Experimental Studies of Droplet Formation Process and Length for Liquid–Liquid Two-Phase Flows in a Microchannel

Li, Lei; Zhao, Yuting; Chen, Wukai; Li, Huiling; Wang, Xinyu; Zhang, Jingzhi

doi:10.3390/en14051341

Cited by 23 publications

(10 citation statements)

References 56 publications

(78 reference statements)

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“…The average diameter of water droplets varied between 75 µm and 225 µm (red and green data points) with a coefficient of variation between 3% and 6%, while the volume percent of inner water phase in the oil phase was between 7 vol% and 50 vol% (also for red and green points). For flow focusing devices, the dimensionless droplet diameter in dripping regime can be estimated from the following scaling law [33]:…”

Section: Morphology Of Multiple Emulsion Dropletsmentioning

confidence: 99%

Novel glass capillary microfluidic devices for the flexible and simple production of multi-cored double emulsions

Leister

Vladisavljević

Karbstein

2022

Journal of Colloid and Interface Science

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Section: Morphology Of Multiple Emulsion Dropletsmentioning

confidence: 99%

Novel glass capillary microfluidic devices for the flexible and simple production of multi-cored double emulsions

Leister

Vladisavljević

Karbstein

2022

Journal of Colloid and Interface Science

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“…Ca has a relation with j G / j L while certain value deviates from the line due to effects of their viscosity and surface tension 45 , 46 . L S is decreased with increasing Ca since the capillary number intensifies shearing effect of two fluids 56 . Higher Ca means increased viscous force and the interface between two phases experiences higher shear stress.…”

Section: Resultsmentioning

confidence: 99%

Quantitative study for control of air–liquid segmented flow in a 3D-printed chip using a vacuum-driven system

Hong

Song

Yeom

2022

Sci Rep

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The formation of droplets or bubbles in a microfluidic system is a significant topic requiring device miniaturization and a small volume of samples. Especially, a two-phase segmented flow can be applied to micro-mixing for chemical reactions and the treatment of heat and mass transfer. In this study, a flow of liquid slugs and bubbles was generated in a 3D-printed chip and controlled by a single pump creating a vacuum at the outlet. The pump and chip device were integrated to form a simple and portable system. The size and flow rate of liquid slugs, obtained through image processing techniques, were analyzed considering several parameters related to hydraulic resistance and pressure drop. In addition, the effect of segmentation on mixing was observed by measuring the intensity change using two different colored inks. The hydraulic resistance of air and liquid flows can be controlled by changing the tube length of air flow and the viscosity of liquid flow. Because the total pressure drop along the channel was produced using a single pump at the outlet of the channel, the size and flow rate of the liquid slugs showed a near linear relation depending on the hydraulic resistances. In contrast, as the total pressure varied with the flow rate of the pump, the size of the liquid slugs showed a nonlinear trend. This indicates that the frequency of the liquid slug formation induced by the squeezed bubble may be affected by several forces during the development of the liquid slugs and bubbles. In addition, each volume of liquid slug segmented by the air is within the range of 10–1 to 2 µL for this microfluidic system. The segmentation contributes to mixing efficiency based on the increased homogeneity factor of liquid. This study provides a new insight to better understand the liquid slug or droplet formation and predict the segmented flow based on the relationship between the resistance, flow rate, and pressure drop.

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“…4a) was formed. This pattern is dominated by the strong shear and drag forces of the continuous phase (Lei et al, 2021).…”

Section: Figmentioning

confidence: 99%

“…In this pattern, the dispersed phase remains stuck to the channel wall and pulled away from the junction due to the drag force exerted by the continuous phase. Then, the high shear of the continuous phase causes the dispersed phase to break up rapidly into small droplets (Lei et al, 2021). These droplets are usually much smaller than the width of the microchannel.…”

Section: Figmentioning

confidence: 99%

Numerical Investigation of Flow Patterns and Plug Hydrodynamics in a 3D T-junction Microchannel

Said

BOUDA

Harmand

2023

Microgravity Sci. Technol.

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A three-dimensional (3D) numerical simulation of two-phase flow liquid/liquid is performed in a rectangular microchannel with a T-junction. The volume of fluid (VOF) method was used under ANSYS Fluent to capture the interface between the two phases. The dynamic mesh adaptation technique together with the assumption of symmetry plane helps us to reduce the computational cost.The study focuses on the flow patterns and hydrodynamics of plugs. So, the influence of the flow rate ratio 𝑞, the capillary number 𝐶𝑎, and the viscosity ratio  on the liquid film, the plug/droplet shape, and velocity are examined here. Particularly, the plug/droplet lengths predicted by the simulation show good agreement with experimental and correlation available in the literature.The results revealed six distinct flow patterns by dispersing water in a continuous phase of silicone oil. By decreasing the flow rate ratio as well as the viscosity ratio, the liquid film thickness increases in the corners and side planes. In turn, this greatly impacts the liquid film velocity and the plug velocity. Furthermore, capillary number (based on two-phase flow velocity 𝑈 𝑇𝑃 ) is also shown to have a greater impact than viscosity ratio and flow rate ratio on plug shape, with the tail curvature always larger than the front curvature.

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Experimental Studies of Droplet Formation Process and Length for Liquid–Liquid Two-Phase Flows in a Microchannel

Cited by 23 publications

References 56 publications

Novel glass capillary microfluidic devices for the flexible and simple production of multi-cored double emulsions

Novel glass capillary microfluidic devices for the flexible and simple production of multi-cored double emulsions

Quantitative study for control of air–liquid segmented flow in a 3D-printed chip using a vacuum-driven system

Numerical Investigation of Flow Patterns and Plug Hydrodynamics in a 3D T-junction Microchannel

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