Analytical modeling of slip flow in parallel-plate microchannels
This paper presents analytical modeling of slip liquid flow in parallel-plate microchannels, and can be divided in two parts. In the first part, classical relationships describing velocity, flow rate, pressure gradient, and shear stress are extended to the more general cases where there exist two di...
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sg-ntu-dr.10356-1029232020-03-07T13:19:27Z Analytical modeling of slip flow in parallel-plate microchannels Kashaninejad, Navid Chan, Weng Kong Nguyen, Nam-Trung School of Mechanical and Aerospace Engineering DRNTU::Engineering This paper presents analytical modeling of slip liquid flow in parallel-plate microchannels, and can be divided in two parts. In the first part, classical relationships describing velocity, flow rate, pressure gradient, and shear stress are extended to the more general cases where there exist two different values of the yet-unknown slip lengths at the top and bottom walls of the channel. These formulations can be used to experimentally determine the values of slip length on the channels fabricated from two different hydrophobic walls. In the second part, the emphasis is given on the quantification of the slip length analytically. Generating mechanism of slip is attributed to the existence of a low-viscosity region between the liquid and the solid surface. By extending the previous works, the analytical values of slip length are determined using exact, rather than empirical, values of air gap thickness at different ranges of air flow Knudsen number. In addition to the exact expressions of air gap thickness, the corresponding ranges of the channel height where slip flow can be induced are also found analytically. It is found that when the channel height is larger than 700 μ m, air flow is in continuum regime and no-slip boundary condition can be used. For the case where the channels height is smaller than 700 μ m, and larger than 7.5 μm, slip boundary condition should be used to model the air flow in the channel. Finally, for the channel with the height smaller than 7.5 μm, Navier-Stokes equation cannot be used to model the air flow, and instead molecularbased approaches should be implemented. The results of this paper can be used as a guideline for both experimentalists and theoreticians to study the slip flow in parallel-plate microchannels. 2014-04-10T03:56:29Z 2019-12-06T21:02:22Z 2014-04-10T03:56:29Z 2019-12-06T21:02:22Z 2013 2013 Journal Article Kashaninejad, N., Chan, W. K., & Nguyen, N.-T. (2013). Analytical modeling of slip flow in parallel-plate microchannels. Micro and Nanosystems, 5(4), 245-252. 1876-4029 https://hdl.handle.net/10356/102923 http://hdl.handle.net/10220/19215 10.2174/187640290504131127120423 en Micro and nanosystems © 2013 Bentham Science Publishers. |
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DRNTU::Engineering Kashaninejad, Navid Chan, Weng Kong Nguyen, Nam-Trung Analytical modeling of slip flow in parallel-plate microchannels |
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This paper presents analytical modeling of slip liquid flow in parallel-plate microchannels, and can be divided in two parts. In the first part, classical relationships describing velocity, flow rate, pressure gradient, and shear stress are extended to the more general cases where there exist two different values of the yet-unknown slip lengths at the top and bottom walls of the channel. These formulations can be used to experimentally determine the values of slip length on the channels fabricated from two different hydrophobic walls. In the second part, the emphasis is given on the quantification of the slip length analytically. Generating mechanism of slip is attributed to the existence of a low-viscosity region between the liquid and the solid surface. By extending the previous works, the analytical values of slip length are determined using exact, rather than empirical, values of air gap thickness at different ranges of air flow Knudsen number. In addition to the exact expressions of air gap thickness, the corresponding ranges of the channel height where slip flow can be induced are also found analytically. It is found that when the channel height is larger than 700 μ m, air flow is in continuum regime and no-slip boundary condition can be used. For the case where the channels height is smaller than 700 μ m, and larger than 7.5 μm, slip boundary condition should be used to model the air flow in the channel. Finally, for the channel with the height smaller than 7.5 μm, Navier-Stokes equation cannot be used to model the air flow, and instead molecularbased approaches should be implemented. The results of this paper can be used as a guideline for both experimentalists and theoreticians to study the slip flow in parallel-plate microchannels. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Kashaninejad, Navid Chan, Weng Kong Nguyen, Nam-Trung |
| format |
Article |
| author |
Kashaninejad, Navid Chan, Weng Kong Nguyen, Nam-Trung |
| author_sort |
Kashaninejad, Navid |
| title |
Analytical modeling of slip flow in parallel-plate microchannels |
| title_short |
Analytical modeling of slip flow in parallel-plate microchannels |
| title_full |
Analytical modeling of slip flow in parallel-plate microchannels |
| title_fullStr |
Analytical modeling of slip flow in parallel-plate microchannels |
| title_full_unstemmed |
Analytical modeling of slip flow in parallel-plate microchannels |
| title_sort |
analytical modeling of slip flow in parallel-plate microchannels |
| publishDate |
2014 |
| url |
https://hdl.handle.net/10356/102923 http://hdl.handle.net/10220/19215 |
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1681037184828702720 |