One of the key factors for increasing the efficiency of reactions in which catalysts are involved is to increase the contacts and exposure of reagents to the catalysts. Using ultrasonic waves to destabilize the boundary layer between solid catalysts and reagents and mixing the homogeneous catalysts and reagent can increase the rate of reaction. Based on this fact, many industrial processesincludingdesulfurization are enhanced by sonication. In this study a sono desulfurization unit with the capacity of 5 bbl per day, in which oxidative desulfurization is the main mechanism, is designed and tested. Also, the influence of different parameters on the efficiency of the reactions is investigated.
Key words: Ultrasonic waves; Desulfurization; Catalyst; Oxidant

Ultrasonic waves; Desulfurization; Catalyst; Oxidant

[1] Anabtawi, J.A., Ali, S.A., Bari Siddiqui, M.A, & Zaidi, S.M.J. (1996). Factors Influencing the Performance of Naphtha Hydro-Desulfurization Catalysts. Studies in Surface Science & Catalyst, 100, 225-234.

[2] Zongxuan, J., Hongying, L., Yongna, ZH., & Can, L. (2011). Oxidative Desulfurization of Fuel Oils. Chinese Journal of Catalysis, 32, 707-715.

[3] Monticello, D.J. (2000). Biodesulfurization and the Upgrading of Petroleum Distillates. Current Opinion in Biotechnology, 11(6), 540-546.

[4] Chu, X., Hu, Y., Li, J., Liang, Q., Liu, Y., Zhang, X., Peng, X., & Yue, W. (2008). Desulfurization of Diesel Fuel by Extraction with [BF₄]⁻-Based Ionic Liquids. Chinese Journal of Chemical Engineering, 8(16), 881-884.

[5] Hernandez-Maldonado, A.J., & Yang, R.T. (2004). Desulfurization of Transportation Fuels by Adsorption. Catalysis Reviews, 46(2), 111–150.

[6] Sano, Y., Choi, K., Korai, Y., & Mochida, I. (2004). Selection and Further Activation of Activated Carbons for Removal of Nitrogen Species in Gas Oil as a Pretreatment for Its Deep Hydrodesulfurization. Energy Fuels, 18(2), 644–651.

[7] Sano, Y., Choi, K., Korai, Y., & Mochida, I. (2004). Adsorptive Removal of Sulfur and Nitrogen Species from a Straight Run Gas Oil over Activated Carbons for Its Deep Hydrodesulfurization. Applied Catalysis B: Environmental, 49, 219–225.

[8] Vasudevan, P.T., & Fierro, J.L.G. (1996). A Review of Deep Hydrodesulfurization Catalysis. Catalysis Reviews: Science & Engineering, 38, 161–188.

[9] Whitehurst, D.D., Isoda, T., & Mochida, I. (1998). Present State of the Art and Future Challenges in the Hydrodesulfurization of Polyaromatic Sulfur Compounds. Advances in Catalysis, 42, 345-471.

[10] Ma, X., Zhou, A., & Song, Ch. (2007). A Novel Method for Oxidative Desulfurization of Liquid Hydrocarbon Fuels Based on Catalytic Oxidation Using Molecular Oxygen Coupled with Selective Adsorption. Catalysis Today, 123, 276–284.

[11] Breysse, M., Diega-Mariadassou, G., Pessayre, S. Geantet, G., Vrinet, M., & Lemaire, M. (2003). Deep Desulfurization: Reactions, Catalysts and Technological Challenges. Catalysis Today, 84, 129–138.

[12] Babich, IV., & Moulijn, JA. (2003). Science and Technology of Novel Processes for Deep Desulfurization of Oil Refinery Streams: A Review. Fuel, 82, 607–631.

[13] Yu, G.X., Lu, S.X., Chen, H., & Zhu, Z.N. (2005). Oxidative Desulfurization of Diesel Fuels with Hydrogen Peroxide in the Presence of Activated Carbon and Formic Acid. Energy Fuels, 19, 447–452.

[14] Shiraishi, Y., & Hirai, T. (2004). Desulfurization of Vacuum Gas Oil Based on Chemical Oxidation Followed by Liquid−Liquid Extraction. Energy & Fuels, 18, 37-40.

[15] Zannikos, F., Lois, E., & Stournas, S. (1995). Desulfurization of Petroleum Fractions by Oxidation and Solvent Extraction. Fuel Processing Technology, 42, 35–45.

[16] Ramírez-Verduzco, L.F., Murrieta-Guevara, F., Garcia-Gutierrez, J. L., Martin-Castanon, R.S., Martinez-Guerrero, M. C., Montiel-Pacheco, M. C., & Manta-Diaz, R. (2004). Desulfurization of Middle Distillates by Oxidation and Extraction Process. Petroleum Science & Technology, 22, 129–139.

[17] Filippis, P.D., & Scarsella, M. (2003). Oxidative Desulfurization: Oxidation Reactivity of Sulfur Compounds in Different Organic Matrixes. Energy Fuels, 17, 1452–1455.

[18] Otsuki, S., Nonaka, T., Takashima, N., Qian, W., Ishihara, A., Imai, T., & Kabe, T. (2000). Oxidative Desulfurization of Light Gas Oil and Vacuum Gas Oil by Oxidation and Solvent Extraction. Energy Fuels, 14, 1232–1239.

[19] Te, M., Fairbridge, C., & Ring, Z. (2001). Oxidation Reactivities of Dibenzothiophenes in Polyoxometalate/H₂O₂ and Formic Acid/H₂O₂ Systems. Applied Catalysis A: General, 219, 267–280.

[20] Li, H., He, L., Lu, J., Zhu, W., Jiang, X., Wang, Y., & Yan, Y. (2009). Deep Oxidative Desulfurization of Fuels Catalyzed by Phosphotungstic Acid in Ionic Liquids at Room Temperature. Energy & Fuels, 23, 1354–1357.

[21] Kong, L.Y., Li, G., & Wang, X.S. (2004). Mild Oxidation of Thiophene over TS-1/H₂O₂. Catalysis Today, 93-95, 341–345.

[22] Shiraishi, Y. , Hirai, T., & Komasawa, I. (2002). TiO₂-Mediated Photocatalytic Desulfurization Process for Light Oils Using an Organic Two-Phase System. Journal of Chemical Engineering of Japan, 35, 489-492.

[23] Torres-Garcia, E., Canizal, G., Velumani, S., Ramirez-Verduzco, L.F., Murrieta-Guevara, F., & Ascencio, J.A. (2004). Influence of Surface Phenomena in Oxidative Desulfurization with WO_x/ZrO₂ Catalysts. Applied Physics A, 79, 2037-2040.

[24] Shiraishi, Y., Naito, T., & Hirai, T. (2003). Vanadosilicate Molecular Sieve as a Catalyst for Oxidative Desulfurization of Light Oil. Industrial & Engineering Chemistry Research, 42, 6034-6039.

[25] Dai, Y., Qi, Y., Zhao, D., & Zhang, H. (2008). An Oxidative Desulfurization Method Using Ultrasound/Fenton's Reagent for Obtaining Low and/or Ultra-Low Sulfur Diesel Fuel. Fuel Processing Technology, 89, 927–932.

[26] Dai, Y., Zhao, D., & Qi, Y. (2011). Sono-Desulfurization Oxidation Reactivities of FCC Diesel Fuel in Metal Ion/H₂O₂ Systems. UltrasonicsSonochemistry, 18, 264–268.

[27] Duarte, F.A., Mello, P.A., Bizzi, C.A., Nunes, M.A.G., Moreira, E.M., Alencar, M.S., Motta, H.N., Dressler, V.L., & Flores, É.M.M. (2011). Sulfur Removal from Hydrotreated Petroleum Fractions Using Ultrasound-Assisted Oxidative Desulfurization Process. Fuel, 90, 2158–2164.

[28] Chen, T., Shen, Y., Lee, W., Lin, Ch., & Wan, M-W. (2010). The Study of Ultrasound-Assisted Oxidative Desulfurization Process Applied to the Utilization of Pyrolysis Oil from Waste Tires. Journal of Cleaner Production, 18, 1850-1858.

[29] Wu, Zh., & Ondruschka, B. (2010). Ultrasound-Assisted Oxidative Desulfurization of Liquid Fuels and Its Industrial Application. Ultrasonics Sonochemistry, 17, 1027–1032.

[30] Kikuchi, T. & Uchida, T. (2011). Calorimetric Method for Measuring High Ultrasonic Power Using Water as a Heating Material.Journal of Physics: Conference Series, 279, 1-5. doi:10.1088/1742-6596/279/1/012012.

[31] Dai, Y., Zhao, D., & Qi, Y. (2011). Sono-Desulfurization Oxidation Reactivities of FCC Diesel Fuel in Metal Ion/H₂O₂ Systems. Ultrasonics Sonochemistry, 18, 264–268.

[32] Dai, Y.C., Qi, Y.T., Zhao, D.Z., & Zhang, H.C. (2008). An Oxidative Desulfurization Method Using Ultrasound/Fenton's Reagent for Obtaining Low and/or Ultra-Low Sulfur Diesel Fuel. Fuel Processing Technology, 89, 927–932.