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Issue
Korean Journal of Chemical Engineering,
Vol.39, No.5, 1215-1226, 2022
Effect of slurry phase catalyst and H2 pressure on hydrocracking of SDA (solvent de-asphalting) pitch
Pham DV, Nguyen NT, Kang KH, Seo PW, Kim GT, Park YK, Park SY
Hydrocracking of solvent deasphalted (SDA) pitch was performed in batch and semi-batch systems, at different reaction temperatures (380-430 ℃) with varying amounts of Mo-octoate precursor (0-1,000 ppm Mo) under 70-130 bar of H2 pressure. The reusability of the catalyst was also examined. Coke formation was unavoidable in the hydrocracking of the asphaltene-rich feed. The coke induction period was prolonged when the catalyst was introduced. Increasing the Mo catalyst concentration decreased the coke yield and improved the product quality. The catalytic hydrocracking of the SDA pitch under high H2 pressure suppressed coke formation, promoted desulfurization, and increased the H/C ratio of the liquid products. At least 500 ppm of Mo catalyst and H2 pressur above 110 bar were required for the hydrocracking of SDA pitch with controllable coke generation in the semi-batch system. Sufficient hydrogen supply and moderate catalyst concentration were essential for the slurry-phase hydrocracking of asphaltenerich feedstocks to enhance the product quality and suppress coke formation.
Keywords: Slurry-phase Hydrocracking; SDA Pitch; Asphaltenes; Coke; Reaction Conditions
[References]
  1. Ancheyta J, Speight JG, Hydroprocessing of heavy oils and residua, CRC Press (2007).
  2. Ancheyta J, Modeling of processes and reactors for upgrading of heavy petroleum, CRC Press (2013).
  3. Angeles MJ, Leyva C, Ancheyta J, Ramírez S, Catal. Today, 220-222, 274, 2014
  4. Absi-Halabi M, Stanislaus A, Trimm DL, Appl. Catal., 72, 193, 1991
  5. Lababidi HMS, Sabti HM, AlHumaidan FS, Fuel, 117, 59, 2014
  6. Ancheyta J, Centeno G, Trejo F, Marroquín G, Energy Fuels, 17, 1233, 2003
  7. Ancheyta J, Trejo F, Rana MS, Asphaltenes: Chemical transformation during hydroprocessing of heavy oils, CRC Press, Taylor & Francis Group, Boca Raton (2010).
  8. Mullins OC, Energy Fuels, 24, 2179, 2010
  9. Nguyen TM, Jung J, Lee CW, Cho J, Fuel, 214, 174, 2018
  10. Speight JG, The chemistry and technology of petroleum, Fifth Edition. Taylor & Francis (2014).
  11. Wiehe IA, Energy Fuels, 26, 4004, 2012
  12. Gawel I, Bociarska D, Biskupski P, Appl. Catal. A: Gen., 295, 89, 2005
  13. Sámano V, Guerrero F, Ancheyta J, Trejo F, Díaz JAI, Catal. Today, 150, 264, 2010
  14. Díaz-Boffelli G, Ancheyta J, Muñoz JAD, Centeno G, Energy Fuels, 32, 55, 2018
  15. Olar HR, Halafawi M, Avram L, Pet. Coal., 63, 278, 2021
  16. Sahu R, Song BJ, Im JS, Jeon YP, Lee CW, J. Ind. Eng. Chem., 27, 12, 2015
  17. Martinez-Grimaldo H, Ortiz-Moreno H, Sanchez-Minero F, Ramírez J, Cuevas-Garcia R, Ancheyta-Juarez J, Catal. Today, 220-222, 295, 2014
  18. Ortiz-Moreno H, Ramírez J, Sanchez-Minero F, Cuevas R, Ancheyta J, Fuel, 130, 263, 2014
  19. Go KS, Lim SH, Kim YK, Kwon EH, Nho NS, Catal. Today, 305, 92, 2018
  20. Quitian A, Ancheyta J, Energy Fuels, 30, 10117, 2016
  21. Park HB, Kim KD, Lee YK, Fuel, 222, 105, 2018
  22. Nguyen NT, Kang KH, Seo PW, Kang N, Van Pham D, Ahn C, Kim GT, Park S, Energies, 13, 4444, 2020
  23. Nguyen NT, Kang KH, Pham HH, Go KS, Van Pham D, Seo PW, Nho NS, Lee CW, Park S, J. Ind. Eng. Chem., 102, 112, 2021
  24. Kang KH, Nguyen NT, Seo PW, Seo H, Kim GT, Kang N, Lee CW, Han SJ, Chung MC, Park S, J. Catal., 384, 106, 2020
  25. Prajapati R, Kohli K, Maity SK, Fuel, 288, 119686, 2020
  26. Nguyen NT, Park S, Jung J, Cho J, Lee CW, Park YK, J. Ind. Eng. Chem., 61, 32, 2018
  27. Rezaei H, Ardakani SJ, Smith KJ, Energy Fuels, 26, 2768, 2012
  28. Kershaw JR, Black KJT, Energy Fuels, 7, 420, 1993
  29. Hassan A, Carbognani L, Pereira-Almao P, Fuel, 87, 3631, 2008
  30. Nguyen NT, Kang KH, Lee CW, Kim GT, Park S, Park YK, Fuel, 235, 677, 2019
  31. Li X, Hu S, Jin L, Hu H, Energy Fuels, 22, 1126, 2008
  32. Merdrignac I, Truchy C, Robert E, Guibard I, Kressmann S, Pet. Sci. Technol., 22, 1003, 2004
  33. Sheng Q, Wang G, Jin N, Husein MM, Gao J, Fuel, 255, 115736, 2019
  34. Félix G, Ancheyta J, Fuel, 241, 495, 2019
  35. Humbert S, Izzet G, Raybaud P, J. Catal., 333, 78, 2016
  36. Rezaei H, Ardakani SJ, Smith KJ, Energy Fuels, 26, 6540, 2012
  37. Panariti N, Del Bianco A, Del Piero G, Marchionna M, Carniti P, Appl. Catal. A: Gen., 204, 215, 2000
  38. Rezaei H, Smith KJ, Energy Fuels, 27, 6087, 2013
  39. Bellussi G, Rispoli G, Molinari D, Landoni A, Pollesel P, Panariti N, Millini R, Montanari E, Catal. Sci. Technol., 3, 176, 2013
  40. Liu B, Zhao K, Chai Y, Li Y, Liu D, Liu Y, Liu C, Fuel, 246, 133, 2019
  41. Rezaei H, Liu X, Ardakani SJ, Smith KJ, Bricker M, Catal. Today, 150, 244, 2010
  42. Trejo F, Ancheyta J, Centeno G, Marroquín G, Catal. Today, 109, 178, 2005
  43. Mitra-Kirtley S, Mullins OC, Van Elp J, George SJ, Chen J, Cramer SP, J. Am. Chem. Soc., 115, 252, 1993
  44. Kim SH, Kim KD, Lee YK, J. Catal., 347, 127, 2017
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