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Abstract

In this study, the mixing performance and pressure drop characteristics have been numerically analyzed for flow through rectangular microchannel with obstacles in the walls arranged in a staggered manner. Three different aspect ratios (AR) of the obstacles are considered, namely 4:1, 1:1, and 1:4. The effects of aspect ratio of the obstacles on the mixing efficiency and the pressure drop are analyzed and compared with that of the channel without obstacle. The results are presented in terms of Reynolds number (Re) and Schmidt number (Sc) in the following range: 0.2 ≤ Re ≤ 1 and 500 ≤ Sc ≤ 1500. Enhanced mixing efficiency is achieved for the case of microchannel with obstacles and the corresponding pressure drop is also found to be higher. The mixing efficiency as well as the pressure drop is maximum for AR = 1:4 among all the geometries considered in the analysis in same flow condition. Furthermore, for a given configuration of the microchannel the mixing efficiency is governed by the mass Peclet number and, accordingly, the mixing efficiency increases with the decrease in Schmidt number for a given Reynolds number.

Keywords

Microchannel obstacle aspect ratio mixing efficiency Schmidt number

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References

Rashidi

Bafekr

Valipour

, et al. A review on the application, simulation, and experiment of the electrokinetic mixers. Chem Eng Process-Process Intensif 2018; 126: 108–122.

Jeong

Chung

Kim

, et al. Applications of micromixing technology. Analyst 2010; 135: 460–473.

Jayaraj

Kang

Suh

. A review on the analysis and experiment of fluid flow and mixing in micro-channels. J Mech Sci Technol 2007; 21: 536–548.

Kunti

Bhattacharya

Chakraborty

. Analysis of micromixing of non-Newtonian fluids driven by alternating current electrothermal flow. J Non-Newtonian Fluid Mech 2017; 247: 123–131.

Mondal B, Mehta SK, Patowari PK, et al. Numerical study of mixing in wavy micromixers: comparison between raccoon and serpentine mixer. Chem Eng Process-Process Intensif 2019; 136: 44–61.

Raza

Hossain

Kim

. Effective mixing in a short serpentine split-and-recombination micromixer. Sensor Actuat B 2018; 258: 381–392.

Hossain

Kim

. Mixing analysis in a three-dimensional serpentine split-and-recombine micromixer. Chem Eng Res Des 2015; 100: 95–103.

Das

Tilekar

Wangikar

, et al. Numerical and experimental study of passive fluids mixing in micro-channels of different configurations. Microsyst Technol 2017; 23: 5977–5988.

Nguyen

. Micromixers—a review. J Micromech Microeng 2005; 15: R1–R16.

10.

Baik

Cho

Choi

, et al. Numerical investigation of the effects of geometric parameters on transverse motion with slanted-groove micro-mixers. J Mech Sci Technol 2016; 30: 3729–3739.

11.

Sudarsan

Ugaz

. Multivortex micromixing. Proc Natnl Acad Sci 2006; 103: 7228–7233.

12.

Solehati

Bae

Sasmito

. Numerical investigation of mixing performance in microchannel T-junction with wavy structure. Comput Fluids 2014; 96: 10–19.

13.

Chen

Zeng

, et al. Numerical and experimental investigation on micromixers with serpentine microchannels. Int J Heat Mass Transfer 2016; 98: 131–140.

14.

Borgohain

Dalal

Natarajan

, et al. Numerical assessment of mixing performances in cross-T microchannel with curved ribs. Microsyst Technol 2018; 24: 1949–1963.

15.

Borgohain

Arumughan

Dalal

, et al. Design and performance of a three-dimensional micromixer with curved ribs. Chem Eng Res Des 2018; 136: 761–775.

16.

Miranda

Oliveira

Teixeira

, et al. Numerical study of micromixing combining alternate flow and obstacles. Int Commun Heat Mass Transfer 2010; 37: 581–586.

17.

Wangikar

Patowari

Misra

. Numerical and experimental investigations on the performance of a serpentine microchannel with semicircular obstacles. Microsyst Technol 2018; 24: 3307–3320.

18.

Kim

Yoon

. Optimal design of groove shape on passive micromixer using design of experiment technique. J Process Mech Eng 2017; 231: 880–887.

19.

Seo

Kim

. A study on the mixing characteristics in a hybrid type microchannel with various obstacle configurations. Mater Res Bull 2012; 47: 2948–2951.

20.

Suh

Kang

. A numerical study on the flow and mixing in a microchannel using magnetic particles. J Mech Sci Technol 2010; 24: 441–450.

21.

Alapati

Fernandes

Suh

. Enhancement of mixing within a micro cavity by use of transient induced-charge electro-osmotic flow around micro electrodes. J Mech Sci Technol 2011; 25: 1495–1499.

22.

Pati

. A textbook on fluid mechanics and hydraulic machines, New Delhi: McGraw-Hill Education (India) Pvt. Ltd., 2012.

23.

Kazemi

Nourian

Movahed

, et al. Two dimensional numerical study on mixing enhancement in micro-channel due to induced charge electrophoresis. Chem Eng Process 2017; 120: 241–250.

24.

Lin

Yang

. Chaotic mixing of fluids in a planar serpentine channel. Int J Heat Mass Transfer 2017; 50: 1269–1277.

25.

Pati

Kumar

. Effects of temperature-dependent thermo-physical properties on hydrodynamic swirl decay in microtubes. J Process Mech Eng 2018. DOI: 10.1177/0954408918755782.

Analysis of mixing performances in microchannel with obstacles of different aspect ratios

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