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Influence of dispersed phase flow-rate pulsations on the liquid–liquid parallel flow in a T-junction microchannel. / Ковалев, Александр Владиславович; Первунин, Константин Сергеевич; Бильский, Артур Валерьевич et al.

In: Chemical Engineering Journal, Vol. 488, 150734, 15.05.2024.

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Ковалев АВ, Первунин КС, Бильский АВ, Ягодницына АА. Influence of dispersed phase flow-rate pulsations on the liquid–liquid parallel flow in a T-junction microchannel. Chemical Engineering Journal. 2024 May 15;488:150734. doi: 10.1016/j.cej.2024.150734

Author

Ковалев, Александр Владиславович ; Первунин, Константин Сергеевич ; Бильский, Артур Валерьевич et al. / Influence of dispersed phase flow-rate pulsations on the liquid–liquid parallel flow in a T-junction microchannel. In: Chemical Engineering Journal. 2024 ; Vol. 488.

BibTeX

@article{80531eb040bf42e096a92676bc4bb756,
title = "Influence of dispersed phase flow-rate pulsations on the liquid–liquid parallel flow in a T-junction microchannel",
abstract = "Active flow control in microfluidic devices to broaden the range of desired conditions is a significant practical concern. In this study, we experimentally investigate liquid–liquid parallel flow under the dispersed phase flow-rate pulsations in a T-junction microchannel. Sinusoidal flow rate disturbances with variations in amplitude and period were applied to dispersed phases of different viscosities. The study involves flow visualization and velocity field measurements using the micro-PIV technique for both free and excited flow conditions. The analysis of flow pattern maps, velocity fields, velocity gradients, and phase-averaged velocity profiles in a T-junction region and far downstream provided insights into the evolution of disturbances, which is different in low- and high-viscosity liquids. In the less viscous liquid, transverse waves amplify longitudinal ones due to relaxation of the liquid–liquid interface, while in the high-viscosity dispersed phase, longitudinal waves are damped significantly, with the transverse wave amplitude remaining almost constant. As a result, we revealed two distinct mechanisms of disturbance wave propagation and the loss of parallel flow stability, which are both dependent on the Ohnesorge number of the dispersed phase. Destabilization of the parallel flow led to the formation of plugs with a narrow length distribution. Single-mode, double-mode, triple-mode, and multi-mode plug formation regimes were identified. The results of the study can potentially be used to extend the range of segmented flow regimes and generate plugs of a desired length.",
keywords = "Microchannel, Liquid–liquid flow, Flow pattern map, Pulsatile flow, Parallel flow stability, Active control, Active control, Flow pattern map, Liquid–liquid flow, Microchannel, Parallel flow stability, Pulsatile flow",
author = "Ковалев, {Александр Владиславович} and Первунин, {Константин Сергеевич} and Бильский, {Артур Валерьевич} and Ягодницына, {Анна Александровна}",
note = "The research was funded by the Russian Science Foundation (Project No. 21-79-10307).",
year = "2024",
month = may,
day = "15",
doi = "10.1016/j.cej.2024.150734",
language = "English",
volume = "488",
journal = "Chemical Engineering Journal",
issn = "1385-8947",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Influence of dispersed phase flow-rate pulsations on the liquid–liquid parallel flow in a T-junction microchannel

AU - Ковалев, Александр Владиславович

AU - Первунин, Константин Сергеевич

AU - Бильский, Артур Валерьевич

AU - Ягодницына, Анна Александровна

N1 - The research was funded by the Russian Science Foundation (Project No. 21-79-10307).

PY - 2024/5/15

Y1 - 2024/5/15

N2 - Active flow control in microfluidic devices to broaden the range of desired conditions is a significant practical concern. In this study, we experimentally investigate liquid–liquid parallel flow under the dispersed phase flow-rate pulsations in a T-junction microchannel. Sinusoidal flow rate disturbances with variations in amplitude and period were applied to dispersed phases of different viscosities. The study involves flow visualization and velocity field measurements using the micro-PIV technique for both free and excited flow conditions. The analysis of flow pattern maps, velocity fields, velocity gradients, and phase-averaged velocity profiles in a T-junction region and far downstream provided insights into the evolution of disturbances, which is different in low- and high-viscosity liquids. In the less viscous liquid, transverse waves amplify longitudinal ones due to relaxation of the liquid–liquid interface, while in the high-viscosity dispersed phase, longitudinal waves are damped significantly, with the transverse wave amplitude remaining almost constant. As a result, we revealed two distinct mechanisms of disturbance wave propagation and the loss of parallel flow stability, which are both dependent on the Ohnesorge number of the dispersed phase. Destabilization of the parallel flow led to the formation of plugs with a narrow length distribution. Single-mode, double-mode, triple-mode, and multi-mode plug formation regimes were identified. The results of the study can potentially be used to extend the range of segmented flow regimes and generate plugs of a desired length.

AB - Active flow control in microfluidic devices to broaden the range of desired conditions is a significant practical concern. In this study, we experimentally investigate liquid–liquid parallel flow under the dispersed phase flow-rate pulsations in a T-junction microchannel. Sinusoidal flow rate disturbances with variations in amplitude and period were applied to dispersed phases of different viscosities. The study involves flow visualization and velocity field measurements using the micro-PIV technique for both free and excited flow conditions. The analysis of flow pattern maps, velocity fields, velocity gradients, and phase-averaged velocity profiles in a T-junction region and far downstream provided insights into the evolution of disturbances, which is different in low- and high-viscosity liquids. In the less viscous liquid, transverse waves amplify longitudinal ones due to relaxation of the liquid–liquid interface, while in the high-viscosity dispersed phase, longitudinal waves are damped significantly, with the transverse wave amplitude remaining almost constant. As a result, we revealed two distinct mechanisms of disturbance wave propagation and the loss of parallel flow stability, which are both dependent on the Ohnesorge number of the dispersed phase. Destabilization of the parallel flow led to the formation of plugs with a narrow length distribution. Single-mode, double-mode, triple-mode, and multi-mode plug formation regimes were identified. The results of the study can potentially be used to extend the range of segmented flow regimes and generate plugs of a desired length.

KW - Microchannel

KW - Liquid–liquid flow

KW - Flow pattern map

KW - Pulsatile flow

KW - Parallel flow stability

KW - Active control

KW - Active control

KW - Flow pattern map

KW - Liquid–liquid flow

KW - Microchannel

KW - Parallel flow stability

KW - Pulsatile flow

UR - https://www.scopus.com/record/display.uri?eid=2-s2.0-85189444874&origin=inward&txGid=9db982611fabc35dc8c2171092326d5c

UR - https://www.mendeley.com/catalogue/0c410857-5f8b-3b2d-8110-55432bc00a09/

U2 - 10.1016/j.cej.2024.150734

DO - 10.1016/j.cej.2024.150734

M3 - Article

VL - 488

JO - Chemical Engineering Journal

JF - Chemical Engineering Journal

SN - 1385-8947

M1 - 150734

ER -

ID: 60030723