Membrane-based solvent extraction of sulfur aroma compounds: influence of operating conditions on mass transfer coefficients in a hollow fiber contactor

Membrane-based solvent extraction is proposed to recover sulfur aroma compounds from an industrial effluent. It consists in transferring the aroma compounds from water into an organic solvent by contacting the two phases inside the pores of a membrane. Mass transfer experiments were performed using...

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Bibliographic Details
Published in:Desalination 2002-09, Vol.148 (1), p.199-204
Main Authors: Pierre, François-Xavire, Souchon, Isabelle, Athes-Dutour, Violaine, Marin, Michèle
Format: Article
Language:English
Subjects:
Biological and medical sciences
Food industries
Fundamental and applied biological sciences. Psychology
General aspects
Liquid—liquid extraction
Microporous membrane
Modeling
Partition coefficient
Pollution and sludges
Solvent viscosity
Volatile
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Summary:Membrane-based solvent extraction is proposed to recover sulfur aroma compounds from an industrial effluent. It consists in transferring the aroma compounds from water into an organic solvent by contacting the two phases inside the pores of a membrane. Mass transfer experiments were performed using a crossflow hollow fiber membrane module, with hexane and miglyol as stripping solvents and synthetic aqueous feed phases with three diluted sulfur compounds. Selective extraction of the aroma compounds is due to the high partition coefficients of aroma compounds between water and the selected solvents. Diffusion inside the organic-filled pores is negligible using hexane, but becomes very important using miglyol, due to its high viscosity. Both tube and shell side compartments are able to receive the feed phase. For these two configurations, mass transfer coefficients are equivalent using hexane as a stripping solvent, but a larger interfacial area is offered when the aqueous feed phase flows in the shell.
ISSN:0011-9164
1873-4464
DOI:10.1016/S0011-9164(02)00698-7