Modification of montmorillonite clay for the selective sorption of argon mixed with oxygen

  • Н. Н. Бурмистрова Burmistrova Natalya N. - past master, department of technology of inorganic substances and electrochemical processes, D.I. Mendeleyev University of Chemical Technology of Russia, Moscow, E-mail: Burmistrova.natasha1994@yandex.ru
  • Е. Н. Иванова Ivanova Ekaterina N. – the postgraduate student, department of technology of inorganic substances and electrochemical processes, D.I. Mendeleyev University of Chemical Technology of Russia, Moscow, E-mail: ivkatushka@gmail.com
  • М. Б. Алехина Alekhina Marina B. – doctor of chemical Sciences, associate prof., department of technology of inorganic substances and electrochemical processes, D.I. Mendeleyev University of Chemical Technology of Russia, Moscow, E-mail: mbalekhina@yandex.ru
  • А. О. Дудоладов Dudoladov Alexander O. – the postgraduate student, department of technology of inorganic substances and electrochemical processes, D.I. Mendeleyev University of Chemical Technology of Russia, Moscow, E-mail: nerfangorn@gmail.com
  • Т. В. Конькова Konkova Tatiana V. - candidate of technical Sciences, associate prof., department of technology of inorganic substances and electrochemical processes, D.I. Mendeleyev University of Chemical Technology of Russia, Moscow, E-mail: kontat@list.ru
  • О. А. Маслова Maslova Olga.A. - candidate of physical and mathematical Sciences, associate prof., department of physical and inorganic chemistry, Altai State University, Barnaul, E-mail: maslova_o.a@mail.ru
DOI: https://doi.org/10.17308/sorpchrom.2017.17/425
Keywords: montmorillonite clay, pillaring, adsorption, oxygen, argon

Abstract

The purpose of this study was to determine optimal conditions for the synthesis of adsorbent based on montmorillonite clays for the selective adsorption of argon from its mixture with oxygen. To determine the conditions for modification of the samples was used the method of experiment planning. The independent factors were chosen: the ratio Al3+/OH-; the temperature of ion exchange; the drying temperature; the calcinations temperature; the ratio Al3+/Cr3+. The area values were as follows: the ratio Al3+/OH- 1:2.0–1:2.4; the temperature of ion exchange 25–75°С; ; the drying temperature 25–85°С; the calcinations temperature 400–550°С; the ratio Al3+/Cr3 0–1. Parameter optimization was the separation factor a gas mixture of argon-oxygen, which is calculated as the ratio of the equilibrium adsorption capacity of argon and oxygen. The paper presents the elemental composition, structural and energy characteristics and data on the adsorption of argon and oxygen on prepared samples. The optimal parameters of medication clays: the ratio Al3+/OH- 1:2.0–1:2.0; the temperature of ion exchange 75°С; ; the drying temperature 25°С; the calcinations temperature 550°С; the ratio Al3+/Cr3 0. The result of pillaring in optimum conditions was obtained the Al-PILC sample with equilibrium adsorption of oxygen and argon 4.50 and 6.70 cm3/g, respectively; the separation factor was 1.5.

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References

1. Shumyatskii Yu.I. Promyshlennye adsorbtsionnye protsessy, M., KolosS Publ., 2009, 184 p.
2. Stepanova M.A., Magazine «RITM», 2012, Vol. 72, No 4, pp. 102-104.
3. Akulov A.K., J. Sfera. Neft' i gaz, 2014, Vol. 42, No 4, pp. 38-42.
4. Vasil'ev A.A., Industriya, 2010, Vol. 98, No 4, pp. 44-45.
5.Kiselev A.V. Mezhmolekulyarnye vzaimodeistviya v adsorbtsii i khromatografii (Intermolecular Interactions in Adsorption and Chromatography). M., Vysshaya Shkola Publ., 1986, 360 p.
6. Alekhina M.B., Kon'kova T.V., Vestnik VGU, seriya: khimiya, biologiya, farmatsiya, 2011, No 2, pp. 67-74.
7. Vahrusheva E.M., Ivanova E.N., Alekhina M.B., Konkova T.V. et al., Uspekhi v himii I himicheskoj tekhnologii, 2013, Vol. 27, No 7 (147), pp. 80-84.
8. Brindley G.W., Sempels R.E., Clay Minerals, 1977, Vol. 12, No 3, pp. 229-237.
9. Scnoonheydt R.A., van den Eynde G., Tubbax H. et al., Clays and Clay Minerals, 1993, Vol. 41, No 5, pp. 598-607.
10. Bottero J.Y.,Cases J.M., Flessinger F., Polrler J.E., J. Phys.Chem., 1980, Vol. 84, No 22, pp. 2933-2939.
11. Zhu H., Lu G., J. of Porous Materials, 1998, Vol. 5, No 3, pp. 227-239.
12. Tarasevich Yu.I. Poverkhnostnye yavleniya na dispersnykh materialakh (Surface phenomena on disperse materials). Kiev, Naukova dumka Publ., 2011, 390 p.
13. Yang R.T., Baksh M.S.A., AIChE J., 1991, Vol.37, No 5, pp. 679-686.
14. Molinard A., Vansant E.E., Adsorption, 1995, Vol. 1, No 1, pp. 49-59.
15. Zhu H.Y., Vansant E.F., J. of Porous Materials, 1995, Vol. 2, No 1, pp. 107-113.
16. Kon'kova T.V., Alekhina M.B., Akhnazarova S.L., Mikhailichenko A.I., Khim. tekhnologiya, 2014, Vol. 15, No 6, pp. 333-337.
17. Akhnazarova S.L., Kafarov V.V. Metody optimizatsii eksperimenta v khimii i khimicheskoi tekhnologii (Methods of Experiment Optimization in Chemistry and Chemical Engineering). Moscow, Vysshaya Shkola Publ., 1985, 327 p.
18. Ivanova E.N., Dudoladov A.O., Alekhina M.B., Konkova T.V. Uspekhi v himii I himicheskoj tekhnologii, 2015, Vol. 28, No 6 (155), pp. 19-21.
19. Alekhina M.B., Ivanova E.N., Burmistrova N.N. «Aktualnye problem teorii adsorbcii, poristosti i adsorbcionnoj selektivnosti», proceedings of the III conference with international participation, Oktober 17-21, 2016, Moscow, 2016, pp. 169-170
20. Kon'kova T.V. Alekhina M.B., Rysev A.P., Sadykov T.F. et al., Perspektivnye materialy, 2013, No 2, pp. 58-63.
Published
2018-02-22
How to Cite
Бурмистрова, Н. Н., Иванова, Е. Н., Алехина, М. Б., Дудоладов, А. О., Конькова, Т. В., & Маслова, О. А. (2018). Modification of montmorillonite clay for the selective sorption of argon mixed with oxygen. Sorbtsionnye I Khromatograficheskie Protsessy, 17(4), 657-666. https://doi.org/10.17308/sorpchrom.2017.17/425
Issue
Vol 17 No 4 (2017): Sorption and chromatographic processes
Section
Статьи