The Effect of Inertia on the Flow and Mixing Characteristics of a Chaotic Serpentine Mixer

Kang, Tae Gon; Anderson, Patrick Patrick

doi:10.3390/mi5041270

Cited by 20 publications

(10 citation statements)

References 36 publications

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“…Through this way, a chaotic flow is induced, which enhances the mixing efficiency. 40 In most of the previous passive mixers, where vortices play a key role in increasing the mixing efficiency, vortex regions were confined to a specific segment of the channel 43,44 while in the micromixers presented in this work, mixing process occurs throughout the structure. Moreover, in designs where the Dean vortices are responsible for increasing the efficiency, the channel length was normally limited due to the lack of fabrication space on a 2D plane.…”

Section: Design Of 3d Micromixersmentioning

confidence: 89%

An easily fabricated three-dimensional threaded lemniscate-shaped micromixer for a wide range of flow rates

Rafeie

Welleweerd

Hassanzadeh-Barforoushi

et al. 2017

Biomicrofluidics

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Mixing fluid samples or reactants is a paramount function in the fields of micro total analysis system (lTAS) and microchemical processing. However, rapid and efficient fluid mixing is difficult to achieve inside microchannels because of the difficulty of diffusive mass transfer in the laminar regime of the typical microfluidic flows. It has been well recorded that the mixing efficiency can be boosted by migrating from two-dimensional (2D) to three-dimensional (3D) geometries. Although several 3D chaotic mixers have been designed, most of them offer a high mixing efficiency only in a very limited range of Reynolds numbers (Re). In this work, we developed a 3D fine-threaded lemniscate-shaped micromixer whose maximum numerical and empirical efficiency is around 97% and 93%, respectively, and maintains its high performance (i.e., >90%) over a wide range of 1 < Re < 1000 which meets the requirements of both the lTAS and microchemical process applications. The 3D micromixer was designed based on two distinct mixing strategies, namely, the inducing of chaotic advection by the presence of Dean flow and diffusive mixing through thread-like grooves around the curved body of the mixers. First, a set of numerical simulations was performed to study the physics of the flow and to determine the essential geometrical parameters of the mixers. Second, a simple and cost-effective method was exploited to fabricate the convoluted structure of the micromixers through the removal of a 3D-printed wax structure from a block of cured polydimethylsiloxane. Finally, the fabricated mixers with different threads were tested using a fluorescent microscope demonstrating a good agreement with the results of the numerical simulation. We envisage that the strategy used in this work would expand the scope of the micromixer technology by broadening the range of efficient working flow rate and providing an easy way to the fabrication of 3D convoluted microstructures. Published by AIP Publishing.

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Section: Design Of 3d Micromixersmentioning

confidence: 89%

An easily fabricated three-dimensional threaded lemniscate-shaped micromixer for a wide range of flow rates

Rafeie

Welleweerd

Hassanzadeh-Barforoushi

et al. 2017

Biomicrofluidics

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“…Due to the apex location changing alternatingly in a periodic unit, two cross-sectional flow portraits are generated in the first and second half cycles and they intersect one another when projected onto the same plane. According to the linked twisted maps (LTM) framework [48], the two flow portraits satisfy the necessary condition for the creation of chaotic advection [49,50]. Figure 3 depicts cross-sectional velocity vectors projected onto planes normal to the z direction.…”

Section: Flow Characteristics Of the Shm With A Permeable Wallmentioning

confidence: 99%

Design Optimization for a Microfluidic Crossflow Filtration System Incorporating a Micromixer

et al. 2019

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In this study, we report on a numerical study on design optimization for a microfluidic crossflow filtration system incorporated with the staggered herringbone micromixer (SHM). Computational fluid dynamics (CFD) and the Taguchi method were employed to find out an optimal set of design parameters, mitigating fouling in the filtration system. The flow and the mass transfer characteristics in a reference SHM model and a plain rectangular microchannel were numerically investigated in detail. Downwelling flows in the SHM model lead to backtransport of foulants from the permeable wall, which slows down the development of the concentration boundary layer in the filtration system. Four design parameters -the number of grooves, the groove depth, the interspace between two neighboring grooves, and the interspace between half mixing periodswere chosen to construct a set of numerical experiments using an orthogonal array L 9 (3 4 ) from the Taguchi method. The Analysis of Variance (ANOVA) using the evaluated signal-to-noise (SN) ratios enabled us to identify the contribution of each design parameter on the performance. The proposed optimal SHM model indeed showed the lowest growth rate of the wall concentration compared to other SHM models.

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“…The time steps for each simulation are appropriately adjusted so as to limit the necessary number of calculation steps needed by the time-consuming transient simulations. For pulse tracer input method, E(t) is given by equation (6). When the mixing performance of flow systems of different sizes or flow conditions is to be compared, a normalized RTD function, E (θ), is used instead of E (t).…”

Section: Icmit 2016mentioning

confidence: 99%

“…Micromixers can be classified into two categories, active and passive, depending on their mixing principle [5]. In active micromixers, active controls over the flow field are introduced to manipulate fluids to be mixed by using moving parts, acoustics waves or electro-magnetic fields or varying pressure gradient [6]. In the case of passive mixer, the mixing enhancement can be achieved by carefully designing the channel so as to create vortices and disturb the flow stability which, in turn, leads to the chaotic flow regime.…”

Section: Introductionmentioning

confidence: 99%

Computational Design and Experimental Validation of SAR Mixers

2016

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Abstract. In this study, two novel split and recombine (SAR) 'H-C' and 'Y-Y' micromixers along with a known SAR 'Chain' mixer are presented. The efficiency and pressure drop at Reynolds numbers (Re) up to 100 were investigated numerically as well as experimentally. Numerical and experimental values of mixing efficiency and pressure drop coincide considerably, which validate the numerical model. Results show that the mixing efficiency of the Chain mixer is good only at Re≥50 and the pressure drop is relatively high, whereas the H-C and the Y-Y mixers give a mixing efficiency higher than 90% over all the range of Reynolds numbers examined and their energy requirement is less than that of the Chain mixer. Furthermore, numerical residence time distribution (RTD) was explored, which successfully predicts the experimental results.

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The Effect of Inertia on the Flow and Mixing Characteristics of a Chaotic Serpentine Mixer

Cited by 20 publications

References 36 publications

An easily fabricated three-dimensional threaded lemniscate-shaped micromixer for a wide range of flow rates

An easily fabricated three-dimensional threaded lemniscate-shaped micromixer for a wide range of flow rates

Design Optimization for a Microfluidic Crossflow Filtration System Incorporating a Micromixer

Computational Design and Experimental Validation of SAR Mixers

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