur ratio and catalyst consumption for maximum yield of desulfurization was economically considerable. The optimal condition was obtained at temperature of 57 °C, H2O2/sulfur ratio of 2.5 mol/mol and catalyst dosage of 0.82 mL in 50 mL solution of DBT in n-hexane leading to a maximum oxidation yield of 95% after 1 hour reaction. Good agreement between predicted and experimental results (less than 4% error) was found.