Viscosity Ratio Influence on Liquid-Liquid Flow in a T-shaped Microchannel

被引:15
|
作者
Kovalev, Alexander V. [1 ,2 ]
Yagodnitsyna, Anna A. [1 ,2 ]
Bilsky, Artur V. [1 ,2 ]
机构
[1] RAS, SB, Kutateladze Inst Thermophys, Lavrentieva Ave,1, Novosibirsk 630090, Russia
[2] Novosibirsk State Univ, Dept Phys, Pirogova,2, Novosibirsk 630090, Russia
来源
CHEMICAL ENGINEERING & TECHNOLOGY | 2021年 / 44卷 / 02期
基金
俄罗斯基础研究基金会;
关键词
Flow patterns; Liquid‐ liquid flows; Microchannels; Plug flows; Viscosity ratios; DROPLET FORMATION; RECTANGULAR MICROCHANNEL; MASS-TRANSFER; HYDRODYNAMICS; PATTERNS;
D O I
10.1002/ceat.202000396
中图分类号
TQ [化学工业];
学科分类号
0817 ;
摘要
The ratio of the dispersed phase viscosity to that of the continuous phase is a critical parameter for microfluidic two-phase flows. Here, the influence of the viscosity ratio on liquid-liquid flow in T-shaped microchannels is studied experimentally. Three basic flow patterns, i.e., parallel, plug, and droplet flow, are observed for different sets of immiscible liquids. Flow pattern maps are plotted and generalized using a combination of Weber and Ohnesorge dimensionless numbers. In the plug flow pattern, interface deformations occur for low viscosity ratios. Existing correlations from the literature are tested against experimental data for plug velocity and lengths. Despite the significant plug interface deformations, the influence of the viscosity ratio on the plug length and velocity is negligible.
引用
收藏
页码:365 / 370
页数:6
相关论文
共 50 条
  • [21] Modeling the flow of liquid-metal coolant in the T-shaped mixer
    O. N. Kashinsky
    P. D. Lobanov
    A. S. Kurdyumov
    N. A. Pribaturin
    Thermophysics and Aeromechanics, 2016, 23 : 379 - 382
  • [22] Modeling the flow of liquid-metal coolant in the T-shaped mixer
    Kashinsky, O. N.
    Lobanov, P. D.
    Kurdyumov, A. S.
    Pribaturin, N. A.
    THERMOPHYSICS AND AEROMECHANICS, 2016, 23 (03) : 379 - 382
  • [23] Liquid-liquid flow patterns and slug characteristics in cross-shaped square microchannel for cryogel beads preparation
    Guan, Tingting
    Yan, Qin
    Wan, Lizhi
    Zhang, Songhong
    Xu, Linhong
    Wang, Jianli
    Yun, Junxian
    CHEMICAL ENGINEERING RESEARCH & DESIGN, 2019, 148 : 312 - 320
  • [24] Formation and flow behavior of micellar membranes in a T-shaped microchannel
    Cardiel, Joshua J.
    Takagi, Daisuke
    Tsai, Hsieh-Fu
    Shen, Amy Q.
    SOFT MATTER, 2016, 12 (39) : 8226 - 8234
  • [25] Comparative study of static and dynamic wetting properties of liquid-liquid phase in PMMA microfluidic T-shaped device
    Omer, Ahmed
    Bashir, Shazia
    Bashir, Muhammad
    Inayat, Mansoor H.
    Amin, Muhammad Abid
    Naveed, Muhammad
    PROCEEDINGS OF 2017 14TH INTERNATIONAL BHURBAN CONFERENCE ON APPLIED SCIENCES AND TECHNOLOGY (IBCAST), 2017, : 492 - 496
  • [26] Liquid-Liquid Two-Phase Flow Patterns in a Serpentine Microchannel
    Sarkar, P. S.
    Singh, K. K.
    Shenoy, K. T.
    Sinha, A.
    Rao, H.
    Ghosh, S. K.
    INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 2012, 51 (13) : 5056 - 5066
  • [27] Dynamics of droplet adsorption at the liquid-liquid interface of parallel flow in a microchannel
    Yi, Haozhe
    Fu, Taotao
    Zhu, Chunying
    Ma, Youguang
    COLLOIDS AND SURFACES A-PHYSICOCHEMICAL AND ENGINEERING ASPECTS, 2024, 686
  • [28] Circulation microchannel for liquid-liquid microextraction
    Kikutani, Yoshikuni
    Mawatari, Kazuma
    Hibara, Akihide
    Kitamori, Takehiko
    MICROCHIMICA ACTA, 2009, 164 (3-4) : 241 - 247
  • [29] Liquid-liquid two-phase flow patterns in a rectangular microchannel
    Zhao, Yuchao
    Chen, Guangwen
    Yuan, Quan
    AICHE JOURNAL, 2006, 52 (12) : 4052 - 4060
  • [30] Droplet motion in a microchannel: The influence of electrokinetic effects at liquid-liquid interfaces
    Wang, Chengfa
    Gao, Qi
    Song, Yongxin
    INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER, 2024, 226
12345