Access the full text.
Sign up today, get DeepDyve free for 14 days.
N. Obot (1988)
Determination of Incompressible Flow Friction in Smooth Circular and Noncircular Passages: A Generalized Approach Including Validation of the Nearly Century Old Hydraulic Diameter ConceptJournal of Fluids Engineering-transactions of The Asme, 110
I. Idelchik, M. Steinberg, Greta Malyavskaya, O. Martynenko (1986)
Handbook of hydraulic resistance
D. Pramanik, S. Saha (2006)
Thermohydraulics of Laminar Flow Through Rectangular and Square Ducts With Transverse Ribs and Twisted TapesJournal of Heat Transfer-transactions of The Asme, 128
S. Shen, Jl Xu, Jj Zhou, Yingming Chen (2006)
Flow and heat transfer in microchannels with rough wall surfaceEnergy Conversion and Management, 47
S. Al-Fahed, L. Chamra, W. Chakroun (1998)
Pressure drop and heat transfer comparison for both microfin tube and twisted-tape inserts in laminar flowExperimental Thermal and Fluid Science, 18
S. Kandlikar, S. Joshi, Shu-qing Tian (2003)
Effect of Surface Roughness on Heat Transfer and Fluid Flow Characteristics at Low Reynolds Numbers in Small Diameter TubesHeat Transfer Engineering, 24
D. Pfund, D. Rector, A. Shekarriz, A. Popescu, J. Welty (1998)
Pressure Drop Measurements in a MicrochannelMicro-Electro-Mechanical Systems (MEMS)
Y. Mishan, A. Mosyak, E. Pogrebnyak, G. Hetsroni (2007)
Effect of developing flow and thermal regime on momentum and heat transfer in micro-scale heat sinkInternational Journal of Heat and Mass Transfer, 50
X. Peng, B. Wang (1993)
Forced convection and flow boiling heat transfer for liquid flowing through microchannelsInternational Journal of Heat and Mass Transfer, 36
P. Lee, S. Garimella (2006)
Thermally Developing Flow and Heat Transfer in Rectangular Microchannels of Different Aspect RatiosInternational Journal of Heat and Mass Transfer, 49
G. Morini (2004)
LAMINAR-TO-TURBULENT FLOW TRANSITION IN MICROCHANNELSMicroscale Thermophysical Engineering, 8
W. Qu, I. Mudawar (2002)
Experimental and numerical study of pressure drop and heat transfer in a single-phase micro-channel heat sinkInternational Journal of Heat and Mass Transfer, 45
Z. Liu, C. Zhang, Y. Huo, X. Zhao (2007)
Flow and Heat Transfer in Rough Micro Steel TubesExperimental Heat Transfer, 20
W. Qu, G. Mala, Dongqing Li (2000)
Heat transfer for water flow in trapezoidal silicon microchannelsInternational Journal of Heat and Mass Transfer, 43
Peiyi Wu, W. Little (1984)
Measurement of the heat transfer characteristics of gas flow in fine channel heat exchangers used for microminiature refrigeratorsCryogenics, 24
HY Wu, P Cheng (2003)
An experimental study of convective heat transfer in silicon microchannels with different surfaceInt J Heat Mass Transf, 46
S. Kakaç, Y. Yener, A. Pramuanjaroenkij (1995)
Convective Heat Transfer
S.L. Qi, P. Zhang, Ruzhu Wang, L. Xu (2007)
Single-phase pressure drop and heat transfer characteristics of turbulent liquid nitrogen flow in micro-tubes.International Journal of Heat and Mass Transfer, 50
G. Maranzana, I. Perry, D. Maillet (2004)
Mini- and micro-channels: influence of axial conduction in the wallsInternational Journal of Heat and Mass Transfer, 47
P. Hao, Z. Yao, Feng He, K. Zhu (2006)
Experimental investigation of water flow in smooth and rough silicon microchannelsJournal of Micromechanics and Microengineering, 16
B. Wang, X. Peng (1994)
Experimental investigation on liquid forced-convection heat transfer through microchannels☆International Journal of Heat and Mass Transfer, 37
R. Phillips (1988)
Microchannel heat sinks, 1
S Al-Fahed, LM Chamra, W Chakroun (1998)
Pressure drop and heat transfer comparison for both micro fin tube and twisted-tape inserts in laminar flowJ Heat Transf, 18
IE Idelchik (1986)
Handbook of hydraulic resistance, Chap. 2
V. Natrajan, K. Christensen (2010)
The impact of surface roughness on flow through a rectangular microchannel from the laminar to turbulent regimesMicrofluidics and Nanofluidics, 9
S. Kandlikar, D. Schmitt, A. Carrano, J. Taylor (2005)
Characterization of surface roughness effects on pressure drop in single-phase flow in minichannelsPhysics of Fluids, 17
G. Mala, Dongqing Li (1999)
Flow characteristics of water in microtubesInternational Journal of Heat and Fluid Flow, 20
D. Tuckerman, R. Pease (1981)
High-performance heat sinking for VLSIIEEE Electron Device Letters, 2
Z Liu, C Zhang, Y Huo, X Zhao (2007)
Flow and heat transfer in rough microtubesExp Heat Transf, 20
O. Mokrani, B. Bourouga, C. Castelain, H. Peerhossaini (2009)
Fluid flow and convective heat transfer in flat microchannelsInternational Journal of Heat and Mass Transfer, 52
Zhigang Liu, S. Liang, M. Takei (2007)
Experimental study on forced convective heat transfer characteristics in quartz microtubeInternational Journal of Thermal Sciences, 46
G. Celata, M. Cumo, V. Marconi, S. McPhail, G. Zummo (2006)
Microtube liquid single-phase heat transfer in laminar flowInternational Journal of Heat and Mass Transfer, 49
P. Gravesen, J. Branebjerg, O. Jensen (1993)
Microfluidics-a reviewJournal of Micromechanics and Microengineering, 3
Huiying Wu, P. Cheng (2003)
An experimental study of convective heat transfer in silicon microchannels with different surface conditionsInternational Journal of Heat and Mass Transfer, 46
Mohammad Elyyan (2008)
Heat Transfer Augmentation Surfaces Using Modified Dimples/Protrusions
G. Croce, P. D’Agaro, C. Nonino (2007)
Three-dimensional roughness effect on microchannel heat transfer and pressure dropInternational Journal of Heat and Mass Transfer, 50
O. Jones (1976)
An Improvement in the Calculation of Turbulent Friction in Rectangular DuctsJournal of Fluids Engineering-transactions of The Asme, 98
RK Shah, AL London (1978)
Laminar flow forced convection in ducts (advances in heat transfer, Supplement 1)
D. Lelea, S. Nishio, K. Takano (2004)
The experimental research on microtube heat transfer and fluid flow of distilled waterInternational Journal of Heat and Mass Transfer, 47
M. Rahman (2000)
Measurements of heat transfer in microchannel heat sinksInternational Communications in Heat and Mass Transfer, 27
V. Natrajan, K. Christensen (2008)
Two-color laser-induced fluorescent thermometry for microfluidic systemsMeasurement Science and Technology, 20
N. Nguyen, D. Bochnia, R. Kiehnscherf, W. Dötzel (1996)
Investigation of forced convection in microfluid systemsSensors and Actuators A-physical, 55
C. Tso, S. Mahulikar (2000)
Experimental verification of the role of Brinkman number in microchannels using local parametersInternational Journal of Heat and Mass Transfer, 43
S. Hong, A. Bergles (1974)
Augmentation of Laminar Flow Heat Transfer in Tubes by Means of Twisted-Tape InsertsJournal of Heat Transfer-transactions of The Asme, 98
G. Morini (2005)
Viscous heating in liquid flows in micro-channelsInternational Journal of Heat and Mass Transfer, 48
G. Croce, P. D’Agaro (2005)
Numerical simulation of roughness effect on microchannel heat transfer and pressure drop in laminar flowJournal of Physics D: Applied Physics, 38
The convective heat transfer behavior of laminar flow through a smooth- and two rough-wall microchannels is investigated by performing non-intrusive and spatially resolved measurements of fluid temperature via two-color fluorescent thermometry under constant heat flux conditions at three of the four microchannel walls. Pressure-drop measurements reveal that the apparent friction factors for all surfaces agree well with established macroscale predictions for laminar flow through rectangular ducts with the onset of transition at Re > Recr = 1,800 for smooth-wall flow and deviation from laminar behavior at progressively lower Re with increasing surface roughness. The local Nu for smooth-wall flow agrees well with macroscale predictions in both the thermally developing and developed regimes. With increasing roughness, while an enhancement in local Nu is noted for flow in the thermally developing regime, no measurable influence is noted upon attainment of a thermally developed state. These observations are supported by the examination of temperature profiles across the microchannel at various axial positions and Re, which suggest that the thermal boundary layer may be regenerated locally by roughness in the thermal entrance region of the flow resulting in an increased axial distance (compared to smooth-wall behavior) at which thermally developed flow is attained in the presence of roughness. Finally, estimates of the bulk Nu indicate enhancement in convective heat transfer over the smooth-wall case for laminar flow at higher Re while the smooth-wall bulk Nu data are found to agree well with macroscale predictions.
Experiments in Fluids – Springer Journals
Published: Mar 8, 2010
Access the full text.
Sign up today, get DeepDyve free for 14 days.