- Author
-
Han, D. H.
|
Kedzierski, M. A.
- Title
- Micro Effects for Single Phase Pressure Drop In Microchannels.
- Coporate
- Design Korea Univ., Seoul, Korea
National Institute of Standards and Technology, Gaithersburg, MD
- Journal
-
International Journal of Transport Phenomena,
Vol. 10,
103-112,
2008
- Sponsor
- National Institute of Standards and Technology, Gaithersburg, MD
Korea Science and Engineering Foundation, Korea
- Keywords
-
micro effects
|
pressure drop
|
microchannels
|
temperature
|
pressure
|
uncertainity
|
Reynolds number
|
friction
|
equations
|
regression
- Identifiers
- microfluidics; microfluidicts; microtechnology; micro devices; fractional factorial experimental design; summarized experimental parameters ranges; estimated uncertainities; friction factor and Poiseuille number; choice of regression model
- Abstract
- This paper investigates the significance of several micro-effects that have been proposed to influence pressure drop measurements in microchannels. Pressure drop measurements were made for liquid flow within tubular microchannels nominally ranging in diameters from 97 mm to 260 mm and Reynolds numbers from 30 to 3000. Fused silica tubes, polyetheretherketone tubes, and stainless steel tubes were examined. Distilled water, tap water, and deionized water were used to investigate the effect of the fluid's ionic composition on the pressure drop. The combination of differing tube surfaces and differing ionic composition was use to examine the influence of surface polarity. The effect of micro particles was investigated by testing filtered and unfiltered test fluids. Statistical examination of the measurements showed that most all of the friction factor measurements exhibited the same dependence on Reynolds number despite variation in tube length, tube material, tube diameter, fluid type, and filtering. In addition, the measurements agreed well with classical theory. This includes the fact that no early transition from laminar flow to turbulent flow was observed. Finally, it was shown that the present pressure drop measurements were not significantly affected by viscous dissipation.