Enhancement of Mixing Performance of Non-Newtonian Fluids using Curving and Grooving of Microchannels

Islami, Sima Baheri; Khezerloo, Marzieh

doi:10.18869/acadpub.jafm.73.238.26374

Cited by 25 publications

(6 citation statements)

References 27 publications

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“…In many microfluidic applications, e.g., fast chemical reactions, DNA separation and amplification, efficient microfluidic mixing schemes are required to ensure that a thorough species mixing can be achieved within small space and time scales. Micromixers are microfluidic systems which enable mixing two or several fluids into a homogenous solution, or control the dispersion of species in solvents (Karniadakis et al 2005;Nguyen and Wu 2005;Suh and Kang 2010;Lee et al 2011;Stevens et al 2012;Baheri Islami and Khezerloo 2017). Micromixers are often classified into two broad categories based on their operation mechanism: passive and active mixers.…”

Section: Introductionmentioning

confidence: 99%

Optimization of an Active Electrokinetic Micromixer Based on the Number and Arrangement of Microelectrodes

Keshavarzian

Shamshiri

Charmiyan

et al. 2018

JAFM

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This paper reports enhancement of mixing process via electroosmotic phenomenon using a microelectrode system, which is structured by aligning a number of electrodes placed on the walls of a mixing chamber integrated within a T-Shape micromixer. A number of electrodes are dispositioned on the inner and outer loops of the annular mixing chamber, and different design patterns based on a variety of arrangements for these electrodes are investigated using numerical methods. The electric potentials on the microelectrodes are time-dependent, and this is found to be a key element for chaotic mixing. Also, it is deduced that due to the impact of the applied AC electric field and the induced surface charge on the fluid particles, a number of vortices are generated in the aqueous solution. These vortices significantly enhance the mixing of the species in the mixing chamber. In order to find an optimum pattern based on electrode dispositioning and the number of electrodes, effects of the geometric configuration of the microelectrodes are analyzed and the mixing effects for different design patterns are investigated via comparing the associated flow structure, concentration transport mechanism, and the mixing performance. Analyzing different designs, an optimum pattern based on the electrode arrangement and the number of electrodes is found to be the case for which the electrodes are placed on the inner and outer loops of the mixing chamber in a cross-like pattern.

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Section: Introductionmentioning

confidence: 99%

Optimization of an Active Electrokinetic Micromixer Based on the Number and Arrangement of Microelectrodes

Keshavarzian

Shamshiri

Charmiyan

et al. 2018

JAFM

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“…Figure 3b shows a flow configuration including primary and secondary Dean vortices. The Dean number at which the secondary Dean vortices start to form is called the critical Dean number, De c [65,80,81].…”

Section: Dean Number Thresholdsmentioning

confidence: 99%

The Physics and Manipulation of Dean Vortices in Single- and Two-Phase Flow in Curved Microchannels: A Review

Saffar,

Kashanj,

Nobes

et al. 2023

Micromachines

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Microchannels with curved geometries have been employed for many applications in microfluidic devices in the past decades. The Dean vortices generated in such geometries have been manipulated using different methods to enhance the performance of devices in applications such as mixing, droplet sorting, and particle/cell separation. Understanding the effect of the manipulation method on the Dean vortices in different geometries can provide crucial information to be employed in designing high-efficiency microfluidic devices. In this review, the physics of Dean vortices and the affecting parameters are summarized. Various Dean number calculation methods are collected and represented to minimize the misinterpretation of published information due to the lack of a unified defining formula for the Dean dimensionless number. Consequently, all Dean number values reported in the references are recalculated to the most common method to facilitate comprehension of the phenomena. Based on the converted information gathered from previous numerical and experimental studies, it is concluded that the length of the channel and the channel pathline, e.g., spiral, serpentine, or helix, also affect the flow state. This review also provides a detailed summery on the effect of other geometric parameters, such as cross-section shape, aspect ratio, and radius of curvature, on the Dean vortices’ number and arrangement. Finally, considering the importance of droplet microfluidics, the effect of curved geometry on the shape, trajectory, and internal flow organization of the droplets passing through a curved channel has been reviewed.

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“…To compare the performance of the micromixers, mixing index is formulated as below [ 48 , 49 ]:

Where σ is the mass fraction's standard deviation, the definition is:

With N denoting the number of sampling points throughouttransversal section,

is the mass fraction atinspecting point i , the ideal mixing mass fraction is

, and the standard deviation (SD) at the inlet section is

.…”

Section: Introductionmentioning

confidence: 99%

Entropy generation analysis and thermal synergy efficiency in the T-shaped micro-kenics

Mahammedi,

Tayeb,

Kim

et al. 2024

Heliyon

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Enhancement of Mixing Performance of Non-Newtonian Fluids using Curving and Grooving of Microchannels

Cited by 25 publications

References 27 publications

Optimization of an Active Electrokinetic Micromixer Based on the Number and Arrangement of Microelectrodes

Optimization of an Active Electrokinetic Micromixer Based on the Number and Arrangement of Microelectrodes

The Physics and Manipulation of Dean Vortices in Single- and Two-Phase Flow in Curved Microchannels: A Review

Entropy generation analysis and thermal synergy efficiency in the T-shaped micro-kenics

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