One approach recently proposed for reducing the frictional resistance to liquid flow in microchannels is the patterning of micro-ribs and cavities on the channel walls. When treated with a hydrophobic coating, the liquid flowing in the microchannel wets only the surfaces of the ribs, and does not penetrate the cavities, provided the pressure is not too high. The net result is a reduction in the surface contact area between channel walls and the flowing liquid. For micro-ribs and cavities that are aligned normal to the channel axis (principal flow direction), these micro-patterns form a repeating, periodic structure. This paper presents experimental and numerical results of a study exploring the momentum transport in a parallel plate microchannel with such microengineered walls. The liquid-vapor interface (meniscus) in the cavity regions is treated as ideal in the numerical analysis (flat). Two conditions are explored with regard to the cavity region: 1) The liquid flow at the liquid-vapor interface is treated as shear-free (vanishing viscosity in the vapor region), and 2) the liquid flow in the microchannel core and the vapor flow within the cavity are coupled through the velocity and shear stress matching at the interface. Predictions and measurements reveal that significant reductions in the frictional pressure drop can be achieved relative to the classical smooth channel Stokes flow. Reductions in the friction factor are greater as the cavity-to-rib length ratio is increased (increasing shear-free fraction) and as the channel hydraulic diameter is decreased. The results also show that the average friction factor – Reynolds number product exhibits a flow Reynolds dependence. Furthermore, the predictions reveal the impact of the vapor cavity regions on the overall frictional resistance.

Volume Subject Area:
Microelectromechanical Systems
Topics:
Laminar flow, Microchannels, Cavities, Flow (Dynamics), Vapors, Friction, Shear (Mechanics), Coating processes, Coatings, Creeping flow, Momentum, Numerical analysis, Periodic structures, Pressure, Pressure drop, Reynolds number, Shear stress, Viscosity
1.
Peng
X. F.
,
Peterson
G. P.
, and
Wang
B. X.
, “
Frictional Flow Characteristics of Water Flowing Through Rectangular Microchannels
,”
Experimental Heat Transfer
7
,
249
265
(
1994
).
2.
I. Papautsky, J. Brazzle, T. Ameel, and A.B. Frazier, “Laminar Fluid Behavior in Microchannels Using Micropolar Fluid Theory,” Sensors and Actuators, Physical Proceedings of the 1998 IIth IEEE International Workshop on Micro Electro Mechanical Systems, MEMS, Heidelberg, Germany 73, 101–108 (1998)
3.
D. Yu, R. Warrington, R. Barron, and T. Ameel, “Experimental and Theoretical Investigation of Fluid Flow and Heat Transfer in Microtubes,” Proceedings of the 1995 ASME/JSME Thermal Engineering Joint Conference, Maui, Hawaii, 523–530 (1995).
4.
Peng
X. F.
and
Peterson
G. P.
, “
Convective Heat Transfer and Flow Friction for Water Flow in Microchannel Structures
,”
International Journal of Heat Transfer and Mass Transfer
,
39
,
2599
2608
(
1996
).
5.
J.R. Judy, “Characterization of Frictional Pressure Drop For Liquid Flows Through Microtubes,” M.S. Thesis, Brigham Young University (2001).
6.
Judy
J.
,
Maynes
D.
, and
Webb
B. W.
, “
Characterization of Frictional Pressure Drop for Liquid Flows Through Microchannels
,”
International Journal of Heat and Mass Transfer
,
45
, pp.
3477
3489
(
2002
).
7.
Ou
J.
,
Perot
B.
,
Rothstein
J. P.
, “
Laminar Drag Reduction in Microchannels Using Ultrahydrophobic Surfaces
,”
Physics of Fluids
,
16
,
4635
4643
(
2004
).
8.
B. Woolford, K. Jeffs, D. Maynes, and B.W. Webb, “Laminar Fully-Developed Flow in a Microchannel with Patterned Ultrahydrophobic Walls,” Proceedings of the ASME Summer Heat Transfer Conference, San Francisco, CA, HT2005-72726, (2005).
9.
Oner
D.
and
McCarthy
T. J.
, “
Ultrahydrophobic Surfaces. Effects of Topography Length Scales on Wettability
,”
Langmuir
,
16
,
7777
7782
(
2000
).
10.
A. Torkkeli, J. Saarilahti, A. Haara, H. Harma, T. Soukka, and P. Tolonen, “Electrostatic Transportation of Water Droplets on Superhydrophobic Surfaces,” Proceedings of the IEEE MEMS 2001 Conference, 475–478 (2001).
11.
J. Kim and C-J. Kim, “Nanostructured Surfaces for Dramatic Reduction of Flow Resistance in Droplet-Based Microfluidics,” Proceedings of the IEEE MEMS 2002 Conference, Las Vegas, NV, 479–482 (2002).
12.
Chen
W.
,
Fadeev
A. Y.
,
Hsieh
M. C.
,
Oner
D.
,
Youngblood
J.
, and
McCarthy
J. T.
, “
Ultrahydrophobic and Ultralyophobic Surfaces: Some Comments and Examples
,”
Langmuir
,
15
,
3395
3399
(
1999
).
13.
Youngblood
J. P.
and
McCarthy
T. J.
, “
Ultrahydrophobic Polymer Surfaces Prepared by Simultaneous Ablation of Polypropylene and Sputtering of Poly(terafluoroethylene) Using Radio Frequency Plasma
,”
Macromolecules
,
32
,
6800
6806
(
1999
).
14.
Bico
J.
,
Thiele
U.
, and
Quere
D.
, “
Wetting of Textured Surfaces
,”
Colloids and Surfaces A
,
206
,
41
46
(
2002
).
15.
F. M. White, Viscous Fluid Flow 2nd ed., McGraw-Hill, (1991).
This content is only available via PDF.
Copyright © 2005
 by ASME
You do not currently have access to this content.