Evaluation of the possibility of separating commercial phenol from the phenolic fraction of coal tar

Y.O. Schastnyy; N.A. Romanova; R.R. Gizatullin

doi:10.1051/e3sconf/202126602011

All issues

Volume 266 (2021)

E3S Web Conf., 266 (2021) 02011

References

Open Access

Issue		E3S Web Conf. Volume 266, 2021 Topical Issues of Rational Use of Natural Resources 2021


Article Number		02011
Number of page(s)		8
Section		Technologies of Complex Processing of Mineral Raw Materials
DOI		https://doi.org/10.1051/e3sconf/202126602011
Published online		04 June 2021

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R. Y. Feshchenko, O. O. Erokhina, V. L. Ugolkov, M. Y. Shabalov, V. V. Vasiliev. Thermal analysis of coal ash. Coke and Chemistry, 1, 17–22 (2017) [Google Scholar]
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T. Jiao, X. Qin, H. Zhang, W. Zhang, Y. Zhang, P. Liang. Separation of phenol and pyridine from coal tar via liquid-liquid extraction using deep eutectic solvents. Chemical Engineering Research and Design, 145, 112–121 (2019) [Google Scholar]
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X. Yang, B. Wang, H. Luo, S. Yan, J. Dai, Z. Bai. Efficient recovery of phenol from coal tar processing wastewater with tributylphosphane/diethyl carbonate/cyclohexane: Extraction cycle and mechanism study. Chemical Engineering Research and Design, 157, 104–113 (2020) [Google Scholar]
S. Mohammadi, A. Kargari, H. Sanaeepur, K. Abbassian, A. Najafi. Phenol removal from industrial wastewaters: a short review. Desalination and Water Treatment, 53, 2215–2234 (2014) [Google Scholar]
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[1] V. Y. Bazhin. Change in the thermoplasticity of low-grade coal in the selective extraction of metals. Journal of Mining Institute, 220, 578–581 (2016) [Google Scholar]

[2] V. Y. Bazhin. Application of heat flow calorimetry for the development of mathematical models of coal coking processes. Coke and chemistry, 7, 25–29 (2015) [Google Scholar]

[3] R. Y. Feshchenko, O. O. Erokhina, A. L. Kvanin, D. S. Lutskiy, V. V. Vasiliev. Analytical review of the foreign publications about the methods of the rise of operating parameters of cathode blocks during 1995-2014. CIS Iron and Steel Review, 13, 48–52 (2017) [Google Scholar]

[4] R. Y. Feshchenko, O. O. Erokhina, V. L. Ugolkov, M. Y. Shabalov, V. V. Vasiliev. Thermal analysis of coal ash. Coke and Chemistry, 1, 17–22 (2017) [Google Scholar]

[5] V. R. Kabirov, D. V. Gorlenkov, R. Y. Feshchenko, E. A. Kochetkova, M. O. Silivanov. Applications of vacuum rectification for energy optimization of the fractional facility of benzene and toluene. Journal of Physics: Conference Series, 1313, 1–5 (2019) [Google Scholar]

[6] S. A. Semenova, O. M. Gavrilyuk, Y. F. Patrakov. Analysis of the component composition of coal coking resin group fractions. Bulletin of the Kuzbass state technical University, 5, 135–139 (2010) [Google Scholar]

[7] V. I. Lobzin, S. V. Mochalnikov, G. A. Solodov, A. V. Nevedrov, A. V. Papin. Production of target commercial products by deep processing of coal tar fractions. Proceedings of Tomsk Polytechnic University, 301(2), 149–151 (2007) [Google Scholar]

[8] O. N. Pavlovich, Composition, properties, and prospects of coal tar processing: educational electronic text edition. (Yekaterinburg: Publishing house GOU VPO UGTU-UPI, 2006) [Google Scholar]

[9] I. A. Oshchepkov, I. M. Zinchenko. Features of coal tar formation and processing. Bulletin of the Kuzbass state technical University, 2, 78–82 (2009) [Google Scholar]

[10] V. M. Zakoshansky. Alternative technologies for obtaining phenol. Russian Chemical Journal, 52(4), 53–71 (2008) [Google Scholar]

[11] M. I. Baykenov, S. K. Amerkhanova, G. G. Baykenova, R. M. Slepov, A. E. Toktybaeva. and Extraction cavitation extraction of phenols from coal tar. Solid fuel chemistry 1, 28p. (2013) [Google Scholar]

[12] V. M. Zakoshansky. Cumene process for the production of phenol-acetone. Petrochemistry, 47(4), 301–314 (2008) [Google Scholar]

[13] E. Rigaut, M. Kleiber, C. Rioual, J. E. Diaz. Process for treatment of phenol and tar acids containing oil. European patent specification. International publication number: WO 2010/100536 (10.09.2010 Gazette 2010/36), International application number: PCT/IB2010/000377, (2014) [Google Scholar]

[14] Y. Zhao, X. Mao, W. Li, X. Gu, G. Wang. Study on extraction phenol from coal tar with high flux centrifugal extractor. International Journal of Coal Science & Technology, 4, 333–341 (2017) [Google Scholar]

[15] T. Jiao, X. Qin, H. Zhang, W. Zhang, Y. Zhang, P. Liang. Separation of phenol and pyridine from coal tar via liquid-liquid extraction using deep eutectic solvents. Chemical Engineering Research and Design, 145, 112–121 (2019) [Google Scholar]

[16] T. Jiao, C. Li, X. Zhuang, S. Cao, H. Chen, S. Zhang. The new liquid-liquid extraction method for separation of phenolic compounds from coal tar. Chemical Engineering Journal, 266, 148–155 (2015) [Google Scholar]

[17] T. Jiao, C. Li, X. Zhuang, S. Cao, H. Chen, S. Zhang Separation of Phenolic Compounds from Coal Tar via Liquid-Liquid Extraction Using Amide-Compounds. Industrial & Engineering Chemistry Research, 54, 2573–2579 (2015) [Google Scholar]

[18] X. Yang, B. Wang, H. Luo, S. Yan, J. Dai, Z. Bai. Efficient recovery of phenol from coal tar processing wastewater with tributylphosphane/diethyl carbonate/cyclohexane: Extraction cycle and mechanism study. Chemical Engineering Research and Design, 157, 104–113 (2020) [Google Scholar]

[19] S. Mohammadi, A. Kargari, H. Sanaeepur, K. Abbassian, A. Najafi. Phenol removal from industrial wastewaters: a short review. Desalination and Water Treatment, 53, 2215–2234 (2014) [Google Scholar]

[20] V. S. Leontiev. Energy optimization of multi-column rectification complexes. Electronic scientific journal “Oil and Gas Business”, 2, 245–254 (2012) [Google Scholar]

[21] V. B. Kogan, Azeotropic and extractive rectification, (2-nd ed.), (Leningrad: Chemistry, 1971) [Google Scholar]