Comparative Analysis of Passive Micromixers at a Wide Range of Reynolds Numbers

Viktorov, Vladimir; Mahmud, Readul; Visconte, Carmen

doi:10.3390/mi6081166

Cited by 19 publications

(13 citation statements)

References 25 publications

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“…A SIMPLEC scheme was assigned as the solution method used to calculate pressure velocity coupling (Mansur, Wang, & Dai, 2008). The secondorder upwind schemes of momentum and pressure were used to achieve a more accurate solution (Viktorov et al, 2015).…”

Section: Methodsmentioning

confidence: 99%

“…One of the SAR mixers, namely the Caterpillar, has been successfully employed for many industrial applications at high Reynolds numbers; nevertheless, its mixing ability is of minor quality in the case of Reynolds numbers below about 500 (Schönfeld, Hessel, & Hofmann, 2004). In fact, according to the literature, most of the micromixers have satisfying operation at either high or low Reynolds numbers -and SAR micromixers in particular have high energy requirements because of their complex structure (Viktorov, Mahmud, & Visconte, 2015). Therefore, the development of high-performance devices that can work over a wide range of Reynolds numbers with an acceptable pressure drop is currently a major focus of research.…”

Section: Introductionmentioning

confidence: 99%

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Numerical study of fluid mixing at different inlet flow-rate ratios in Tear-drop and Chain micromixers compared to a new H-C passive micromixer

Viktorov

Mahmud

Visconte

2016

Engineering Applications of Computational Fluid Mechanics

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A new split and recombine (SAR) passive micromixer, namely the H-C mixer, is presented. The performance of the micromixer is analyzed numerically at Reynolds numbers up to 100, varying the inlet flow-rate ratio. In order to validate the numerical model, tests for an inlet flow-rate ratio of 1 were carried out on the new H-C micromixer along with the established Tear-drop and Chain micromixers for comparison, and good correspondence was found between the differently obtained data. Contrary to the Tear-drop and Chain micromixers, the H-C micromixer exhibited a mixing efficiency greater than 90% independent of Reynolds numbers. In particular, no noticeable dependence on inlet flowrate ratio was observed. Furthermore, the pressure drop along the H-C mixer was found to be lower than those along the already known mixers. ARTICLE HISTORY

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Numerical study of fluid mixing at different inlet flow-rate ratios in Tear-drop and Chain micromixers compared to a new H-C passive micromixer

Viktorov

Mahmud

Visconte

2016

Engineering Applications of Computational Fluid Mechanics

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“…As the Reynolds numbers increase, there is a shorter residence time for the fluid particles to diffuse, and as a result worse mixing efficiency could be expected. Nevertheless, the Y-Y and the H-C mixers show good efficiency due to the three-dimensional change of direction of flow in the input of each element, which promotes a helical fluid motion; as a consequence, the fluid path is lengthened [13]. However, this swirling effect is less evident in the Chain mixer.…”

Section: Resultsmentioning

confidence: 99%

“…SAR mixers show good mixing efficiency at low Reynolds number (Re<20) and high Reynolds number (Re>100), whereas mixing performance is relatively low at middle range [13]. Two novel SAR mixers, namely the Y-Y and the H-C, are developed and studied at Reynolds numbers ranging from 1 to 100.…”

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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“…Other geometries are presented in ( d ) the Teardrop, ( e ) the Y–Y and ( f ) the H–C mixing geometries at Re = 1 ( top ), 30 ( middle ) and 100 ( bottom ). The left column of each geometry represents an experiment, where as on the right the images taken from computer simulations (with permission from Vladimir Viktorov [ 11 ]). ( g ) The herringbone mixer, ( h ) a double helix and ( i ) a triple helix mixer.…”

Section: Figurementioning

confidence: 99%

Microfluidic 3D Helix Mixers

et al. 2016

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Polymeric microfluidic systems are well suited for miniaturized devices with complex functionality, and rapid prototyping methods for 3D microfluidic structures are increasingly used. Mixing at the microscale and performing chemical reactions at the microscale are important applications of such systems and we therefore explored feasibility, mixing characteristics and the ability to control a chemical reaction in helical 3D channels produced by the emerging thread template method. Mixing at the microscale is challenging because channel size reduction for improving solute diffusion comes at the price of a reduced Reynolds number that induces a strictly laminar flow regime and abolishes turbulence that would be desired for improved mixing. Microfluidic 3D helix mixers were rapidly prototyped in polydimethylsiloxane (PDMS) using low-surface energy polymeric threads, twisted to form 2-channel and 3-channel helices. Structure and flow characteristics were assessed experimentally by microscopy, hydraulic measurements and chromogenic reaction, and were modeled by computational fluid dynamics. We found that helical 3D microfluidic systems produced by thread templating allow rapid prototyping, can be used for mixing and for controlled chemical reaction with two or three reaction partners at the microscale. Compared to the conventional T-shaped microfluidic system used as a control device, enhanced mixing and faster chemical reaction was found to occur due to the combination of diffusive mixing in small channels and flow folding due to the 3D helix shape. Thus, microfluidic 3D helix mixers can be rapidly prototyped using the thread template method and are an attractive and competitive method for fluid mixing and chemical reactions at the microscale.

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Comparative Analysis of Passive Micromixers at a Wide Range of Reynolds Numbers

Cited by 19 publications

References 25 publications

Numerical study of fluid mixing at different inlet flow-rate ratios in Tear-drop and Chain micromixers compared to a new H-C passive micromixer

Numerical study of fluid mixing at different inlet flow-rate ratios in Tear-drop and Chain micromixers compared to a new H-C passive micromixer

Computational Design and Experimental Validation of SAR Mixers

Microfluidic 3D Helix Mixers

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