Influence of Thermal Effects on the Transport Characteristics of Cellulose Acetate Porous Films

Influence of Thermal Effects on the Transport Characteristics of Cellulose Acetate Porous Films

Experimental data have been obtained, and the characteristics of the moisture content and permeability of cellulose acetate porous materials were analyzed via thermal action. Dynamic thermogravimetric analysis found that the destruction process in an air-dry sample of the membrane begins at 21°C. It...

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Bibliographic Details
Published in:High temperature Vol. 58; no. 6; pp. 812 - 817
Main Authors: Lazarev, S. I., Golovin, Yu. M., Kovalev, S. V., Lazarev, D. S., Levin, A. A.
Format: Journal Article
Language:English
Published: Moscow Pleiades Publishing 01-11-2020
Springer Nature B.V
Subjects:
Atoms and Molecules in Strong Fields
Cellulose acetate
Classical and Continuum Physics
Destruction
Industrial Chemistry/Chemical Engineering
Laser Matter Interaction
Materials Science
Membranes
Moisture content
Permeability
Physical Chemistry
Physics
Physics and Astronomy
Porous materials
Substrates
Temperature
Temperature effects
Thermogravimetric analysis
Thermophysical Properties of Materials
Transport properties
Weight loss
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Summary:Experimental data have been obtained, and the characteristics of the moisture content and permeability of cellulose acetate porous materials were analyzed via thermal action. Dynamic thermogravimetric analysis found that the destruction process in an air-dry sample of the membrane begins at 21°C. It is accompanied by a 2% weight loss and an endothermic effect. The destruction ends at 50°C. With a subsequent increase in temperature, the manifestation of endothermic effect continues a temperature of 120–175°C with the maximum rate of mass loss at 146°C. The weight loss ends at about 190°C and is 6.5%. The study of MGA-80 and MGA-95 porous cellulose acetate films at transmembrane pressure upon temperature exposure showed that the permeability and specific output flow to water increase as the temperature rises to 50°C. Analysis of dependences of the specific output flow on temperature revealed that the specific output flow to water increases by ~18% upon an initial temperature rise of 10°C. This is due to structural changes in the cellulose acetate layer. A further increase in temperature by 15°C leads to an increase in permeability by ~10%. These phenomena are associated with the process of structural transformation in the active layer and the polymer substrate of the MGA-95 and MGA-80P membranes, respectively.
ISSN:0018-151X
1608-3156
DOI:10.1134/S0018151X20060139