Ultrafiltration Separation of Crude Oil and Waste Oil

Capa

Citar

Texto integral

Acesso aberto Acesso aberto
Acesso é fechado Acesso está concedido
Acesso é fechado Somente assinantes

Resumo

Approximately 90 million barrels of crude oil are processed daily worldwide, with separation processes such as distillation accounting for 10−15% of global energy consumption. In this regard, the scientific community is faced with the ambitious task of finding alternative fractionation technologies that are not based on the volatility of individual components of complex liquid mixtures. The driving force of ultrafiltration is the pressure differential across the membrane, enabling separation without phase transitions and with significantly lower energy consumption compared to distillation. In recent years, there has been a growing interest in the development of membrane technologies for the purification and reuse of used lubricating oil. One of the key challenges in membrane filtration of oil and lubricants is their high viscosity. This review examines two approaches to reducing the viscosity of such systems: filtration at elevated temperatures and pre-dilution of the feedstock followed by filtration. A literature analysis revealed that in most cases, ultrafiltration with ceramic membranes is employed in the former approach, while the latter uses more cost-effective polymer membranes. Special attention in the review is given to the issues of membrane fouling and regeneration.

Texto integral

Acesso é fechado

Sobre autores

A. Nebesskaya

Topchiev Institute of Petrochemical Synthesis

Autor responsável pela correspondência
Email: nebesskaya@ips.ac.ru
Rússia, Moscow, 29, Leninsky Ave., 119991

A. Balynin

Topchiev Institute of Petrochemical Synthesis

Email: nebesskaya@ips.ac.ru
Rússia, Moscow, 29, Leninsky Ave., 119991

A. Yushkin

Topchiev Institute of Petrochemical Synthesis

Email: nebesskaya@ips.ac.ru
Rússia, Moscow, 29, Leninsky Ave., 119991

A. Markelov

Topchiev Institute of Petrochemical Synthesis; Yaroslavl State Technical University

Email: nebesskaya@ips.ac.ru
Rússia, Moscow, 29, Leninsky Ave., 119991; Yaroslavl, 88, Moskovsky Ave., 150023

V. Volkov

Topchiev Institute of Petrochemical Synthesis

Email: nebesskaya@ips.ac.ru
Rússia, Moscow, 29, Leninsky Ave., 119991

Bibliografia

  1. Sholl D.S., Lively R.P. // Nature. 2016. V. 532. N 7600. P. 435−437.
  2. Duong A., Chattopadhyaya G., Kwok W.Y., Smith K.J. // Fuel. 1997. V. 76. N 9. P. 821−828.
  3. Kutowy O., Guerin P., Tweddle T., Woods J. // Proc. 35th Can. Chem. Eng. Conf. 1985. V. 1. – P. 241.
  4. Kutowy O., Tweddle T.A., Hazlett J.D. // Patent № US4814088A United States.
  5. Sparks B., Hazlett J., Kutowy O., Tweddle T. // American Institute of Chemical Engineers. 1990. V. 36. N 8.
  6. Magomedov R.N., Pripakhaylo A.V., Maryutina T.A., Shamsullin A.I., Ainullov T.S. // Russian Journal of Applied Chemistry. 2019. V. 92. N 12. P. 1634−1648.
  7. Ching M.-J.T.M., Pomerantz A.E., Andrews A.B., Dryden P., Schroeder R., Mullins O.C.,
  8. Barbier J., Marques J., Caumette G., Merdrignac I., Bouyssiere B., Lobinski R., Lienemann C.-P. // Fuel Processing Technology. 2014. V. 119. P. 185−189.
  9. Marques J., Merdrignac I., Baudot A., Barré L., Guillaume D., Espinat D., Brunet S. // Oil & Gas Science and Technology - Revue d’IFP Energies nouvelles. 2008. V. 63. N 1. P. 139.
  10. Юшкин А.А., Балынин А.В., Небесская А.П., Ефимов М.Н., Муратов Д.Г., Карпачева Г.П. // Мембраны И Мембранные Технологии. 2023. Т. 13. N 6. C. 521−534.
  11. Юшкин А.А., Балынин А.В., Небесская А.П., Ефимов М.Н., Бахтин Д.С., Баскаков С.А., Канатьева (Антошкина) А.Ю. // Мембраны И Мембранные Технологии. 2023. Т. 13. N 4. C. 331−344.
  12. Chisca S., Musteata V.-E., Zhang W., Vasylevskyi S., Falca G., Abou-Hamad E., Emwas A.-H., Altunkaya M., Nunes S.P. // Science. 2022. V. 376. N 6597. P. 1105−1110.
  13. Lai W.-C., Smith K.J. // Fuel. 2001. V. 80. N 8. P. 1121−1130.
  14. Duong A., Smith K.J. // The Canadian Journal of Chemical Engineering. 1997. V. 75. N 6. P. 1122−1129.
  15. Ashtari M., Ashrafizadeh S.N., Bayat M. // Journal of Petroleum Science and Engineering. 2012. V. 82−83. P. 44−49.
  16. Ashtari M., Bayat M., Sattarin M. // Energy & Fuels. 2011. V. 25. N 1. P. 300−306.
  17. Widodo S., Ariono D., Khoiruddin K., Hakim A.N., Wenten I.G. // Environmental Progress & Sustainable Energy. 2018. V. 37. N 6. P. 1867−1881.
  18. Boadu K.O., Joel O.F., Essumang D.K., Evbuomwan B.O. // Chemical Science International Journal. 2019. V. 26. N 4. P. 1−11.
  19. Ratiu S.A., Mihon N.L., Armioni M.D. // Romanian Journal of Automotive Engineering. 2020. V. 26. N 2.
  20. Pinheiro C.T., Quina M.J., Gando-Ferreira L.M. // Critical Reviews in Environmental Science and Technology. 2021. V. 51. N 18. P. 2015−2050.
  21. Anisuzzaman S.M., Jumaidi M.H., Nasir N.N.M. // IOP Conference Series: Materials Science and Engineering. 2021. V. 1195. No. 1. P. 012031.
  22. Islam M.S., Sanzida N., Rahman M.M., Alam M.D. // Case Studies in Chemical and Environmental Engineering. 2021. V. 4.. P. 100159.
  23. Sánchez-Alvarracín C., Criollo-Bravo J., Albuja-Arias D., García-Ávila F., Pelaez-Samaniego M.R. // Recycling. 2021. V. 6. N 1. P. 10.
  24. Wang Y., Yang Q., Ke L., Peng Y., Liu Y., Wu Q., Tian X., Dai L., Ruan R., Jiang L. // Fuel. 2021. V. 283. P. 119170.
  25. Ratiu S.A., Tirian G.O., Mihon N.L., Armioni M.D. // IOP Conference Series: Materials Science and Engineering. 2022. V. 1220. N 1. P. 012034.
  26. Mandloi H., Thakur L.S. // International Journal for Research in Applied Science and Engineering Technology. 2023. V. 11. N 6. P. 4368−4371.
  27. Nissar A., Hanief M., Mir F.Q. // International Journal of Energy and Water Resources. 2023. V. 7. N 3. P. 453−464.
  28. Sarkar S., Datta D., Deepak K.S., Mondal B.K., Das B. // Journal of Material Cycles and Waste Management. 2023. V. 25. N 4. P. 1935−1965.
  29. Kupareva A., Mäki-Arvela P., Murzin D.Y. // Journal of Chemical Technology & Biotechnology. 2013. V. 88. N 10. P. 1780−1793.
  30. Mynin V.N., Smirnova E.B., Katsereva O.V., Komyagin E.A., Terpugov G.V., Smirnov V.N. // Chemistry and Technology of Fuels and Oils. 2004. V. 40. N 5. P. 345−350.
  31. Psoch C., Wendler B., Goers B., Wozny G., Ruschel B. // Journal of Membrane Science. 2004. V. 245. N 1. P. 113−121.
  32. Gourgouillon D., Schrive L., Sarrade S. // Environmental Science & Technology. 2000. V. 34. N 16. P. 3469−3473.
  33. Gourgouillon D., Schrive L., Sarrade S., Rios G.M. // Separation Science and Technology. 2000. V. 35. N 13. P. 2045−2061.
  34. Sarrade S., Schrive L., Gourgouillon D., Rios G.M. // Application to used oil regeneration. Separation and Purification Technology. 2001. V. 25. N 1. P. 315−321.
  35. Rodriguez C., Sarrade S., Schrive L., Dresch-Bazile M., Paolucci D., Rios G.M. // Desalination. 2002. V. 144. N 1. P. 173−178.
  36. Федосов С.В., Осадчий Ю.П., Маркелов А.В. // Мембраны И Мембранные Технологии. 2020. Т. 10. N 3. C. 177−189.
  37. Федосов С., Осадчий Ю., Маркелов А., Соколов А. // Мембраны и мембранные технологии. 2021. Т. 11. N 6. C. 435−446.
  38. Fedosov S.V., Markelov A.V., Sokolov A.V., Osadchy Yu.P. // Membranes and Membrane Technologies. 2022. V. 4. N 5. P. 297−305.
  39. Cao Y., Yan F., Li J., Liang X., He B. // Desalination and Water Treatment. 2009. V. 11. N 1−3. P. 73−80.
  40. Rouzegari F., Sargolzaei J., Ramezanian N. // Energy Sources, Part A: Recovery, Utilization, and Environmental Effects. V. 0. N 0. P. 1−16.
  41. White L.S., Nitsch A.R. // Journal of Membrane Science. 2000. V. 179. N 1. P. 267−274.
  42. Ariono D., Widodo S., Khoiruddin K., Wardani A.K., Wenten I.G. // IOP Conference Series: Materials Science and Engineering. 2018. V. 395. N 1. P. 012018.
  43. Widodo S., Khoiruddin K., Ariono D., Subagjo S., Wenten I.G. // Journal of Environmental Chemical Engineering. 2020. V. 8. N 3. P. 103789.
  44. Zhu H., Chen K., Sun G., Zhao W., Jiang Q., Xiao C. // Journal of Water Process Engineering. 2023. V. 55. P. 104163.
  45. New Logic Research – Innovative separation solutions since 1987. – URL: https://www.vsep.com/ (дата обращения: 04.10.2024).
  46. Федосов С.В., Блиничев В.Н., Масленников В.А., Осадчий Ю.П., Маркелов А.В. // Известия высших учебных заведений. Химия и химическая технология. 2015. Т. 58. N 8. C. 79−82.
  47. Морозов И.В., Масленников В.А., Осадчий Ю.П., Маркелов А.В. // Аграрный вестник Верхневолжья. 2014. N 3 (8). C. 25.
  48. Nebesskaya A., Kanateva A., Borisov R., Yushkin A., Volkov V., Volkov A. // Polymers. 2024. №16. P. 2910.

Arquivos suplementares

Arquivos suplementares
Ação
1. JATS XML
Baixar
2. Fig. 1. Spectrum of filtration processes.

Baixar (207KB)
Metadados

Declaração de direitos autorais © Russian Academy of Sciences, 2024