Open Access
E3S Web Conf.
Volume 266, 2021
Topical Issues of Rational Use of Natural Resources 2021
Article Number 08002
Number of page(s) 16
Section Sustainable Development of Regions and Environmental Safety
Published online 04 June 2021
  1. J. Ancheta, HYDRO-MPC technology for heavy oil refining. Journal of Mining Institute 224: 229–234. (2017). [Google Scholar]
  2. A.A. Sukhanov, Y.E. Petrova, The possibility of recycling valuable associated components of heavy oils while increasing the overall efficiency of their development. Oil and gas geology. Theory and Practice 4: 1–13 (2009). [Google Scholar]
  3. E.A. Mustafina, O.Y. Poletaeva, E.M. Movsumzade, Heavy metal oils and their demetallization. Oil and Gas Chemistry 4: 15–18. (2014). [Google Scholar]
  4. B. Issa, et al., Assessment of possibility of obtaining alloying components in the process of desalting of heavy hydrocarbon raw materials. Part 1. CIS Iron and Steel Review 19: 8–12 (2020). [Google Scholar]
  5. A. F. Akhmetov, et al. The state of vanadium (V) in crude oil and petroleum residues. International Journal of Applied Engineering Research 10(21): 42553–42555. (2015). [Google Scholar]
  6. N. A. Mironov, [et al.]. Comparative Study of Resins and Asphaltenes of Heavy Oils as Sources for Obtaining Pure Vanadyl Porphyrins by the Sulfocationite-Based Chromatographic Method. Energy & Fuels. 32(12): 12435–12446. (2018). [Google Scholar]
  7. N. A. Mironov, et al., Methods for Studying Petroleum Porphyrins. Petroleum Chemistry 59(10): 1077–1091. (2019). [Google Scholar]
  8. S. G. Yakubova, et al., Distribution of vanadium and vanadyl porphyrins during fractionation of resins of heavy sulfurous oils. Petroleum Science and Technology, 36(16): 1319–1324. (2018). [Google Scholar]
  9. D.N. Nukenov, S.A. Punanova, Z.G. Agafonova, Metals in oils, their concentration and extraction methods. (Moscow: GEOS, 2001). [Google Scholar]
  10. V.M. Kapustin, V.F. Glagoleva, Physicochemical aspects of petroleum coke formation. Petroleum Chemistry 56(1): 1–9 (2016). [Google Scholar]
  11. E. Nazari, et al., Simultaneous recovery of vanadium and nickel from power plant flyash: Optimization of parameters using response surface methodology. Waste Management 34: 2687–2696. (2014). [Google Scholar]
  12. M. V. Tsygankova, et al., The recovery of vanadium from ash obtained during the combustion of fuel oil at thermal power stations. Russian Journal of Non-Ferrous Metals 52(1): 19–23 (2011). [Google Scholar]
  13. H. Tokuyama, et al., Process development for recovery of vanadium and nickel from heavy oil fly ash by leaching and ion exchange. Separation science and technology 38(6): 1329–1344 (2003). [Google Scholar]
  14. R. Navarro, et al., Vanadium recovery from oil fly ash by leaching, precipitation and solvent extraction processes. Waste Management 27: 425–438 (2007). [Google Scholar]
  15. E. Guibal, et al., Vanadium extraction from fly ash-preliminary study of leaching, solvent extraction, and sorption on chitosan. Separation science and technology journal 38(12): 2881–2899. (2003). [Google Scholar]
  16. R. Parvizi, et al., Hydrometallurgical extraction of vanadium from mechanically milled oil-fired fly ash: analytical process optimization by using Taguchi design method. Metallurgical and materials transactions 43B: 1269–1276 (2012). [Google Scholar]
  17. V.A. Rudko, N.K. Kondrasheva, R.E. Lukonin, The effect of acid leaching parameters on the extraction of vanadium from petroleum coke. Proceedings of SPbGTI(TU) 42: 43–48 (2018). [Google Scholar]
  18. M.R. Tavakoli, S. Dornian, D.B. Dreisinger, The leaching of vanadium pentoxide using sulfuric acid and sulfite as a reducing agent. Hydrometallurgy 141: 59–66. (2014). [Google Scholar]
  19. Y.L. Zhang, L.Q. Yang, X.G. Tian, The effect of sodium sulfate on vanadium leaching From Petroleum coke and surface physical-chemical properties of leaching solution. Petroleum science and technology 33(15): 1492–1498. (2015). [Google Scholar]
  20. S. A. Savchenkov, The research of obtaining master alloys magnesium-gadolinium process by the method of metallothermic recovery. Tsvetnye Metally 5: 33–39 (2019). [Google Scholar]
  21. S.A. Savchenkov, V.Y. Bazhin, V.G. Povarov, Research on the process of gadolinium recovery from the melt of salts on formation of Mg - Zn - Gd master alloys for manufacturing of magnesium and aluminium special-purpose alloys. Non-ferrous Metals 48(1): 35–40. (2020). [Google Scholar]
  22. N.K. Kondrasheva, V.A. Rudko, V.G. Povarov, Determination of sulfur and trace elements in petroleum coke by X-ray fluorescent spectrometry. Coke and Chemistry 60(6): 247–253 (2017). [Google Scholar]
  23. W.L. Bragg, The Structure of Some Crystals as Indicated by Their Diffraction of X-rays. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 89(610): 248–277 (1913). [Google Scholar]
  24. G. Wulff, Über die Kristallröntgenogramme. PhysikalischeZeitschrift 14: 217–220. (1913). [Google Scholar]
  25. P. Scherrer. Bestimmung der innerenStruktur und der Größe von KolloidteilchenmittelsRöntgenstrahlen. (Berlin, Heidelberg: Springer Berlin Heidelberg. 1912). [Google Scholar]
  26. F.R. Feret, Determination of the crystallinity of calcined and graphitic cokes by X-ray diffraction. The Analyst 123(4): 595–600 (1998). [Google Scholar]
  27. A.D. Badikova, et al., Complex technological solution for recycling of spent sulfuric acid from alkylation of isobutane by olefins. Chemistry and Technology of Fuels and Oils 53(1): 29–37 (2017). [Google Scholar]
  28. X. Fan, The Fates of Vanadium and Sulfur Introduced with Petcoke to Lime Kilns. (Toronto. 2010). [Google Scholar]
  29. C. Song, K. Liu, Z. Gong, Y. Liu, Thermogravimetric analysis of combustion characteristics of coal gangue and petroleum coke mixture. Journal of Physics: Conference Series 1324: 12–77 (2019). [Google Scholar]
  30. P.N. Kuznetsov, et al., Comparison of supramolecular organization of brown coal from different deposits. Chemistry for sustainable development 9: 255–261 (2001). [Google Scholar]
  31. E.A. Belenkov, E.A. Karnaukhov, Influence of crystal dimensions on interatomic distances in dispersed carbon. Physics of the Solid State 41(4): 672–675 (1999). [Google Scholar]
  32. Y. Zhu, et al., Preparation and Characterization of Coal Pitch-Based Needle Coke (Part I) : The Effects of Aromatic Index (fa) in Refined Coal Pitch. Energy & Fuels 33(4): 3456–3464. (2019). [Google Scholar]
  33. Y. Zhu, et al., Preparation and Characterization of Coal Pitch-Based Needle Coke (Part II) : The Effects of ß Resin in Refined Coal Pitch. Energy & Fuels 34(2): 2126–2134 (2020). [Google Scholar]
  34. A.N. Popova. Crystallographic analysis of graphite by X-Ray diffraction. Coke and Chemistry 60(9): 361–365 (2017). [Google Scholar]
  35. Z.R. Ismagilov, et al., Structural Analysis of Needle Coke. Coke and Chemistry 62(4): 135–142. (2019). [Google Scholar]

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