Volume 18, Issue 1 (3-2018)
Modares Mechanical Engineering 2018, 18(1): 27-38 |
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1- Ferdowsi University of Mashhad
2- Mechanical Engineering Department,Payame Noor University (PNU),Tehran, Iran
2- Mechanical Engineering Department,Payame Noor University (PNU),Tehran, Iran
Abstract: (7654 Views)
In this study, effects of zeta potential distribution and geometrical specifications are investigated on mixing efficiency in electroosmotic flows. Flow geometry in this research is a series of converging-diverging microchannels with different diverging ratios. Governing equations including the Navier Stokes equation for fluid flow and the Poisson-Boltzmann equation for internal electrical field are solved numerically in a two-dimensional domain by using the lattice Boltzmann method. Numerical simulations are validated against available analytic solutions for electroosmotic flow in homogeneous straight channels. The response surface methodology (RSM) is then employed to investigate relationship between flow variables and consequently to optimize mixing efficiency and flow rate of the channel. Results indicate that increasing the zeta potential ratio and diverging ratio, leads to increased value of flow rate, while meanwhile it decreases the mixing efficiency. Zeta potential pattern does not affect flow rate considerably, but its effects on mixing efficiency is noticeable. Furthermore, it is found that mixing efficiency and flow rate are more sensitive to zeta potential ratio than diverging ratio. At last, optimum parameters are determined by RSM which are 0.5 for zeta potential ratio, 0.6 for diverging height, and pp-nn pattern for zeta potential distribution, all associated to simultaneously maximized flow rate and mixing efficiency.
Keywords: Lattice Boltzmann Method, Mixing, Electroosmotic, Response surface methodology (RSM), Optimization
Article Type: Research Article |
Subject:
Micro & Nano Systems
Received: 2017/08/28 | Accepted: 2017/11/15 | Published: 2017/12/29
Received: 2017/08/28 | Accepted: 2017/11/15 | Published: 2017/12/29
References
1. J. Yahng, S. Jeoung, D. Choi, D. Cho, J. Kim, Fabrication of microfluidic devices by using a femtosecond laser micromachining technique and μ-PIV studies on its fluid dynamics, the Korean Physical Society, Vol. 47, No. 6, pp. 977-981, 2005.
2. A. J. Tüdős, G. A. Besselink, R. B. Schasfoort, Trends in miniaturized total analysis systems for point-of-care testing in clinical chemistry, Lab on a Chip, Vol. 1, No. 2, pp. 83-95, 2001.
3. E. B. Cummings, S. Griffiths, R. Nilson, P. Paul, Conditions for similitude between the fluid velocity and electric field in electroosmotic flow, Analytical Chemistry, Vol. 72, No. 11, pp. 2526-2532, 2000.
4. S. Jeong, J. Park, J. M. Kim, S. Park, Microfluidic mixing using periodically induced secondary potential in electroosmotic flow, Journal of Electrostatics, Vol. 69, No. 5, pp. 429-434, 2011.
5. N. Loucaides, A. Ramos, G. E. Georghiou, Configurable AC electroosmotic pumping and mixing, Microelectronic Engineering, Vol. 90, pp. 47-50, 2011
6. H. Le The, H. Le Thanh, T. Dong, B. Q. Ta, N. Tran-Minh, F. Karlsen, An effective passive micromixer with shifted trapezoidal blades using wide Reynolds number range, Chemical Engineering Research and Design, Vol. 93, pp. 1-11, 2015.
7. V. Papadopoulos, I. Kefala, G. Kaprou, G. Kokkoris, D. Moschou, G. Papadakis, E. Gizeli, A. Tserepi, A passive micromixer for enzymatic digestion of DNA, Microelectronic Engineering, Vol. 124, pp. 42-46, 2014.
8. L. Ren, D. Li, Electroosmotic flow in heterogeneous microchannels, Colloid and Interface Science, Vol. 243, No. 1, pp. 255-261, 2001
9. L. M. Fu, J. Y. Lin, R. J. Yang, Analysis of electroosmotic flow with step change in zeta potential, Colloid and Interface Science, Vol. 258, No. 2, pp. 266-275, 2003.
10. J. Yang, J. Masliyah, D. Y. Kwok, Streaming potential and electroosmotic flow in heterogeneous circular microchannels with nonuniform zeta potentials: Requirements of flow rate and current continuities, Langmuir, Vol. 20, No. 10, pp. 3863-3871, 2004.
11. E. Biddiss, D. Erickson, D. Li, Heterogeneous surface charge enhanced micromixing for electrokinetic flows, Analytical Chemistry, Vol. 76, No. 11, pp. 3208-3213, 2004.
12. A. Nayak, Analysis of mixing for electroosmotic flow in micro/nano channels with heterogeneous surface potential, Heat and Mass Transfer, Vol. 75, pp. 135-144, 2014.
13. C. Wang, Y. Hu, Mixing of Liquids Using Obstacles in Y-Type Microchannels, Tamkang Journal of Science and Engineering, Vol. 13, No. 4, pp. 385г394, 2010
14. C. C. Cho, Electrokinetically-driven flow mixing in microchannels with wavy surface, Colloid and Interface science, Vol. 312, No. 2, pp. 470-480, 2007.
15. H. Yoshida, T. Kinjo, H. Washizu, Analysis of electro-osmotic flow in a microchannel with undulated surfaces, Computers & Fluids, Vol. 124, pp. 237-245, 2016.
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