Plug flow of immiscible liquids with low viscosity ratio in serpentine microchannels

Standard

Plug flow of immiscible liquids with low viscosity ratio in serpentine microchannels. / Kovalev, Alexander ; Yagodnitsyna, Anna; Bilsky, Artur.

в: Chemical Engineering Journal, Том 417, 127933, 01.08.2021.

Результаты исследований: Научные публикации в периодических изданиях › статья › Рецензирование

Harvard

Kovalev, A , Yagodnitsyna, A & Bilsky, A 2021, 'Plug flow of immiscible liquids with low viscosity ratio in serpentine microchannels', Chemical Engineering Journal, Том. 417, 127933. https://doi.org/10.1016/j.cej.2020.127933

APA

Kovalev, A., Yagodnitsyna, A., & Bilsky, A. (2021). Plug flow of immiscible liquids with low viscosity ratio in serpentine microchannels. Chemical Engineering Journal, 417, [127933]. https://doi.org/10.1016/j.cej.2020.127933

Vancouver

Kovalev A , Yagodnitsyna A, Bilsky A. Plug flow of immiscible liquids with low viscosity ratio in serpentine microchannels. Chemical Engineering Journal. 2021 авг. 1;417:127933. Epub 2020 дек. 2. doi: 10.1016/j.cej.2020.127933

Author

Kovalev, Alexander ; Yagodnitsyna, Anna ; Bilsky, Artur. / Plug flow of immiscible liquids with low viscosity ratio in serpentine microchannels. в: Chemical Engineering Journal. 2021 ; Том 417.

BibTeX

@article{639f054915174b3f9bfb18aa8db00230,

title = "Plug flow of immiscible liquids with low viscosity ratio in serpentine microchannels",

abstract = "The paper aims to assess hydrodynamic features of liquid–liquid flows in serpentine microchannels to control mixing and mass transfer. Segmented or plug flow of the oil–water system in serpentine microchannels with different curvatures is studied. The novelty of the topic consists in the use of multiple bends of high curvature (width to curvature radius ratio β = 1) in conjunction with the low viscosity ratio of phases (λ = 0.001). Plug acceleration/deceleration in straight parts and bends depends on the channel curvature and leads to a drastic change in the plug length. Plug elongation is more pronounced for higher channel curvature and is found to be a linear function on the capillary number. Plug rupture is discovered in the microchannel with β = 1. Flow structure in both the oil slugs and aqueous plugs is visualized using laser-induced fluorescence and particle tracking velocimetry techniques. Qualitatively different flow patterns in oil slugs are revealed depending on the bend curvature. In the aqueous plugs additional vortex appears due to curvature influence and intensifies for higher curvature. Optimal conditions for efficient mixing and mass transfer in the plug flow regime are stated.",

keywords = "Curvature, Flow structure, Immiscible liquids, Plug flow, Serpentine microchannel",

author = "Alexander Kovalev and Anna Yagodnitsyna and Artur Bilsky",

year = "2021",

month = aug,

day = "1",

doi = "10.1016/j.cej.2020.127933",

language = "English",

volume = "417",

journal = "Chemical Engineering Journal",

issn = "1385-8947",

publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Plug flow of immiscible liquids with low viscosity ratio in serpentine microchannels

AU - Kovalev, Alexander

AU - Yagodnitsyna, Anna

AU - Bilsky, Artur

PY - 2021/8/1

Y1 - 2021/8/1

N2 - The paper aims to assess hydrodynamic features of liquid–liquid flows in serpentine microchannels to control mixing and mass transfer. Segmented or plug flow of the oil–water system in serpentine microchannels with different curvatures is studied. The novelty of the topic consists in the use of multiple bends of high curvature (width to curvature radius ratio β = 1) in conjunction with the low viscosity ratio of phases (λ = 0.001). Plug acceleration/deceleration in straight parts and bends depends on the channel curvature and leads to a drastic change in the plug length. Plug elongation is more pronounced for higher channel curvature and is found to be a linear function on the capillary number. Plug rupture is discovered in the microchannel with β = 1. Flow structure in both the oil slugs and aqueous plugs is visualized using laser-induced fluorescence and particle tracking velocimetry techniques. Qualitatively different flow patterns in oil slugs are revealed depending on the bend curvature. In the aqueous plugs additional vortex appears due to curvature influence and intensifies for higher curvature. Optimal conditions for efficient mixing and mass transfer in the plug flow regime are stated.

AB - The paper aims to assess hydrodynamic features of liquid–liquid flows in serpentine microchannels to control mixing and mass transfer. Segmented or plug flow of the oil–water system in serpentine microchannels with different curvatures is studied. The novelty of the topic consists in the use of multiple bends of high curvature (width to curvature radius ratio β = 1) in conjunction with the low viscosity ratio of phases (λ = 0.001). Plug acceleration/deceleration in straight parts and bends depends on the channel curvature and leads to a drastic change in the plug length. Plug elongation is more pronounced for higher channel curvature and is found to be a linear function on the capillary number. Plug rupture is discovered in the microchannel with β = 1. Flow structure in both the oil slugs and aqueous plugs is visualized using laser-induced fluorescence and particle tracking velocimetry techniques. Qualitatively different flow patterns in oil slugs are revealed depending on the bend curvature. In the aqueous plugs additional vortex appears due to curvature influence and intensifies for higher curvature. Optimal conditions for efficient mixing and mass transfer in the plug flow regime are stated.

KW - Curvature

KW - Flow structure

KW - Immiscible liquids

KW - Plug flow

KW - Serpentine microchannel

UR - http://www.scopus.com/inward/record.url?scp=85097788712&partnerID=8YFLogxK

U2 - 10.1016/j.cej.2020.127933

DO - 10.1016/j.cej.2020.127933

M3 - Article

AN - SCOPUS:85097788712

VL - 417

JO - Chemical Engineering Journal

JF - Chemical Engineering Journal

SN - 1385-8947

M1 - 127933

ER -

ID: 27082913