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Microscale heat transfer

Chaudhari AM, Woudenberg TM, Albin M, Goodson KE (1998) Transient liquid crystal thermometry of microfabricated PCR vessel arrays. J Microelectromech Sys 7 345-355 Cheng P, Wu WY (2006) Mesoscale and microscale phase heat transfer. In Greene G, Cho Y, Hartnett J, Bar-Cohen A (eds) Advances in heat transfer, vol 39. Elsevier, Amsterdam Choi SB, Barron RF, Warrington RQ (1991) Fluid flow and heat transfer in micro- tubes. ASME DSC 40 89-93... [Pg.93]

Guo ZY, Li ZX (2003) Size effect on single-phase channel flow and heat transfer at microscale. Int J Heat Mass Transfer 24 284-298... [Pg.93]

Sobhan CB, Garimella SV (2001) A comparative analysis of studies on heat transfer and fluid flow in micro-channels. Microscale Thermophys Eng 5 293-311 Steinke M, Kandlikar SG (2003) Flow boiling and pressure drop in parallel flow micro-channels. In Kandlikar SG (ed) Proceedings of 1st International Conference on Micro-channels and Mini-channels, Rochester, 24-25 April 2003, pp 567-579 Thome JR (2006) State-of-the-art overview of boiling and two-phase flows in microchannels. Heat Transfer Eng 27(9) 4-19... [Pg.97]

Webb RL, Zhang M (1998) Heat transfer and friction in small diameter channels. Microscale Thermophys Eng 2 189-202... [Pg.97]

Yoo JY (2006) Recent studies on fluid flow and heat transfer in thermal microdevices. Nanoscale Microscale Thermophys Eng 10 67-81... [Pg.98]

Duncan AB, Peterson GP (1994) Review of microscale heat transfer. Appl Mech Rev 47 397 28... [Pg.140]

Lelea D, Nishio S, Takano K (2004) The experimental research on micro-tube heat transfer and fluid flow of distilled water. Int J Heat Mass Transfer 47 2817-2830 Li ZX, Du DX, Guo ZY (2003) Experimental study on flow characteristics of liquid in circular micro-tubes. Microscale Thermophys Eng 7 253-265 Lindgren ER (1958) The transition process and other phenomena in viscous flow. Arkiv fur Physik 12 1-169... [Pg.141]

Plam B (2000) Heat transfer in microchannels. In Heat Transfer and Transport Phenomena in Microscale. Banff Oct 54-64... [Pg.141]

Asako Y, Toriyama H (2005) Heat transfer characteristics of gaseous flows in micro-channels. Microscale Thermophys Eng 9 15-31... [Pg.188]

Sobhan CB, Gaiimella SV (2001) A comparative analysis of studies on heat transfer and fluid flow in micro-channels. Microscale Thermophys Eng 5 293-311 Tuckerman D (1984) Heat transfer micro structure for integrated circuits. Dissertation, Stanford University, Stanford... [Pg.464]

Palm, B.. Heat transfer in microchannels, Microscale Therm. Eng. 5 (2001) 155-175. [Pg.251]

Mathematical modeling is the science or art of transforming any macro-scale or microscale problem to mathematical equations. Mathematical modeling of chemical and biological systems and processes is based on chemistry, biochemistry, microbiology, mass diffusion, heat transfer, chemical, biochemical and biomedical catalytic or biocatalytic reactions, as well as noncatalytic reactions, material and energy balances, etc. [Pg.2]

Takeda, T., Kunitomi, K., Horie, T., Iwata, K., Feasibility study on the applicability of a diffusion-welded compact intermediate heat exchanger to next-generation high temperature gas-cooled reactor, Nucl. Eng. Des. 1997, 168,11-21. Bier W., Keller W., Linder G., Seidel, D., Schubert, K., Martin, H., Gas-to-gas heat transfer in micro heat exchangers, Chem. Eng. Process. 1993, 32, 33-43. Schubert, K., Brandner J., Fichtner M., Linder G., Schygulla, U., Wenka, A., Microstructure devices for applications in thermal and chemical process engineering, Microscale Therm. Eng. 2001, 5,17-39. www.fzk.de, Forschungszentrum Karlsruhe, 17 July 2004. [Pg.407]

Microscale Disturbances Inside the Viscous Sublaye, J. Heat Transfer. Vol. 114, pp. 348-353, 1992. 1... [Pg.253]

Recent inventions in micro and nano-scale systems and the development of micro and nano-scale devices continues to pose new challenges, and the understanding of the fluid flow and heat transfer at such scales is becoming more and more important. In Chapter 6, microscale heat transfer is presented as a Topic of Special Interest. [Pg.13]

Heat transfer considerations play a crucial role in the design and operation of many modern devices. New approaches and methods of analyses have been developed to understand and modulated (enhance or suppress) such energy interactions. Modulation typically occurs through actively controlling the surface phenomena, or focusing of the volumetric energy. In this section we discuss one such example microscale heat transfer. [Pg.404]

The conventional macroscopic Fourier conduction model violates this non-local feature of microscale heat transfer, and alternative approaches are necessary for analysis. The most suitable model to date is the concept of phonon. The thermal energy in a uniform solid material can be jntetpreied as the vibrations of a regular lattice of closely bound atoms inside. These atoms exhibit collective modes of sound waves (phonons) wliich transports energy at tlie speed of sound in a material. Following quantum mechanical principles, phonons exhibit paiticle-like properties of bosons with zero spin (wave-particle duality). Phonons play an important role in many of the physical properties of solids, such as the thermal and the electrical conductivities. In insulating solids, phonons are also (he primary mechanism by which heal conduction takes place. [Pg.405]

S. Kakag et al. (eds.), Microscale Heat Transfer, 1-24. 2005 Springer. Printed in the Netherlands. [Pg.1]

A NATO Advanced Study Institute was held, between July 18 - 30, 2004, in Qe me-Izmir, Tiirkiye to discuss the fundamentals and applications of microscale heat transfer in biological and microelectromechanical systems. During the institute, the most recent state-of-the-art developments have been presented in considerable depth by eminent researchers in the field. This current volume, edited by Kaka et al. [19] brings together the important contributions from the institute as a permanent reference for the use of researchers in the field. [Pg.19]

A number of heat transfer and fluid transport issues at the microscale surveyed can be summarized as follows ... [Pg.19]

Kakag, S., Vasiliev, L.L., Bayazitoglu, Y. and Yener, Y., (eds.). Microscale Heat Transfer - Fundamentals and Applications, 2005, Kluwer, The Netherlands. Kavehpour, H.P., Faghri, M. and Asako, Y., Effects of Compressibility and Rarefaction on Gaseous Flows in Microchannels, Numerical Heat Transfer, 1997, Part A, 32, 677-696. [Pg.22]

See other pages where Microscale heat transfer is mentioned: [Pg.291]    [Pg.303]    [Pg.291]    [Pg.303]    [Pg.142]    [Pg.189]    [Pg.191]    [Pg.253]    [Pg.343]    [Pg.59]    [Pg.251]    [Pg.252]    [Pg.83]    [Pg.528]    [Pg.543]    [Pg.122]    [Pg.88]    [Pg.83]    [Pg.257]    [Pg.284]    [Pg.141]    [Pg.7]    [Pg.13]    [Pg.404]    [Pg.412]    [Pg.1]   
See also in sourсe #XX -- [ Pg.385 , Pg.386 , Pg.387 ]



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