Affiliation:
1. MIREA – Russian Technological University University
2. Mendeleev University of Chemical Technology of Russia
Abstract
Objectives. To investigate the swelling of the main types of rubbers used in the rubber industry in carbon dioxide in a supercritical state (SC-CO2), in order to assess the possibility of obtaining elastomeric materials with porous structures using fluid technology, based on them.Methods. The process of swelling of rubbers in SC-CO2 and subsequent foaming was carried out according to a specially developed technique using the original installation. This is a high-pressure apparatus with transparent windows, allowing for the use of an optical technique to directly measure the geometric dimensions of samples during swelling and foaming using a digital video camera. The study of the porous structure of foamed rubbers was carried out using scanning electron microscopy.Results. The study established experimental curves of the swelling kinetics in SC-CO2 of isoprene, butadiene, styrene butadiene, ethylene propylene, chloroprene, ethylene acrylate, siloxane, and organofluorine rubbers. The influence of temperature and pressure on the rate and equilibrium degree of swelling was studied. The diffusion coefficients of SC-CO2 in rubbers of various chemical natures were also determined.Conclusions. It was shown that the equilibrium swelling degree of rubbers in SC-CO2 depends on the chemical nature of rubbers. It does not correlate with the value of their solubility parameters, changes directly proportional to the diffusion coefficient and increases with increasing temperature and pressure. It was found that irrespective of the degree of swelling in SC-CO2, all the rubbers studied are intensively foamed at a sharp pressure drop. The size of the pores formed is tens of microns: significantly smaller than the size of pores formed when chemical pore formers are used.
Reference20 articles.
1. Arzhakova O.V., Arzhakov M.S., Badamshina E.R., Bryuzgina E.B., Bryuzgin E.V., et al. Polymer for the future. Russ. Chem. Rev. 2022;91(12):RCR5062. https://doi.org/10.57634/RCR5062
2. Sarver J.A., Kiran E. Foaming of polymers with carbon dioxide – The year-in-review – 2019. J. Supercritical Fluids. 2021;173:105166. https://doi.org/10.1016/j.supflu.2021.105166
3. Bruno T.J., Ely J.F. Supercritical Fluid Technology: Reviews in Modern Theory and Applications. Taylor & Francis Group; 2017. 606 p. ISBN 978-11-385-07-005
4. McHugh M.A., Krukonis V.J. Supercritical Fluid Extraction: Principles and Practice. Stoneham: Butterworth Publishers; 1986. 507 p.
5. Razgonova M.P., Zakharenko A.M., Sergievich A.A. Sverkhkriticheskie flyuidy: teoriya, etapy stanovleniya, sovremennoe primenenie: uchebnoe posobie (Supercritical Fluids: Theory, Stages of Formation, Modern Application: textbook). St. Petersburg: Lan; 2019. 192 p. (in Russ). ISBN 978-5-8114-3915-7