화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korean Journal of Chemical Engineering, Vol.30, No.11, 1985-1989, November, 2013
DOI10.1007/s11814-013-0157-x  Export Citation
Effects of aromatic cycle oils on performance of residue hydrotreating
Yongjun Liu, and Yu Zou
  • College of Chemical Engineering, Huaqiao University, Jimei 668, Xiamen 361021, Fujian, P. R. China
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Hydrotreating, as an important pretreatment process of residue catalytic cracking, is used to eliminate metals, S and N contaminants and partly process asphaltene from streams so that the products can be efficiently processed in downstream conversion units. We investigated the effects of aromatic additives on residue hydrtreating (RHT) by adding various types and contents of high aromatic cycle oils into atmosphere residue (AR). The aromatic additives modify the colloidal structure of asphaltene in AR and improve the liberation of heteroatomic compounds bound in nucleus. Therefore, the amount of carbon residue in blending oils decreases and the removal efficiency of Ni, V, S and N increases obviously. The increase of conversion is greater for nitrogen than for sulfur, and hydrodevanadium reveals a distinct advantage over hydrodenickel. However, excessive amount of light cycle oil (more than 20% wt) is not helpful for removing the Ni and V since a little of metalloporphyrins stubbornly bond with the superstructure of nucleus.
Keywords:Residue Hydrotreating;Cycle Oil;Asphaltene;Colloidal Structure
  1. Tamm PW, Harnsberger HF, Bridge AG, Ind. Eng. Chem.Process Des. Dev., 20, 262 (1981)
  2. Pacheco ME, Salim VMM, Pinto JC, Ind. Eng. Chem. Res., 50(10), 5975 (2011)
  3. Seki H, Kumata F, Energy Fuels, 14(5), 980 (2000)
  4. Matsushita K, Marafi A, Hauser A, Stanislaus A, Fuel, 83(11-12), 1669 (2004)
  5. Nellensteyn FJ, J. Inst. Petrol. Technologists., 10, 311 (1924)
  6. Mack C, J. Phys. Chem., 36, 2901 (1932)
  7. Yen TF, Fuel Science and Technology International., 10, 723 (1992)
  8. Pfeiffer JP, Saal RNJ, J. Phys. Chem., 44, 139 (1940)
  9. Lesueur D, Gerard JF, Claudy P, Letoffe JM, Planche JP, Martin D, J. Rheol., 40(5), 813 (1996)
  10. Wiehe IA, Liang KS, Fluid Phase Equilib., 17, 201 (1996)
  11. Mullins OC, Sabbah H, Eyssautier J, Pomerantz AE, Barre L, Andrews AB, Ruiz-Morales Y, Mostowfi F, McFarlane R, Goual L, Lepkowicz R, Cooper T, Orbulescu J, Leblanc RM, Edwards J, Zare RN, Energy Fuels, 26(7), 3986 (2012)
  12. Skowronski RP, Ratto JJ, Goldberg IB, Heredy LA, Fuel., 63, 440 (1984)
  13. Shi B, Ding JW, Que GH, J. Fuel Chem. Technol., 32, 253 (2004)
  14. Oboho EO, Oboho SP, Chem. Eng. Technol., 15, 278 (1992)
  15. Mizutani H, Kiriyama K, Idei K, Mochida I, J. Jpn. Pet. Inst., 47, 303 (2004)
  16. Kubo J, Higashi H, Ohmoto Y, Arao H, Energy Fuels, 10(2), 474 (1996)
  17. Niu CF, Effect of aromatic heavy gas oil on residue hydrotreating reactions, Research Institute of Petroleum Processing, Beijin, 85 (1997)
  18. Maity SK, Perez VH, Ancheyta J, Rana MS, Centeno G, Petroleum Science and Technology., 25, 241 (2007)
  19. Ancheyta J, Betancourt G, Centeno G, Marroquin G, Alonso F, Garciafigueroa E, Energy Fuels, 16(6), 1438 (2002)
  20. Jin M, Han BP, Ranliao Huaxue Xuebao., 31, 524 (2003)
  21. Pfeiffer JP, Saal RNJ, J. Phys. Chem., 44, 139 (1940)
  22. Barre L, Simon S, Palermo T, Langmuir, 24(8), 3709 (2008)
  23. Sheu EY, Energy Fuels., 16, 74 (2001)
  24. Espinosa M, Campero A, Salcedo R, Inorg. Chem., 40(18), 4543 (2001)
  25. Rana MS, Samano V, Ancheyta J, Diaz JAI, Fuel, 86(9), 1216 (2007)