Influence of physico-chemical parameters of surface-active systems components for minimization of evaporation of hydrocarbon liquids
No. 31 (2021), CONTENTS
No. 31 (2021)

Influence of physico-chemical parameters of surface-active systems components for minimization of evaporation of hydrocarbon liquids

CONTENTS
https://doi.org/10.15407/kataliz2021.31.084
Published November 7, 2021
O.A. Spas'ka
National Aviation University, Ukraine 03058, Kyiv, Lubomyr Husar Avenue, 1
V.L. Chumak
National Aviation University, Ukraine 03058, Kyiv, Lubomyr Husar Avenue, 1
M.R. Maksymyuk
National Aviation University, Ukraine 03058, Kyiv, Lubomyr Husar Avenue, 1
V.M. Rudenko
National Aviation University, Ukraine 03058, Kyiv, Lubomyr Husar Avenue, 1
O.I. Kosenko
National Aviation University, Ukraine 03058, Kyiv, Lubomyr Husar Avenue, 1
E.V. Polunkin
V.P. Kukhar Institute of Bioorganic Chemistry and Petrochemistry of the National Academy of Sciences of Ukraine, Ukraine 02160, Kyiv, Kharkivske Shosse, 150
O.O. Gaidai
V.P. Kukhar Institute of Bioorganic Chemistry and Petrochemistry of the National Academy of Sciences of Ukraine, Ukraine 02160, Kyiv, Kharkivske Shosse, 150
Article PDF

Keywords

evaporation of hydrocarbon liquids
stability of surface-active system
hydrophilic-lipophilic balance
glass microspheres

How to Cite

Spas’ka, O., Chumak, V., Maksymyuk, M., Rudenko, V., Kosenko, O., Polunkin, E., & Gaidai, O. (2021). Influence of physico-chemical parameters of surface-active systems components for minimization of evaporation of hydrocarbon liquids. Catalysis and Petrochemistry, (31), 84-91. https://doi.org/10.15407/kataliz2021.31.084
ACM ACS APA ABNT Chicago Harvard IEEE MLA Turabian Vancouver

Download Citation

Endnote/Zotero/Mendeley (RIS) BibTeX

Abstract

Highly efficient stable aerated hydrophilic compositions containing fluorotensides and ultralight microdisperse systems using gas-filled glass, aluminosilicate and polymer microspheres have been developed. Designing the compositions of PAS based on the surface activity of surfactants, their solubility in water and the ability to bind water and the formation of hydrogen bonds between the components. The main condition for the stability of the coating when mixing the components - the chemical interaction between them and the formation of a system that does not dissolve in hydrocarbons and does not break down in terms of use. The best film-forming characteristics necessary for the operation of the coating (simultaneous reduction of surface tension and film formation) active substances (FPAR), the non-polar part of the molecules of which contains a fluorocarbon chain, so they are insoluble in hydrocarbons, well soluble in water and easily distributed on the surface of hydrocarbon liquids, creating a protective film. The choice of co-surfactants was based on the ability to stabilize hydrophilic films on the surface of hydrocarbons not only at favorable HLB, but also at the lowest, although higher than the critical concentration of micelle formation (CCM), concentrations for forming a mixed adsorption layer of increased strength. This surfactant was water-oil-soluble twin80, which will significantly increase the hydrophilic part and enhance the stability of the PAS and the stability of the aerated system. The introduction of glass microspheres into the components of the system has significantly enhanced its strength and stability.
In the study of the stability and gas permeability of the developed surfactant systems, it was found that the insulating ability of the coating increases with increasing hydrophilic-lipophilic balance of the system and due to chemical interaction between the carboxyl group of fluorotenside and hydroxyl groups of surfactants.

https://doi.org/10.15407/kataliz2021.31.084
Article PDF

References

Enerhetychna stratehiya Ukrayiny na period do 2035 roku. Tsentr Razumkova, 2020. 67 s.

Pysʹmenna U., Trypolʹsʹka H. Eliminatsiya enerhetychnoyi bidnosti ta yiyi vplyv na enerhetychnu stalistʹ. Visnyk Odesʹkoho natsionalʹnoho universytetu. Ekonomika. 2020. T. 25. Vyp. 1(80). S. 25-32.

Kovalʹov I. V. Dosvid stvorennya stratehichnykh zapasiv nafty i naftoproduktiv u derzhavakh - chlenakh YeS. Formuvannya rynkovykh vidnosyn v Ukrayini. 2009. № 6. S. 106-110.4. Clean energy for all Europeans. URL: https://ec.europa.eu/energy/en/topics/energy-strategy-andenergy-union/clean-energy-all-europeans/

Kwon K.C., Ibrahim T.H., Park YoonKook and Simmons C.M. Pseudo-binary molecular diffusion of vapors into air. Advances in Environmental Research. 2004. V. 8. pp. 667-678. https://doi.org/10.1016/S1093-0191(03)00039-X

Fingas M. F. Modeling oil and petroleum evaporation. Journal of Petroleum Science Research (JPSR). 2013. V. 2. pp. 104-115.

Holmberg K., Jonsson B., Kronberg B. and Lindman B. Surfactants and Polymers in Aqueous Solution. 2nd edition. John Wiley & Sons, Ltd. 2003. P. 547 https://doi.org/10.1002/0470856424

Larking D. M., Mitik-Dineva N., Ivanova E. P., Lonergan G.T. and Crowford R. J. Effective degradation of polyvinyl alcohol by combined chemical and microbial processes. Biotekhnolohiya. 2012. T. 5. № 5. S. 54-64.

Pop H.S., Spasʹka O.A., Bodachivsʹka L.YU. Polehsheni invertni mikrodyspersiyi dlya minimizatsiyi vyparovuvannya vuhlevodnevykh ridyn. Kataliz i naftokhimiya. 2011. №19. S. 95-100.

Patent №29641 MPK B65D 90/22. Ivanov S.V., Spasʹka O.A., Bilokopytov Yu.V. Sposib zapobihannya vyparovuvannyu letkykh vuhlevodnevykh ridyn pry yikh tryvalomu zberihanni. Ukraina. 24.07.2007. Byul. № 2.

Spas'ka O.A. Ultralight surface-active systems for preventing liquid hydrocarbons evaporation. Chemistry and chemical technolodgy. 2016, № 1. pp. 63-66. https://doi.org/10.23939/chcht10.01.063