Phase-Field Simulation of the Coalescence of Droplets Permeating through a Fibrous Filter Obtained from X‑ray Computed Tomography Images: Effect of the Filter Microstructure

We numerically study the droplet coalescence of an oil-in-water (O/W) emulsion permeating through a fibrous filter. Our numerical simulation method is based on the phase-field model for capturing a free interface, the immersed boundary method used to calculate fluid–solid interactions, and the wetti...

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Veröffentlicht in:	Langmuir 2020-05, Vol.36 (17), p.4711-4720
Hauptverfasser:	Ueda, Masaki, Rozy, Mohammad Irwan Fatkhur, Fukasawa, Tomonori, Ishigami, Toru, Fukui, Kunihiro
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container_end_page	4720
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creator	Ueda, Masaki Rozy, Mohammad Irwan Fatkhur Fukasawa, Tomonori Ishigami, Toru Fukui, Kunihiro
description	We numerically study the droplet coalescence of an oil-in-water (O/W) emulsion permeating through a fibrous filter. Our numerical simulation method is based on the phase-field model for capturing a free interface, the immersed boundary method used to calculate fluid–solid interactions, and the wetting model that assigns an order parameter to the solid surface according to the wettability. To represent realistic flow inside the filter during simulation, the voxel data obtained from X-ray computed tomography (CT) images of the filter microstructure are used in the simulation. The effects of the filter microstructure, such as fiber arrangement and orientation of the droplet coalescence, are investigated by using several filter domains. Our simulations demonstrate that the arrangement of closely attached fibers placed at the permeate-side surface enhances droplet coalescence. In addition, the parallel orientation of the fiber to the main flow direction suppresses droplet enlargement due to the coalescence but reduces the number of droplet passages without coalescence in the filter.
doi_str_mv	10.1021/acs.langmuir.0c00640
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title	Phase-Field Simulation of the Coalescence of Droplets Permeating through a Fibrous Filter Obtained from X‑ray Computed Tomography Images: Effect of the Filter Microstructure
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