Membrane material based on octyl-substituted polymethylsiloxane for separation of C3/C1 hydrocarbons

Membrane material based on octyl-substituted polymethylsiloxane for separation of C3/C1 hydrocarbons

Novel one-step technique has been proposed for octyl-substituted polymethylsiloxane (POMS) synthesis and vulcanization. The technique makes it possible to prepare С 3 /С 1 selective gas separation membranes. The fact of POMS formation and vulcanization by hydrosilylation reaction involving 1-octene...

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Bibliographic Details
Published in:Petroleum chemistry Vol. 57; no. 4; pp. 334 - 340
Main Authors: Grushevenko, E. A., Borisov, I. L., Bakhtin, D. S., Legkov, S. A., Bondarenko, G. N., Volkov, A. V.
Format: Journal Article
Language:English
Published: Moscow Pleiades Publishing 2017
Springer Nature B.V
Subjects:
Chemistry
Chemistry and Materials Science
Hydrosilylation
Industrial Chemistry/Chemical Engineering
Infrared spectroscopy
Materials substitution
Selectivity
vulcanization
POMS
membrane gas separation
polyoctylmethylsiloxane
polymethylhydrosiloxane
separation of hydrocarbons
1,7-octadiene
hydrosilylation
siloxane modification
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Summary:Novel one-step technique has been proposed for octyl-substituted polymethylsiloxane (POMS) synthesis and vulcanization. The technique makes it possible to prepare С 3 /С 1 selective gas separation membranes. The fact of POMS formation and vulcanization by hydrosilylation reaction involving 1-octene and polymethylhydrosiloxane has been confirmed by IR spectroscopy data. On the basis of the results obtained by measuring permeability of POMS membranes to permanent gases and propane, a preferred modifier to crosslinker ratio at which polymer films with the best gas transport properties can be obtained has been estimated at 95/5. Experimentally determined permeability coefficients for methane and propane (270 and 1560 barrer, respectively) and ideal propane/methane selectivity of 5.8 allow for the conclusion that POMS obtained in the study has transport properties comparable to those of similar membrane materials reported in the literature as obtained via multistep synthesis.
ISSN:0965-5441
1555-6239
DOI:10.1134/S0965544117040028