Liquid-liquid extraction using combined hydrophilic-hydrophobic emulsion templated macroporous polymer micromixer-settlers

Hande Barkan-Öztürk, Joanna Delorme, Angelika Menner, Alexander Bismarck (Corresponding author)

Publications: Contribution to journalArticlePeer Reviewed

Abstract

Continuous liquid-liquid extraction and separation of 4-aminoacetophenone, a product of the hydrogenation of 4-nitroacetophenone, was performed within emulsion templated macroporous polymer (polyHIPE) extraction units combined with a miniaturized gravity-based settler. PolyHIPEs with interconnected and tailorable macroporous structures are effective micromixers allowing to mix fluids in both axial and radial directions. We fabricated extraction units by combining hydrophilic and hydrophobic polyHIPEs, which improved the extraction efficiency by inverting the liquid/liquid dispersion type from oil/water to water/oil (or vice versa) during the extraction. The dispersion type is governed by the wettability of the porous medium. The extraction efficiency of our combined polyHIPE micromixer reached 98%, while that of control experiments performed using a blank tube or commercial Kenics® static mixer was 78%. The overall volumetric mass transfer coefficient k La in polyHIPE micromixer-settlers was significantly higher 0.011 s −1 reaching interfacial areas a of 17900 m 2/m 3, much larger compared to a blank tube (k La = 0.0035 s −1 and a = 5700 m 2/m 3) and static mixer (k La = 0.0041 s −1 and a = 6800 m 2/m 3). PolyHIPE micromixer-settlers could be potentially useful to intensify continuous L-L extractions.

Original languageEnglish
Article number109153
Number of pages10
JournalChemical Engineering and Processing - Process intensification
Volume181
DOIs
Publication statusPublished - Nov 2022

Austrian Fields of Science 2012

  • 104017 Physical chemistry
  • 204004 Organic chemical technology
  • 104019 Polymer sciences

Keywords

  • L -L extraction
  • PolyHIPEs
  • Volumetric mass transfer coefficient
  • Extraction efficiency
  • MASS-TRANSFER PERFORMANCE
  • FLOW
  • CAPILLARY
  • MONOLITHS
  • SUPPORTS
  • DROP
  • L-L extraction

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