A study of MHD-based chaotic advection to enhance mixing in microfluidics using transient three dimensional CFD simulations

Yuan, Fangping; Isaac, Kakkattukuzhy M.

doi:10.1016/j.snb.2016.07.063

Cited by 28 publications

(15 citation statements)

References 28 publications

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“…As it has been reported [1,[7][8][9] in the micro-scale, mixing can be improved by "chaotic advection", which involves breaking, stretching, and folding of liquid streams leading to an increase of the interfacial contact area of the fluids. In our laboratory, the mixing efficiency of several types of passive μ-mixers was investigated both experimentally and numerically [5][6][7]10].…”

Section: Introductionmentioning

confidence: 99%

“…Several comprehensive reviews of µ-mixing devices and their principles can be found in the relevant literature [1][2][3][4][5][6]. As it has been reported [1,[7][8][9] in the micro-scale, mixing can be improved by "chaotic comprehensive reviews of μ-mixing devices and their principles can be found in the relevant literature [1][2][3][4][5][6]. As it has been reported [1,[7][8][9] in the micro-scale, mixing can be improved by "chaotic advection", which involves breaking, stretching, and folding of liquid streams leading to an increase of the interfacial contact area of the fluids.…”

Section: Introductionmentioning

confidence: 99%

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Design of a Novel μ-Mixer

Kanaris

Mouza

2018

Fluids

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Abstract:In this work, the efficiency of a new µ-mixer design is investigated. As in this type of devices the Reynolds number is low, mixing is diffusion dominated and it can be enhanced by creating secondary flows. In this study, we propose the introduction of helical inserts into a straight tube to create swirling flow. The influence of the insert's geometrical parameters (pitch and length of the propeller blades) and of the Reynolds number on the mixing efficiency and on the pressure drop are numerically investigated. The mixing efficiency of the device is assessed by calculating a number-i.e., the index of mixing efficiency-that quantifies the uniformity of concentration at the outlet of the device. The influence of the design parameters on the mixing efficiency is assessed by performing a series of 'computational' experiments, in which the values of the parameter are selected using design of experiments (DOE) methodology. Finally using the numerical data, appropriate design equations are formulated, which, for given values of the design parameters, can estimate with reasonable accuracy both the mixing efficiency and the pressure drop of the proposed mixing device.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design of a Novel μ-Mixer

Kanaris

Mouza

2018

Fluids

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“…In many studies, mixing process is investigated experimentally or by numerical of some passive scalars, while less numerical research has been done on analysis of mixing characteristics in MHD flows. [14][15][16] In this article the effect of uniform and constant external magnetic field in mixing properties of isotropic MHD flow is investigated by analyzing large and small scale eddies dynamics; In order to explore mutual interaction of velocity and magnetic field, MHD flow with moderate magnetic Reynolds number is considered and solved by use of DNS. The results of this research can be useful in phenomenology and also prediction of mixing behavior of some industrial equipment as well as natural phenomena.…”

Section: Introductionmentioning

confidence: 99%

Effect of External Magnetic Field on Dynamics of Two-dimensional Isotropic Conducting Flow

Chitsaz

Fathali

2019

E3S Web Conf.

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In this article, the impact of external uniform magnetic field on the dynamic characteristics and mixing parameters of two-dimensional isotropic magnetohydrodynamic (MHD) flow is investigated. For this purpose, the direct numerical simulation (DNS) is applied to two-dimensional incompressible Navier-Stokes and magnetic induction equations by pseudo-spectral method. Governing equations are considered in the N-S vorticity equations to guarantee the incompressibility conditions and remove the pressure term from equations. The Results of the calculations show that the deformation of vortexes by external magnetic field reduces the mixing efficiency. It is also demonstrated that in MHD flow the energy is exchanged by Lorentz force between the flow and the magnetic field in such a way that the kinetic energy decreases and consequently mixing of the fluid is reduced. This energy transfer causes reduction of viscous dissipation of energy and mixing efficiency, despite increasing the total dissipated energy rate.

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“…Its principle of operation is based on the Lorentz force acting in an electrical conductive solution, in the presence of magnetic and electric fields, resulting in a motion flow. The most used solutions in the beginnings of MHD research were liquid metals and ionized gases, though in the more recent scientific literature electrolyte solutions have made an incursion [ 2 ]. This is because the flow in a MHD stirrer depends on the solution electrical conductivity.…”

Section: Introductionmentioning

confidence: 99%

Electrolyte Magnetohydrondyamics Flow Sensing in an Open Annular Channel—A Vision System for Validation of the Mathematical Model

Valenzuela-Delgado

Flores-Fuentes

Rivas-López

et al. 2018

Sensors

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Magnetohydrodynamics (MHD) is becoming more popular every day among developers of applications based on microfluidics, such as “lab on a chip” (LOC) and/or “micro-total analysis systems” (micro-TAS). Its physical properties enable fluid manipulation for tasks such as pumping, networking, propelling, stirring, mixing, and even cooling without the need for mechanical components, and its non-intrusive nature provides a solution to mechanical systems issues. However, these are not easy tasks. They all require precise flow control, which depends on several parameters, like microfluidics conductivity, the microfluidics conduit (channel) shape and size configuration, and the interaction between magnetic and electric fields. This results in a mathematical model that needs to be validated theoretically and experimentally. The present paper introduces the design of a 3D laminar flow involving an electrolyte in an annular open channel driven by a Lorentz force. For an organized description, first of all is provided an introduction to MHD applied in microfluidics, then an overall description of the proposed MHD microfluidic system is given, after that is focused in the theoretical validation of the mathematical model, next is described the experimental validation of the mathematical model using a customized vision system, and finally conclusions and future work are stated.

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A study of MHD-based chaotic advection to enhance mixing in microfluidics using transient three dimensional CFD simulations

Cited by 28 publications

References 28 publications

Design of a Novel μ-Mixer

Design of a Novel μ-Mixer

Effect of External Magnetic Field on Dynamics of Two-dimensional Isotropic Conducting Flow

Electrolyte Magnetohydrondyamics Flow Sensing in an Open Annular Channel—A Vision System for Validation of the Mathematical Model

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