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Separation of major and minor lipid components using supercritical CO2 coupled with cross-flow reverse osmosis membrane filtration

A reverse osmosis polyamide membrane was used to test the feasibility of concentrating triacylglycerol (TAG) and α-tocopherol/β-sitosterol from model mixtures (Oleic Acid (OA)/TAG and OA/α-tocopherol/β-sitosterol, respectively) solubilized in SC-CO2 using cross-flow filtration regime. SG membrane wa...

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Bibliographic Details
Published in:Journal of membrane science 2018-04, Vol.551, p.333-340
Main Authors: Araus, Karina, Temelli, Feral
Format: Article
Language:English
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Summary:A reverse osmosis polyamide membrane was used to test the feasibility of concentrating triacylglycerol (TAG) and α-tocopherol/β-sitosterol from model mixtures (Oleic Acid (OA)/TAG and OA/α-tocopherol/β-sitosterol, respectively) solubilized in SC-CO2 using cross-flow filtration regime. SG membrane was used for up to 26 h at pressures of 120 and 280 bar and temperature of 40 °C and its performance was measured in terms of CO2 flux and separation factor at a transmembrane pressure of 10 bar. Increasing the pressure to 280 bar resulted in a higher reduction in CO2 flux in comparison to that at 120 bar, which was attributed to fouling. CO2 flux was reestablished after cleaning with pure SC-CO2. Feed pressure of 120 bar showed the best separation factors, where the OA separation factor was higher than 1 and those for TAG and α-tocopherol/β-sitosterol were less than 1. The preferential permeation of OA through the reverse osmosis membranes in comparison to TAG and α-tocopherol/β-sitosterol could be attributed to the higher diffusivity of this smaller molecular weight compound and the effect of plasticization and swelling of the membrane upon exposure to SC-CO2. The cross-flow regime efficiently reduced the extent of fouling and subsequent decline of permeate flux. The findings demonstrate the potential to separate bioactive components present in vegetable oil deodorizer distillate and/or to deacidify vegetable oils using coupled supercritical and membrane technologies. •Coupled system of supercritical CO2 and cross-flow filtration was used.•Binary, ternary and quaternary lipid mixtures were separated.•A reverse osmosis polyamide membrane (SG) was used for up to 26 h at 120 and 280 bar, 40 °C and ∆P of 10 bar.•The slight drop in CO2 flux due to fouling at 280 bar was reestablished with the addition of pure CO2.•The best separation factors were obtained at 120 bar (> 1 for oleic acid and < 1 for TAG and α-tocopherol/β-sitosterol).
ISSN:0376-7388
1873-3123
DOI:10.1016/j.memsci.2018.01.014