International Journal of Heat and Mass Transfer 53 (2010) 4397–4447
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International Journal of Heat and Mass Transfer journal homepage: www.elsevier.com/locate/ijhmt
Review
Heat transfer—A review of 2005 literature R.J. Goldstein , W.E. Ibele, S.V. Patankar, T.W. Simon, T.H. Kuehn, P.J. Strykowski, K.K. Tamma, J.V.R. Heberlein, J.H. Davidson, J. Bischof, F.A. Kulacki, U. Kortshagen, S. Garrick, V. Srinivasan, K. Ghosh, R. Mittal *
Heat Transfer Laboratory, Department of Mechanical Engineering, University of Minnesota, Minneapolis, MN, USA
a r t i c l e
i n f o
Article history:
Received 20 March 2010 Received in revised form 26 March 2010 Accepted 26 March 2010 Available online 7 July 2010 Keywords:
Conduction Boundary layers Internal flows Porous media Heat transfer Experimental methods Natural convection Rotating flows Mass transfer Bio-heat transfer Melting Freezing Boiling Condensation Radiative heat transfer Numerical methods Transport properties Heat exchangers Solar energy Thermal plasmas
a b s t r a c t
The present review is intended to encompass the heat transfer literature published in 2005. While of a wide-range in scope, some selection is inevitable. We restrict ourselves to papers published in English through a peer-review process, with selected translations from journals published in other languages. Papers from conference proceedings generally are not included, though the Proceeding itself may be cited in the introduction. A significant fraction of the papers reviewed herein relates to the science of heat transfer, including experimental, analytical and numerical studies. Other papers cover applications where heat transfer plays a major role, not only in man-made devices but in natural systems as well. The papers are grouped into major subject areas and then into subfields within these areas. In addition to reviewing the literature, we mention major conferences held in 2005, major awards related to heat transfer presented in 2005, and books on heat transfer published during the year. Ó 2010 Published by Elsevier Ltd.
Contents
1. Intro Introduc ductio tion. n. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A. Con Condu duct ctio ion n ............. ............ ............ ............ ............. ............ ............ ............. ..... B. Bound Boundary ary layer layerss and exter external nal flows flows.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . C. Cha Chann nnel el flo flows ws . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D. Separ Separate ated d flows flows . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DP. Heat Heat tran transfe sferr in porou porouss media. media. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E. Exper Experime imenta ntall method methodss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . F. Natur Natural al conve convecti ction— on—int intern ernal al flows flows . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . FF. Natu Natural ral conve convecti ction— on—ext extern ernal al flows flows . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . G. Conve Convecti ction on from from rotat rotating ing surf surface aces. s. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . H. Combi Combined ned heat heat and and mass mass trans transfer. fer. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . I. Biohe Bioheat at trans transfer fer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . *
Corresponding author. E-mail address:
[email protected] (R.J. Goldstein).
0017-9310/$ - see front matter Ó 2010 Published by Elsevier Ltd. doi:10.1016/j.ijheatmasstransfer.2010.05.005 doi:10.1016/j.ijheatmasstransfer.2010.05.005
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J. Change of phase—boiling and evaporation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4404 JJ. Change of phase—condensation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4405 JM. Change of phase—freezing and melting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4405 K. Rad Radia iati tion on . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4406 4406 N. Numer Numerica icall method methodss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4407 4407 P. Prop Propert erties. ies. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4407 4407 Q. Heat Heat transf transfer er appli applicat cation ions—h s—heat eat excha exchang ngers ers and and thermo thermosyp syphon honss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4407 4407 S. Heat Heat transfe transferr applic applicati ations ons—ge —gener neral al . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4408 4408 T. Sol Solar ar ene energ rgy. y. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4409 4409 U. Plasm Plasmaa heat tran transfe sferr and MHD MHD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4409 4409 Refe Refere renc nces es . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4409 4409
1. Introduction
As in previous previous years, a considerabl considerablee effort has been devoted to research in traditional applications such as chemical processing, general manufacturing, and energy conversion devices, including general power systems, heat exchangers, and high performance gas turbines. In addition, a significant number of papers address topics that are at the frontiers of both fundamental research and important emerging technologies, including nanoscale structures, microchannel flows and bio-heat transfer. The present review considers the heat transfer literature published lished in 2005. While While intending intending to be exhaustive, exhaustive, some selection is inevitable. We restrict ourselves to papers published in English language through a peer-review process, with selected translations from journals published in other languages also having been included. cluded. The papers are grouped into separate separate subject subject related sections and then into subfields within these sections. In addition to reviewing the literature, we mention major heat transfer related conferences, major awards and books on heat transfer published during the year. The International Center for Heat and Mass Transfer organized SPRAY’05, the International Symposium on Heat and Mass Transfer in Spray Systems, in Antalya, Turkey from 5 to 10 June. Sessions addressed turbulence effects on interfacial phenomena, vaporization, combustion, droplet impact on heated surfaces, and spray cooling. The ASME Turbo Expo was organized by the International Gas Turbine Institute from 6 to 9 June in Reno, USA. The Heat Transfer Division conducted numerous sessions with a focus on heat transfer effects related to laminar-turbulent transition, internal air systems and seals, and combustion. At INTERPACK’05 held in San Francisco, USA from 17 to 22 July, several sessions were held on thermal management of micro-electronic and photonic systems, microscale heat transfer phenomena in electronics, thermal interface materials, heat pipes, and data center cooling. At a conference on Interdiscip Interdisciplinar linaryy Transport Transport Phenomena Phenomena in Microgravity Microgravity and Space Sciences held in Tomar, Portugal from 7 to 12 August, papers were presented on topic including but not limited to thermophysical property measurements, diffusion effects in crystal growth, boiling, biotransport phenomena, and interfacial phenomena. The International Solar Energy Conference from 6 to 12 August included sessions on ocean thermal power, solar ponds, and solar thermal power. The Fifth International Conference on Enhanced, Compact, and Ultra-Compact Heat Exchangers held from 11 to 16 September September in Whistler, Whistler, Canada discussed discussed fundamental fundamental studies in single- and multi-phase flow, design data and methodology, and micro-heat exchangers. A meeting on Heat Transfer Fluid Flow at the Microscale was organized in Barga, Italy on 25–30 September. Topics covered included measurement techniques, two-phase flow in microchannels, microfluidic systems and molecular dynamic simulations. At the International Mechanical Engineering Congress and Exposition (IMECE) held on 5–11 November in Orlando, USA,
sessions on heat tra nsfer discussed various topics including gas–liquid and phase-change flows at the microscale, heat pipes and property estimation. The 2004 Max Jakob Memorial award was presented to Dr. V.K. Dhir for his pioneering work in the fundamentals and applications of boiling heat transfer, such as his contributions to the study of boiling in microgravity, and cooling of high heat flux devices. The 2005 Heat Transfer Memorial Awards were conferred on A. HajiSheikh (Science), M. Modest (Art), and Wei Shyy (General). The Donald Q. Kern Award for 2004 was given to Dr. Ramesh K. Shah at the Summer Annual Heat Transfer Conference, San Francisco, USA on July 19, 2005. Books pertaining to heat transfer which were published in 2005 are the following: Heat Heat Tran Transf sfer er and and Flui Fluid d Flo Flow in Mini Minicchan hannels nels and and Microchannels S. Kandlikar, D. Li, S. Garimella Elsevier The Equations of Radiation Hydrodynamics G.C. Pomraning Dover Publications Finite Element Method: Applications in Solids, Structures, and Heat Transfer M.R. Gosz Marcel Dekker Thermo-fluid Dynamics of Two-Phase Flow M. Ishi, T. Hibiki Springer-Verlag, New York Transport Phenomena in Porous Media, Volume III I. Pop, D.B. Ingham Elsevier Thermal Food Processing: New Technologies and Quality Issues D.-W. Sun CRC Press Computational Methods for Heat and Mass Transfer P. Majumdar Taylor & Francis Heat Transfer Calculations M. Kutz McGraw-Hill
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J. Change of phase—boiling and evaporation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4404 JJ. Change of phase—condensation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4405 JM. Change of phase—freezing and melting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4405 K. Rad Radia iati tion on . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4406 4406 N. Numer Numerica icall method methodss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4407 4407 P. Prop Propert erties. ies. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4407 4407 Q. Heat Heat transf transfer er appli applicat cation ions—h s—heat eat excha exchang ngers ers and and thermo thermosyp syphon honss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4407 4407 S. Heat Heat transfe transferr applic applicati ations ons—ge —gener neral al . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4408 4408 T. Sol Solar ar ene energ rgy. y. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4409 4409 U. Plasm Plasmaa heat tran transfe sferr and MHD MHD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4409 4409 Refe Refere renc nces es . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4409 4409
1. Introduction
As in previous previous years, a considerabl considerablee effort has been devoted to research in traditional applications such as chemical processing, general manufacturing, and energy conversion devices, including general power systems, heat exchangers, and high performance gas turbines. In addition, a significant number of papers address topics that are at the frontiers of both fundamental research and important emerging technologies, including nanoscale structures, microchannel flows and bio-heat transfer. The present review considers the heat transfer literature published lished in 2005. While While intending intending to be exhaustive, exhaustive, some selection is inevitable. We restrict ourselves to papers published in English language through a peer-review process, with selected translations from journals published in other languages also having been included. cluded. The papers are grouped into separate separate subject subject related sections and then into subfields within these sections. In addition to reviewing the literature, we mention major heat transfer related conferences, major awards and books on heat transfer published during the year. The International Center for Heat and Mass Transfer organized SPRAY’05, the International Symposium on Heat and Mass Transfer in Spray Systems, in Antalya, Turkey from 5 to 10 June. Sessions addressed turbulence effects on interfacial phenomena, vaporization, combustion, droplet impact on heated surfaces, and spray cooling. The ASME Turbo Expo was organized by the International Gas Turbine Institute from 6 to 9 June in Reno, USA. The Heat Transfer Division conducted numerous sessions with a focus on heat transfer effects related to laminar-turbulent transition, internal air systems and seals, and combustion. At INTERPACK’05 held in San Francisco, USA from 17 to 22 July, several sessions were held on thermal management of micro-electronic and photonic systems, microscale heat transfer phenomena in electronics, thermal interface materials, heat pipes, and data center cooling. At a conference on Interdiscip Interdisciplinar linaryy Transport Transport Phenomena Phenomena in Microgravity Microgravity and Space Sciences held in Tomar, Portugal from 7 to 12 August, papers were presented on topic including but not limited to thermophysical property measurements, diffusion effects in crystal growth, boiling, biotransport phenomena, and interfacial phenomena. The International Solar Energy Conference from 6 to 12 August included sessions on ocean thermal power, solar ponds, and solar thermal power. The Fifth International Conference on Enhanced, Compact, and Ultra-Compact Heat Exchangers held from 11 to 16 September September in Whistler, Whistler, Canada discussed discussed fundamental fundamental studies in single- and multi-phase flow, design data and methodology, and micro-heat exchangers. A meeting on Heat Transfer Fluid Flow at the Microscale was organized in Barga, Italy on 25–30 September. Topics covered included measurement techniques, two-phase flow in microchannels, microfluidic systems and molecular dynamic simulations. At the International Mechanical Engineering Congress and Exposition (IMECE) held on 5–11 November in Orlando, USA,
sessions on heat tra nsfer discussed various topics including gas–liquid and phase-change flows at the microscale, heat pipes and property estimation. The 2004 Max Jakob Memorial award was presented to Dr. V.K. Dhir for his pioneering work in the fundamentals and applications of boiling heat transfer, such as his contributions to the study of boiling in microgravity, and cooling of high heat flux devices. The 2005 Heat Transfer Memorial Awards were conferred on A. HajiSheikh (Science), M. Modest (Art), and Wei Shyy (General). The Donald Q. Kern Award for 2004 was given to Dr. Ramesh K. Shah at the Summer Annual Heat Transfer Conference, San Francisco, USA on July 19, 2005. Books pertaining to heat transfer which were published in 2005 are the following: Heat Heat Tran Transf sfer er and and Flui Fluid d Flo Flow in Mini Minicchan hannels nels and and Microchannels S. Kandlikar, D. Li, S. Garimella Elsevier The Equations of Radiation Hydrodynamics G.C. Pomraning Dover Publications Finite Element Method: Applications in Solids, Structures, and Heat Transfer M.R. Gosz Marcel Dekker Thermo-fluid Dynamics of Two-Phase Flow M. Ishi, T. Hibiki Springer-Verlag, New York Transport Phenomena in Porous Media, Volume III I. Pop, D.B. Ingham Elsevier Thermal Food Processing: New Technologies and Quality Issues D.-W. Sun CRC Press Computational Methods for Heat and Mass Transfer P. Majumdar Taylor & Francis Heat Transfer Calculations M. Kutz McGraw-Hill
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Heat and Mass Transfer Shyam Anshan Publishing Principles of Enhanced Heat Transfer R.L. Webb, N.-H. Kim Taylor & Francis Free-Convective Heat Transfer O.G. Martynenko, P.P. Khramtsov Springer-Verlag, New York Properties of Glass Formation Melts D.L. Pye, J. Innocent, M. Angelo CRC Press Engineering Thermofluids M. Massoud Springer-Verlag, New York Handbook of Porous Media K. Vafai (Ed.) CRC Press Nanoscale Energy Transport and Conversion G. Chen Oxford University Press
A. Conduction
Highlights of papers dealing with heat conduction in solids structures, and materials, and the relevant literature appear in this section dealing with a wide variety of subcategories. The various subcategories include (1) contact conduction/contact resistance; (2) microscale/nanoscale heat transport, and wave propagation; (3) heat transfer in fins, composites, and complex geometries; (4) analytical analytical and numerical numerical methods and analysis, analysis, (5) experimental experimental and/or and/or compara comparativ tivee studie studies; s; (6) therma thermall stress stress and thermo thermo-mechanical mechanical problems; and (7) miscellaneo miscellaneous us application applications. s. These are briefly referenced as follows. 1. Contact conduction/contact conduction/contact resistance Papers Papers in this this subcate subcategor goryy deal with with drople droplets ts and surfac surfaces es [A1,A2],, slidin [A1,A2] slidingg surfac surfaces es [A3,A4] [A3,A4],, and other other app applic licati ations ons [A5] including roughness characteristics [A6] [A6].. 2. Microscale/nanoscale heat transport and wave propagation Various papers dealing with brownian motion [A7] [A7],, hyperbolic heat conduction [A8–A14] [A8–A14],, nanoparticles, nanotubes, and nanocomposites [A15–A17] [A15–A17],, and phonon transport [A18,A19] appear. 3. Heat transfer in fins, composites, and complex geometries The studies in this subcategory deal with layered materials and slabs and/or composites [A20–A25] [A20–A25],, fins and different geometries [A26–A33],, and other applications [A34] [A26–A33] [A34].. 4. Analytical and numerical methods and analysis In this subcategory, papers dealing with various types of solution methods methods [A35–A43] [A35–A43],, numeric numerical al simula simulatio tions ns and analys analysis is [A44–A56],, various specialized applications [A57–A75] [A44–A56] [A57–A75],, and inverse problems [A76–A81] appear. 5. Experimental and/or comparative studies Experimental and/or comparative studies appear in specialized applications such as two-layer systems [A82] and machined surfaces [A83] [A83]..
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6. Thermal stress and thermomechanical problems Thermal and/or thermomechanical studies in metal films [A84] [A84],, thick walled spherical vessel [A85] [A85],, MEMS [A86] [A86],, falling film [A87] [A87],, and functionally graded rectangular plate [A88] appear in this subcategory. 7. Miscellaneous Miscellaneous applications applications Various miscellaneous and specialized applications and studies dealing with a wide variety of issues on heat conduction appear in [A89–A97].. [A89–A97] B. Boundary layers and external flows
Papers on boundary layers and external flows for 2005 have been categorized as follows: flows influenced externally, flows with special geometric effects, compressible and high-speed flows, analysis and modeling techniques, unsteady flow effects, flows with film and interfacial effects, flows with special fluid types or property effects, and flows with combustion and other reactions. 1. External effects External effects on boundary layers addressed in the 2005 literature include imposed magnetic fields, electrical fields, and reduce duced d grav gravit itati ation onal al field fieldss and and heat heat tran transf sfer er with with vari variou ouss approach flow directions [B1–B8] [B1–B8].. 2. Geometric effects As in previous years, many papers deal with variations in geometry. Such geometric features include surface micro-profiling; surface face-m -mou ount nted ed delt delta-w a-win ingl glets ets;; elec electr tron onic ic comp compon onen ents ts or distributed heating elements; solder balls; shallow cavities in the surface; surface; steps in the wall; fins of various shapes, sizes, and orientations to the flow; cylinders of various shapes, including elliptical cylinders; monodispersed droplets; and oblate spheroids. Several papers dealt with turbine blade geometries geometries endwalls, airfoil surfaces, and the junctions between them. Moving surface geometries include stretching sheets. The most popular application area in this category in 2005 was electronics cooling [B9–B44] [B9–B44].. 3. Compressibility and high-speed flow effects Three papers were presented in 2005 on compressibility effects. These were related to turbine blade tip heat transfer with localized shocks and a compressible atmosphere [B45–B47] [B45–B47].. 4. Analysis and modeling Numerous papers addressed developments in modeling. These include a homotopy analysis method applied to electrically conducting fluids on stretching surfaces; inverse Fourier transform solutions solutions to convectio convection/con n/conducti duction on transient transient heat transfer transfer problems; new solution techniques for heat transfer problems with distributions tributions of wall temperature; temperature; techniques techniques using distributeddistributedvortices for heat transfer from horizontal plates of finite length; discriminated dimensional analyses; and differential transformation methods for wedge flows. A generalized methodology was presented for optimum design of thin heated fins; another employed genetic algorithm-based evolutionary computing for fin optimizatio optimization. n. Optimized Optimized flow architectur architectures es were presented presented for maximizing heat transfer density in cylinder arrays. A universal solution was presented for convective heat transfer to moving sheets. Different scaling relationships for transpired boundary layers were proposed. A model was formulated for boundary layer transition on a flat plate. A method was offered for finding the multiple tiple soluti solutions ons of the convec convectiv tivee heat heat transfe transferr equati equation. on. The uniqueness of limit solutions for combustion systems was investigated. Turbulence models applied to heat transfer in rod bundles or electronics cooling applications were discussed. An entropy generation analysis for flat plate boundary layer heat transfer was con-
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ducted using several solution techniques. A means of correction for two-dimensional fin analysis errors was given. An analysis was presented for laminar flow over a porous plate with injection. A semianalytical-numerical technique was presented for slip flow over a free disk. And, cases with heat transport against the driving gradient were discussed [B48–B68] [B48–B68].. 5. Unsteady effects Papers on unsteady effects include convection and flow bifurcation with sudden expansion; responses to sudden changes in heat flux or temperature at the surface; two-dimensional wave disturbances; flow oscillations; plate vibration near heated walls; transient sient heatin heatingg during during grindi grinding; ng; period periodic ic heatin heatingg for therma thermall control; control; unsteady unsteady operation operation of electronics electronics;; and transient transient heating heating and moisture transfer in insulations. Instabilities in buoyant flow boundary layers on flexible surfaces and in side-heated cavities were described [B69–B82] [B69–B82].. 6. Films and interfacial effects Three papers were found in this category. In one, an electric field was applied for heat transfer enhancement to a drop; in another, heat transfer in liquid bridges was described; and, in the third, heat transfer in a falling water film was studied numerically and experimentally [B83–B85] [B83–B85].. 7. Effects of fluid type or fluid properties Papers on the effects of fluid types discuss liquid helium over chemically oxidized or anodized copper plates; non-Newtonian fluids; micropolar fluids; perfectly-conducting polar fluids; foreign gases injection through permeable surfaces into boundary layers; and diffusion in concrete subjected to heating. Several papers were on variable viscosity or other fluid property effects. Finally, viscous dissipation in mixed convection over an exponentially stretching surface was analyzed [B86–B96] [B86–B96].. 8. Flows with reactions Flows with reactions include combustion of straw on a gratebased boiler and a study of scaling laws for heat release in exothermic reacting mixing layers [B97,B98] [B97,B98].. C. Channel flows
The review of articles for channel flow heat transfer was subcategorized into the following areas str aight-wall channels and ducts; ducts having fins or profiling for heat transfer enhancement; flow and heat transfer in channels in complex geometries; unsteady and transient flow and heat transfer in channels; micro-channel heat transfer; and channel flows with multiphase and non-Newtonian flow. 1. Straight-walled ducts Experimental Experimental and computation computational al studies studies were conducted conducted in a variety of ducts having the general characteristic of straight walls. Turbulent Turbulent flows were modeled in circular, circular, square and concentric concentric annuli; uniform temperature and heat flux boundary conditions were imposed, as well as asymmetric boundary conditions. Mixed convection convection was studied studied in annular annular channels channels under under laminar laminar and turturbulent flows and in a horizontal square duct with local inner heating. Maintaining uniform surface temperature was considered for insulated pipes. Duct cross sections shape was considered on Nusselt number; rectangular, semicircular, square duct and planar channel flows were investigated. The accuracy of algebraic models was examined in circular pipes, channels, and concentric annuli [C1–C34].. [C1–C34] 2. Finned and profiled ducts The 2005 literature continued to examine a rich collection of channels dominated by roughness, turbulators, local heat genera-
tion, and general profiling for heat transfer augmentation—the majority of studies were computational in nature. Experimental studies included the insertion of twisted tapes, spirals, and wire coils for heat transfer enhancement. Mixed convection was studied as it developed over heated blocks in a channel. Cross-angled ribs were studied using LES in a rectangular channel; tandem cylinder sources sources were investigated investigated in laminar laminar flow; continuous continuous and truncated ribs were investigated experimentally in a square duct; and a design of simulation method was used to reduce the complexity of multi-variable problems [C35–C77] [C35–C77].. 3. Irregular geometries Duct geometries that are not generally straight walled nor dominated by fins and/or profiling are captured in this category. Flow and heat transfer for fully developed turbulent flow was studied computationally in a corrugated duct with variable width. Spiraled ducts having circular and rectangular cross-sections were investigated; the commercial code FLUENT was used in one study. Baffles were used in inclined channels and near the inlet of a channel to produce produce unsteadine unsteadiness. ss. A parallelogra parallelogrammic mmic partial enclosure enclosure of stacked elements was studied numerically; an LES was conducted of turbulent flow and heat transfer in a channel with a single wavy wall; right-angled triangular cavities were investigated where the vertical walls were heated and the hypotenuse was cooled; and heat heat transf transfer er was calcul calculated ated in Ranque Ranque–Hi –Hilsc lsch’s h’s vortex vortex tube tube [C78–C110].. [C78–C110] 4. Periodic and unsteady channel flows Unsteady or periodically forced channel flows were studied in a variety of configurations, including periodically fully developed flow and heat transfer in corrugated triangular channels in the transitional flow regime; in a pulsatile flow to study local transient entropy entropy generation; generation; under unsteady unsteady turbulent turbulent conditions conditions in a reciprocating circular ribbed channel; for a pulsative turbulent pipe flow with a liquid of variable properties; unsteady oscillatory flow in a horizo horizonta ntall channe channel; l; and for heat heat transfe transferr enhanc enhanceement from rectangular blocks in a pulsating channel flow [C111– C134].. C134] 5. Microchannel flow and heat transfer Mini-, micro,- and nano-channel flow and heat transfer studies continued to have a strong showing in the channel flow literature in 2005, continuing a trend from 2004. Microchannels encompass a considerable range of scales and are seeing attention both computationally and experimentally. Gaseous microchannel flow was investigated in the transitional transitional regime; the heat transfer coefficient coefficient was determined for a minichannel, which was in good agreement with classical correlations; microchannel heat sinks were examined using constructal design and optimization techniques; techniques; viscous heating was considered in a microchannel; and heat transfer augmentation mentation was studied studied experimental experimentally ly in a three-dimen three-dimension sional al internally finned microfinned helical tube [C135–C166] [C135–C166].. 6. Non-Newtonian and multiphase heat transfer in channels The multiphase literature is seeing an increased attention to nanofluids with a focus on those flow conditions most conducive to heat transfer augmentation. Microsize phase-change material particles were evaluated in liquid flow; the conduction properties of sub-100nm particles were studied studied in terms of heat transfer characteristics as well as migration properties; nanofluids were also considered as a replacement for traditional coolants, comparing performance performance to common common metals; nanoparticl nanoparticles es were also used to improve heat transfer of nanolubricants; and diffusion effects were investigated for both nanoparticles and flexible hairy fins. Other flows considered involved the annular flow of air–water in vertical tubes, the behavior of ice slurries, slurries, and Bingham and Robertson-Stiff fluids [C167–C191] [C167–C191]..
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D. Separated flows
This section deals with papers addressing heat transfer characteristics in flows experiencing separation, either by rapid changes in geometry or strong adverse pressure gradient. This section also includes includes the thermal thermal behavior of flow past bluff objects, objects, jets, and reattachment. 1. Sudden expansions were studied in a variety of circumstances, including the effect of buoyancy on mixed convection heat and mass transfer; the influence of baffles on mixed convection downstream of a step; a numerical study of mixed convection over a three-dimensional backward-facing step; and LES was applied to an unsteady turbulent turbulent flow for an expansion expansion ratio of 2. Flow past single cylinders and banks of cylinders/tubes were investigated both computationally and experimentally. Fin placement and wake generators placed on a cylinder were used to optimize forced convection heat transfer. Vortex shedding and heat transfer we re studied from a heated square cylinder. Various cavity flows were studied, both forced and unforced, as well as under the influence of control [D1–D46] [D1–D46]..
DP. Heat transfer in porous media
Heat and mass transfer in porous media encompasses a wide range of technologies which continue to motivate numerical and experimental studies. Most of the theoretical papers published in 2005 are based on the Darcy–Brink Darcy–Brinkman–F man–Forche orcheimer imer formulation formulation of the momentum equation and either a one or two equation description of the thermal problem. A good number of the studies reported have included experiments for either establishing controlling physical quantities for a nalysis or validating multi-component convective diffusion models. Forced and mixed convection in saturated and unsaturated porous media received wide spread attention during the past year. Nearly all of the reported studies were numerical in nature, with few achieving closed form solutions for special cases. Steady free convection in saturated porous media was extensively addressed analytically and numerically for a wide range of thermophysical and structural properties, but few experiments were reported. Research on packed and fluidized beds has focused prediction of particle motion and heat transfer coefficients to immersed objects and surfaces. Review papers were published in design methods for heat transfer surface in bubbling and circulating beds and heat and mass transfer in fabric systems under equilibrium conditions. A growing topic of interest appears to be heat transfer transfer in metal foams. foams. 1. Combined heat and mass transfer A good number of studies of coupled heat and mass transfer have included included experiments experiments for either establishing establishing controllin controllingg physical physical quantities quantities for analysis analysis or validating validating multi-comp multi-component onent convective diffusion models. Fibrous materials, such as those that occur occur in clothing, clothing, are generally treated as capillary capillary materials and in several papers, as hygroscopic materials. One study of drying in a capillary porous wick identifies a two-phase zone between the vapor-saturated and the liquid-saturated zones in the wick. This leads to the development of a multi-zone model for further analysis and application. The drying of food stuffs, unsaturated soil, and paper was treated as a problem in coupled heat and mass transfer in which the formulation of boundary conditions the applicability of the results. In some cases, experiments are conducted to validate the modeling assumptions. The application of humid porous materials to the cooling of structures was analyzed as a problem to couple heat and mass transfer, and experimental data that validated the analysis were presented. Analytical techniques that either provide promising utility or suggest avenues
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for future development encompass inverse solutions and transfer function methods [DP1–DP24] [DP1–DP24].. 2. Combustion systems Combustion systems employing porous burners and reactors were the subject of several analytical and numerical studies aimed at predicting hot spots, ignition points, velocity profiles and temperature perature profiles. profiles. Limited experimental experimental work was published published on a novel reactor designed to achieve a uniform temperature in the reactions zone [DP25–DP29] [DP25–DP29].. 3. Fluidized beds Analytical work on heat transfer to imbedded surfaces and tubes in fluidized beds has focused on predictions of non-uniform flow effects, details of the cores regions flow, and description of wall and annular region flow. Generally the goal in this work is to predict heat transfer coefficients under various limiting assumptions. Experiments were reported on the cooling of immersed complex plex shapes shapes and heat heat exchan exchanger gers. s. Papers Papers add addres ressin singg partic particle le convection and void fraction near a surface also appeared, and one novel approach treated the fluidized medium as an emulsion near a surface. Design methods for heat transfer surface in bubbling bling and circulat circulating ing beds were presented presented in a review review paper [DP30–DP43].. [DP30–DP43] 4. Foams Foams and foam-like materials continue to be studied to predict their heat transfer capabilities through direct measurement and thermo-structural modeling. In some cases, volumetric heat transfer coefficients are determined for forced convection with pore per inch (PPI), or overall porosity, being the primary structural discriminator. The heat transfer capability of any particular foam was not however conclusively established based on porosity alone. Experimental studies generally report correlations in the Nusseltversus-Reyn versus-Reynolds olds number number form. Ad hoc hoc models, models, such as ordered rectilinear ligaments, meet with some success in predicting the overall heat transfer rates [DP44–DP51] [DP44–DP51].. 5. Forced and mixed convection Forced and mixed convection heat transfer in saturated and unsaturated porous media received wide spread attention during the past year. Nearly all of the reported studies were numerical in nature, with few achieving closed form solutions for special cases. Channel flows for randomly packed particles, fibrous systems and sintered metal particles were analyzed for a wide variety of thermal boundary conditions. Channel flows partially filled with a porous medium were analyzed as well. Conjugate heat transfer problems have reappeared as an area of interest for both Darcian and non-Darcian flows. A few studies considered channel flows of special shape, such as triangular and elliptical. External flow and heat transfer were analyzed for the case of constant wall temperature, as well as linearly varying wall temperature. Several papers focus on effects of heat generation, wall channeling, thermal non-equil non-equilibriu ibrium, m, radiation radiation interaction interaction,, viscous viscous dissipation dissipation,, nonuniform fluid properties, fluid compressibility, impingement flow, and developing flow. One paper has presented a generalized model of single and two-phase forced flow as it occurs in oil and gas recovery. Another analyzes transient flow in a way that suggests how effective permeability can be det ermined when pulsating flow is present [DP52–DP103] [DP52–DP103].. 6. Free convection Steady free convection in saturated porous media was extensively sively addressed addressed analyticall analyticallyy and numerically, numerically, but few experiments were reported. Effects on heat transfer of temperaturedependent dependent properties, properties, variable variable permeability permeability,, viscous viscous dissipation dissipation,, dispersion, anisotropy in the porous matrix, non-Newtonian fluids, and thermal non-equilibrium were reported generally for the dif-
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ferentially heated cavity as the standard test geometry. When twoequation models are exercised, it is found that Nusselt numbers tend to differ from those predicted with a homogenous continuum when Darcy number decreases. Free convection driven by heat generation, thermo-diffusion, Marangoni effects, and magnetic effects was of some interest as well. Sudden transitions in the flow field were also analyzed as a stability problem, and a special case treats the flow resulting from a sudden imposition of gravity. Papers also appeared on heat transfer from imbedded objects, in annular geometries and inclined layers, and from flat surfaces with transpiration and void formation due to evaporation. One study addressed the little researched topic of free convection in a vertical microchannel [DP104–DP142]. 7. Packed beds Prediction of complex single- and two-phase flows was the focus of the literature during the past year. Numerical analysis often with experimental validation address particle trajectories and circulation, gas liquid flows, gas holdup, and wall heat transfer coefficients. One study has identified two flow regimes for a two-phase bed homogenous and heterogeneous flow [DP143–DP147]. 8. Phase change and boiling Phase change processes and boiling in porous media were investigated in connection to a wide range of practical problems nuclear safety, crystal growth, transpiration cooling, alloy solidification, and modeling of moisture evaporation in fires. Modeling work dominates the literature and ranges from linear stability analysis of convection in super-posed layers mushy and liquid layers to self similar solutions for boiling with precipitation in rock fractures to film condensation. For a biporous medium with a regular structure and ice inclusions, one study shows the validity of the Onsager reciprocal relations when phase transformation occurs. Boiling in heat-generating porous layers was modeled via induction heating of the particle matrix. At sufficiently high heating rates, vapor channels form, and enhancement of heat transfer occurs due to buoyancy effects [DP148–DP158]. 9. Properties Determination of the permeability and effective thermal conductivity of a porous medium were the focus of experimental and numerical research. Experimental dominate the reported efforts at determining effective thermal conductivity. Numerical analysis, chiefly using probabilistic methods, was the focus of work on determining permeability of fractal porous media [DP159– DP165]. 10. Conduction in porous media Heat conduction in a fluid-filled porous medium has been investigated largely to address non-Fourier behavior, namely the conditions necessary for thermal disequilibrium between the solid and fluid phases and the emergence of thermal waves. One theoretical result suggested the existence of thermal oscillations and resonance. Some limited experimental data has appeared that validates a non-Fourier conduction model [DP166–DP169]. 11. Radiation in porous media Studies of thermal radiation in a porous medium have sought to predict the solid and fluid phase temperatures under the Rosseland approximation. In some cases, the effects of radiative surface properties of the porous structure are examined [DP170,DP171]. E. Experimental methods
Although one dream of some engineers and scientists may be that heat transfer results can be obtained for all systems through strictly numerical methods clearly that has not come to pass and probably never will. The need for experiments remains strong.
Even with the success of numerical analysis, in solving conduction and laminar flow problems, calculations for turbulent and some separated flows still require experimental input for empirical constants and verification. Also one still needs thermodynamic and transport properties of materials for real problems and these unfortunately cannot be calculated accurately from first principles. Thus the need for measurements is clear, and measurements require sensors, data acquisition systems, and readout equipment. The development of better, simpler, and more accurate measurement techniques is the subject of the present section. This relates to experimental methods in heat transfer research and applications. (1) Systems for direct measurement of heat transfer or heat flux; (2) techniques for temperature measurement, local and average, steady and transient; (3) flow measurement and flow visualization systems used in convection heat transfer studies; (4) thermodynamic and thermal transport property measurement; and (5) a number of miscellaneous items. These are the subcategories of the present section. Studies reported in the current year, 2005. 1. Direct measurement of heat transfer has been reported in a variety of conditions from cryogenic to high temperature. These include use of circular heat flow discs, thermistors and quenching systems, as well as comparison and calibration of heat flux sensors. Devices studied include differential scanning calorimeters, improved thin film heat transfer gages, infrared thermography and liquid crystals and other visualization techniques [E1–E21]. 2. Temperature-measuring device studies include new thin film thermocouples, sputtered micro thermocouples, thermo fluorescents, thin-foil thermography and fine wire thermocouples for transient measurement. The effect of incident light on imaging from liquid crystals, and use of absorption spectroscopy have been reported [E22–E35]. 3. Velocity and flow measurement developments include thermal gas law sensors, use of magnetic resonance to determine velocity of freezing droplets, flow velocity measurement techniques, and a thermal sensor used in a bubbly flow. Advances in hot wire anemometry, mass flow sensors, novel flow visualization techniques and a Mems designed thermal shear-stress detector are reported [E36–E48]. 4. Property measurement developments include pulse-heating systems for thermal properties of high temperature materials, improvements in differential scanning calorimeters, conductance measurements in low Reynolds number channel flows, and measurements of thermal diffusivity of powders and thermal properties of natural gas hydrates [E49–E55]. 5. Miscellaneous measurement techniques include a heat transfer measurement determining the gap width of flying heads for optical recording technology, measuring evaporation coefficients, thermographic non-destructive testing, X-ray radiography applied to diffusivity measurements, thermal boundary layer studied with thermo reflectants and development of thermal sensors for studying moving surfaces [E20,E56–E60]. F. Natural convection—internal flows
1. The large number of papers report studies of Rayleigh-Benard convection with a variety of fluids and thermal boundary conditions [F1–F15]. 2. A few papers include particles in the fluid that are composed of phase change materials or are some form of nanoparticles. Studies of heat-generating fluids include a linear stability analysis that
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has been made to study the effects of critical Rayleigh number and wavenumber when internal heat sources are nonuniform [F16– F20]. 3. Other papers report on studies of flows and heat transfer in square, triangular, rectangular cavities and horizontal annuli. A wide variety of thermocapillary flows were studied including the effects of surfactants at the surface, grooved walls, gas diffusion into the liquid, localized heating and magnetic effects [F21–F31]. 4. Bubbles, droplets and half-zone liquid bridges were also investigated. As in previous years, a large number of papers appeared on cavities including square, cubic or rectangular geometries [F31– F64]. 5. Numerous boundary conditions, time varying conditions and internal partitions are considered. Other geometries include inclined rectangular, cylindrical and partially open cavities. Several papers consider flows in vertical channels with various thermal boundary conditions and fluid conditions [F65–F78]. 6. Channels filled with porous media are also studied as are the channels with unheated chimneys and extensions and flows in vertical cylinders and annuli. Numerical solution methods are the predominant solution method for the study of natural convection within vertical cylinders and cylindrical annuli, elliptic cylinders and annuli and horizontal cylindrical and spherical annuli [F30,F76,F79–F95]. 7. A few studies on mixed convection were reported including air flows in spent fuel storage facilities, shallow enclosures with internal heating and cavities with pulsating resistive heating [F96– F101]. 8. Complex geometries include a vertical plate enclosed within a horizontal cylinder, assemblies of blocks and cylinders, and heat exchangers immersed in liquid thermal storage tanks [F102–F105]. 9. Ref. [F106]. 10. Papers on double diffusive convection include a study of hydromagnetic convection in a radiatively participating medium and the role of chemical boundary layers in ocean circulation [F107,F108]. 11. Some interesting observations were made on turbulent natural convection research and work was reported on liquid-encapsulated molten semiconductors [F109–F112]. FF. Natural convection—external flows
1. Vertical, horizontal and inclined plates A significant number of papers reported studies of natural convection from vertical flat plates including methods to model turbulent flow, the effects of micropolar fluids, porous media, wavy surfaces and double diffusive flows [FF1–FF11]. 2. Channels, fin arrays and electronic cooling The driving force behind many of the publications on channel flow is the optimal cooling of electronic equipment [FF12–FF24]. Options include channel construction, fin design and localized heat sources.
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5. Mixed convection Most of the studies on mixed convection use the vertical flat plate geometry but vary the nature of the heat source and the direction of the forced flow [FF35–FF40]. 6. MiscellaneousAdditional investigations include an improved heat transfer correlation for natural convection, heat transfer from horizontal and vertical helical coils, mixed convection from a square cylinder in channel flow, heat and mass fluxes across density-stratified interfaces [FF41–FF44].
G. Convection from rotating surfaces
1. Rotating disks Heat transfer, convective instabilities from rotating disks were studied [G1–G5]. Thermal-fluid flow between stationary and rotating parallel disks was also analyzed [G6–G8]. 2. Rotating channels Effectiveness of latticework coolant blade passages under rotation was investigated [G9]. Heat transfer in rotating rectangular and square channels/ducts were studied [G10–G18]. Convective flow in a rotating fluid over a vertical plate was studied [G19]. Impingement cooling in a rotating passage of semi-cylindrical cross-section was studied [G20]. 3. Enclosures Thermal effects in planetary mixer and rotor-stator systems were studied [G21,G22]. Numerical studies of fluid and heat flow in rotating annulus were performed [G23–G26]. Other studies involved transient heat transfer on a moving surface in a rotating fluid [G27], rotating bodies with heat generation [G28,G29] and evaporation of volatile droplets in vacuum of rotating blanks [G30]. 4. Cylinders, spheres and bodies of revolution Thermal transport involving other bodies of revolution includes spherical shells [G31], spinning spheres [G32,G33] and cylinders [G34]. Some general studies involving rotating systems include Kuppers–Lortz instability in rotating Rayleigh–Benard convection [G35], simulation of convection motion in Earth’s outer core [G36] and the development of finite-element schemes for steady convective heat transfer with system rotation [G37].
H. Combined heat and mass transfer
We divide the section into 7 subcategories covering different topics. 1. Ablation This includes mass transfer through aerodynamic heating and mass-transfer in multi-component materials [H1,H2]. 2. Transpiration This includes heat and mass transfer in porous materials, desalination, and the effect of material coatings on both heat and mass transfer [H3–H13].
3. Bodies of revolution Single horizontal cylinders, arrays of cylinders, spheres and horizontal disks were studied [FF25–FF30].
3. Film cooling This section includes two-phase flow, determination of heat transfer coefficients under a variety of flow conditions, and the effect of surface conditions and geometry/configuration on heat and mass transfer [H14–H30].
4. Buoyant plumes Studies of thermal plumes include experimental investigations using a PIV technique and the effect of a lateral cylinder on the plume rising from a disk [FF31–FF34].
4. Jet impingement—submerged jets This section includes the use of liquid crystal techniques, modeling of jets, and flames, in various configurations, to describe the heat and mass-transfer from flat and curved objects [H31–H84].
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5. Jet impingement—liquid jets This section includes the use of liquid jets, various diameters and configurations, including the modeling of heat transfer in incompressible flows as they impinge on solid surfaces [H85–H90]. 6. Sprays This section includes droplet dynamics, the enhancement of heat transfer during droplet impingement and vaporization, and the effects of nozzle configuration during multi-phase transport [H91–H104]. 7. Drying This section includes the modeling of heat and mass transfer in porous materials, including biomass and foodstuff, microwaves and radio-frequency assisted drying, and the effects of fluid dynamics and turbulence on drying [H56,H105–H124]. 8. Modeling and simulation This includes analytical and numerical modeling, direct simulation, and device-level simulation of heat and mass transfer [H125– H171]. I. Bioheat transfer
The present review includes only a small portion of the overall literature in this area. This represents work predominantly in engineering journals with the occasional inclusion of basic science and biomedical journals. This is a very dynamic and cross disciplinary area of research, and thus, this review should be taken as more of an overview, particularly from an engineering point of view, rather than an exhaustive list of all work in this area for this year. Subsections include work in (1) biopreservation, (2) thermal therapies, (3) thermoregulation (thermal comfort and physiology), (4) thermal measurement, modeling and properties, (5) food technology and (6) general/miscellaneous areas. 1. Biopreservation This sub-section includes an article addressing cryopreservation of a bioartificial liver device [I1]. 2. Thermal therapies This includes articles related to cryosurgery, laser, high intensity focused ultrasound, radiofrequency and microwave [I2–I20]. 3. Thermoregulation Work in this sub-topic comprised of areas including thermal comfort and physiological assessments of thermoregulation [I21– I28]. 4. Thermal measurement, modeling and properties This section lists papers related to heat transfer propagation and enhancement in biological media. A few numerical studies were conducted to study the 3D bioheat transfer problem. Analytical studies of heat transfer in blood vessels were conducted [I29– I38]. 5. Food technology Papers related to food technology include study of various process technologies like drying and thawing analysis, [I39–I42]. 6. General studies in the area of bioheat transfer are listed here These include cooling of biocrystals, thermal isolation techniques and heat flow in proteins [I43–I45]. J. Change of phase—boiling and evaporation
Papers on boiling change of phase for 2005 have been categorized as follows: those that focus on droplet and film evaporation, boiling incipience and effects of bubble dynamics, pool boiling, film
and transition boiling, flow or forced convection boiling, and twophase thermohydrodynamic effects. 1. Droplet and film evaporation These papers focus on evaporation of droplets, films, and interfaces. Many of them address evaporators for refrigeration or evaporation of falling films (laminar, turbulent, or transitional; steady or pulsatile) and evaporation of drops, sprays, or mist. Many relate to evaporation in mini- and micro-channels, some for other duct shapes. Fluid types are refrigerants, including hydrocarbon refrigerants, aqueous foam-forming solutions, and moisture in foods. Some discuss surface geometry effects such as micro-porous coatings or micro-fins. Some deal with interface characteristics such as contact angle (including surface tension flow instability) effects. Some look at external influences such as electric fields. Various measurement and modeling techniques for evaporative processes are presented [J1–J30]. 2. Boiling incipience and effects of bubble dynamics In an attempt to characterize boiling better, many of the papers specifically address the effects of bubble dynamics, including nucleation (heterogeneous or homogeneous), initial growth, interactions with neighboring bubbles, and subsequent coalescence. Some discuss surface tension-driven motion or bubble sliding motion effects. Many discuss surface geometry effects such as artificial cavities or porous coatings – one with titanium dioxide displays contact angle sensitivity to UV light. Geometric settings include wires, microchannels, narrow annular ducts, superheated liquid drops, and plates at various orientations. The effects of additives, such as nanoparticles or aqueous polymers and other surfactant solutions, are addressed. Some are with binary mixtures. Many papers specifically address surface wetting or contact angle (including dynamic contact angle) effects. Some show surface energy change effects by changing fluid types. Some discuss microscopic processes, such as jetting near bubbles, micro-bubble emission, ‘‘explosive boiling,” or bubble lift-off events while some studies track paths of single bubbles after nucleation or present bubble departure diameters and frequencies. Others discuss external influences such as transient heating or microgravity. Techniques for enhanced nucleation and reduction of nucleation hysteresis are discussed and methods for modeling (like bubble tracking) and experimentation are presented [J31–J61]. 3. Pool boiling Nucleate pool boiling and critical heat flux in pool boiling are addressed in this section. Incipience, transition boiling, or film boiling papers have been put into other sections. Many papers discuss performance with various fluids, such as refrigerants, liquid metals, fuels, lubricants, electrolytes, acids, carbon dioxide, or fluids with additives like surfactants and nanoparticles. Various macro-scale geometries, such as annuli of various geometries, small-size heaters, downward facing hemispheres, flat surfaces at various orientations, cylinders and bundles of cylinders, and microchannels or narrow gaps between plates are discussed. Some discuss smallscale geometric features, such as reentrant cavities or micro-porous coated surfaces, micro-pin-fins, and junctions between fins. Some address boundary condition effects, such as spatial variations in applied heat flux, or external influences such as magnetic, and low-gravity, or micro-gravity fields. Many of the papers present modeling concepts (such as a neural network modeling) or experimental techniques [J56,J62–J96]. 4. Film boiling Film boiling papers in this section address either pool or forced convection boiling. They apply to internal or external films on smooth or prepared surfaces that are flat, downward-facing hemispheres, tubes, or spacers. Some discuss various fluid types, such as
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Helium II; surface characteristics, such as various metals or oxide layers; or external influences, such as radiation induced surface activation. Some focus on transient effects, such as film growth rate or dry patch dynamics due to instabilities. Several of the film boiling papers present modeling ideas and some present experimental methods. Several papers in this section discuss transition boiling, the portion of the boiling curve between nucleate boiling and film boiling [J97–J103]. 5. Flow boiling There were numerous papers in the 2005 review on flow boiling. Forced convection was through straight, single and parallel channels (including narrow channels, gaps, mini-tubes, microchannels, tubes with porous material or twisted tapes within), over tubes or tube bundles, or with impinging jets. Micro-channel studies dominated this category. Many papers discussed boiling performance with various fluids, such as hydrocarbons, high-viscosity fluids, binary mixtures, carbon-dioxide; various refrigerants and refrigerant mixtures; various solutions with surfactants and salts; and fluid mixtures. Some discussed surface feature effects such as re-entrant cavities and micro-fins of various designs. Some addressed external influences such as periodic flow rates, bubble-induced motion, microgravity, orientation with respect to the gravity vector, or magnetic or electric fields. Many discussed modeling (such as the population balance approach or a homogeneous turbulence model) and others discussed experimental techniques (such as liquid crystal thermography) [J104–J151]. 6. Two-phase thermohydrodynamic effects Emphasis in this section was on hydrodynamic effects during boiling. Some papers dealt with flow boiling, tying behavior to two-phase flow regimes and others dealt with pool boiling vapor removal patterns. Some addressed flashing flow. Many addressed modeling and tied model formulation to the flow regime. Some of the hydrodynamic effects studied were tied to channel geometry. Papers on boiling in micro-channels and parallel micro-channels were particularly common. Some papers addressed external effects such as reduced gravity or electric fields. Many of the papers addressed unsteady or unstable effects tied to thermohydrodynamics, such as flow through parallel channels which may display periodic wetting and dryout, and ‘‘explosive boiling.” Much of the work in this section was supported with high-speed photographs [J152–J168].
JJ. Change of phase—condensation
Papers on condensation are categorized into those dealing with the analysis and modeling of all aspects of condensation heat transfer, surface modifications to enhance heat transfer, experimental and analytical papers dealing with global geometrical modifications, and the heat transfer behavior of condensing mixtures. 1. Modeling and analysis Analytical work on condensation in 2004 includes research on linear stability of a condensate film acted on by gravity and vapor shear [JJ1], condensation of refrigerants in micro-fin tubes [JJ2], circular and non-circular microchannels [JJ3,JJ4], turbulent condensation on horizontal and inclined elliptical tubes [JJ5,JJ6], tubes with variable wall temperature [JJ7], models for condensation in a vertical tube with non-condensables [JJ8,JJ9], and comparison of the performance of various models in predicting the effects of noncondensables [JJ10]. Interface location in direct contact condensation was predicted numerically [JJ11], while the effects of largescale surges of condensate leaving flow systems and associated system response in heat exchangers were studied using a void fraction model [JJ12].
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2. Global geometry Studies addressed steam and steam–air condensation on banks of integral-fin tubes [JJ13], R-134a vapor and ethylene glycol condensing on integral-fin tubes [JJ14,JJ15], and refrigerants condensing inside micro-fin tubes [JJ16–JJ20], spiraled micro-fin tubes [JJ6], circular, rectangular and multiport minichannels [JJ21–JJ23]. Turbulent condensation on an isothermal sphere [JJ24] was analyzed using the Colburn analogy. Condensation in nozzles [JJ25] and transonic flows [JJ26,JJ27] was studied numerically. Steady and transient behavior of in-tube condensation of steam–air mixtures was examined in order to understand loss-of-coolant situations in nuclear reactors [JJ28]. Other work examined re-condensation in non-adiabatic capillary tubes [JJ29], direct contact condensation of steam in water [JJ30], reflux condensation of steam-air mixtures in a vertical tube [JJ31], and the effects of flooding on the condensation heat transfer performance of tube banks [JJ32,JJ33]. 3. Surface effects Papers in this category documented the heat transfer behavior of steam, R113 and ethylene glycol condensing on a wire-wrapped tube [JJ34], dropwise condensation on surfaces covered with selfassembled organic monolayers [JJ35,JJ36] and the effects of small amounts of additives [JJ36]. 4. Mixtures Papers on condensing mixtures covered work on in-tube and external condensation of zeotropic mixtures [JJ37,JJ38], non-azeotropic hydrofluorocarbons condensing on low-fin tubes [JJ39] and Marangoni effects in a ternary vapor mixture of water, ethanol and air [JJ40]. Thome [JJ41] presented a unified flow-pattern based model for predicting local heat transfer coefficients for in-tube condensation of pure fluids, and zeotropic and azeotropic mixtures. JM. Change of phase—freezing and melting
In this section, freezing and melting problems in the literature are reviewed. The problems are broken into various further subdivisions as noted in the subheadings below. 1. Melting and freezing of sphere, cylinders and slabs Topics studied included frost growth on a flat plate [JM1]; phase-change interface in the thawing of frozen food [JM2]; freeze drying of cylindrical porous media [JM3] and melting from a vertical plate [JM4]. 2. Stefan problems, analytical solutions/special solutions An article studied freeze drying problems using a fixed grid method [JM5]. 3. Ice formation/melting A number of articles were published in this area. They include effect of ice density change on the heat transfer coefficient [JM6]; ventilation in ice rinks [JM7]; heat transfer during ice scraping [JM8]; ice melting in cool-thermal discharge systems [JM9,JM10]; de-icing of wings [JM11]; porous media with ice inclusions [JM12]; frost formation [JM13,JM14]; de-frosting of inclined surface [JM15]; freezing and immersion cooling in food systems [JM16–JM18]; ice slurry generation and analysis [JM19,JM20]; ice plate melting [JM21]; freezing in scraped surface eutectic crystallizer [JM22] and ice crystal interactions in thunderstorms [JM23]. Other studies involved MRI investigations of solid fraction during recalescence of freezing drops [JM24] and ice gradients in food dough [JM25]. 4. Melting and melt flows This subsection contains papers related to phase change in moving layer [JM26]; electromagnetic treatment of steel melts
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[JM27]; oxygen refining in ferromanganese melt [JM28]; ion beam ablation [JM29]; Stoke’s problem with melting [JM30]; density variation in free surface melt flows [JM31] and nanosize silica melting [JM32]. 5. Powders, films, emulsions, polymers and particles in a melt Studies include numerical investigation of heat transfer in composite processing [JM33]; melting and solidification in metal powder bed [JM34]; heat transfer in blast furnace [JM35]; and mathematical modeling of a two-layer sintering process [JM36]. 6. Glass technology No articles in this subsection were reported this year. 7. Welding Studies include laser microwelding [JM37]; friction welding [JM38]; and a heat transfer model to obtain a specific weld geometry [JM39]. 8. Energy storage—PCM Heat transfer associated with phase change mater ials formed an active area of research this year. Studies include heat transfer enhancement [JM40,JM41]; thermal insulation and regulation [JM42–JM44]; mathematical models [JM45]; PCMs in finned tubes, ducts and heat sinks [JM46–JM49]; heat transfer during phase change of wax systems [JM50–JM53]; variable wall temperature PCM storage system [JM54]; effect of geometry [JM55]; metal foams [JM56]; solidification in PCM [JM57]; polymer solutions and water as PCM [JM58]; fatty acids in PCM design [JM59]; and thermal conductivity effects on melting in PCM [JM60]. Heat transfer studies in rectangular enclosures [JM61,JM62] and thermocapillary and buoyancy driven flows [JM63] were also studied. 9. Casting, moulding and extrusion Activity in these three areas are broken up below. Casting: Reports in this subsection focused on melt flows [JM64], coupled heat and mass transfer [JM65], temperature control [JM66] and heat transfer improvements [JM67]. Casting effects with aluminum [JM68,JM69] and steel [JM70–JM72] were actively studied. Other studies include water cooling in aluminum and steel casting [JM73], direct chill casting in alloy [JM74], flows in microcasting [JM75], film casting [JM76], hot strip rolling of metals [JM77]; Leidenfrost temperature effects and cooling [JM78], directional solidification in blade like castings [JM79], multi-cavity die casting [JM80], and billet design in continuous casting [JM81]. Moulding: Studies include work on injection moulding tools [JM82], injection moulding [JM83], electromagnetic stirring on mold heat transfer [JM84] and glass bulb mold [JM85]. Extrusion: Heat and mass transfer during a polymer extrusion process was studied [JM86]. 10. Mushy zone—dendritic growth and segregation Papers studied columnar growth in the presence of convection [JM87] and dendritic microstructure during directional solidification in microgravity [JM88]. 11. Solidification Work in this area included an ALE-FEM numerical model [JM89]; composite solidification [JM90]; solidification in horizontal ingots [JM91], tubes [JM92], moulds [JM93,JM94]; solidification control using magneticfields [JM95]; macroscopicmodeling[JM96]; vertical gradient freezing [JM97]; polymer solidification[JM98]; alloy solidification [JM99–JM102]; casting solidification and grain structure analysis [JM103]; thermal processing [JM104] and heat and mass transfer analysis during solidification of a binary solution [JM105]. 12. Crystal growth This subsection discusses heat transfer associated with crystal growth. Materials studied include polymers [JM106]. Mathemati-
cal models were described [JM107–JM109]. Other studies involve eutectic crystallization [JM110]; baffle design for crystal growth [JM111,JM112]; a periodic crystallization model [JM113]; temperature gradient and gravity effects [JM114] and single crystal growth [JM115]. One paper studied the Bridgman–Stockbarger process coupled with a magnetic field [JM116]. 13. Droplets, spray and splat cooling Articles in this section studied liquid metal on cooled moving substrate [JM117], impinging droplets [JM118], spray forming [JM119], droplet freezing in hypersonic melting ablation [JM120]. 14. Oceanic, geological, and astronomical phase change The role of chemical boundary layers in regulating oceanic thermal boundary layers was investigated [JM121].
K. Radiation
Papers on radiation focus on the radiative heat transfer calculations and the influence of geometry, the role of radiation in combustion processes, the effect of participating media, radiation combined with other modes of heat transfer, radiative transfer in microscale systems, and experimental methods to assess radiative transfer and materials properties. The papers here are divided into these subcategories that focus on the different impacts of radiation. Most of the papers report the results of modeling studies. Papers describing the developments of new numerical methods themselves are reviewed in the numerical methods section under the subcategory radiation. 1. Radiative transfer calculations and influence of the geometry Papers in this category focus on view factors [K1,K2], and the modeling of radiative heat transfers in two-dimensional [K3,K4] and three-dimensional systems [K5–K7]. Cylindrical geometries are studied in [K8]. Papers [K9–K13] focus on improved numerical methods for radiative transfer. 2. Participating media In the category of participating media, studies concentrate on the absorptive, emissive, refractive and scattering properties of media. Absorbing/emitting media are investigated in [K14–K23]. Emissivity of real gases is considered [K24]. Spatially non-uniform refraction is considered in [K25–K27]. A significant number of papers concentrate on scattering media [K28–K32]. Scattering is important in systems containing droplets and particles [K33– K37]. General methods for participating media are discussed in [K38–K47]. 3. Radiation and combustion Radiative heat transfer is an important factor in combustion processes and is studied in several papers [K48–K52]. 4. Combined heat transfer Papers in this subcategory consider the combined effect of radiation with conduction and/or convection. A large number of papers consider radiative heat transfer combined with heat conduction [K53–K63]. Radiation combined with convection is treated in [K64–K75]. The combination of all three modes of heat transfer is studied in [K76–K83]. 5. Microscale radiative transfer Studies on microscale radiative heat transfer include radiation in thin films [K84] and through nanoscale apertures [K85]. 6. Intensely irradiated systems Studies in this section investigate the interaction of systems with intense radiation. Laser irradiation is considered in [K86– K88].
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N. Numerical methods
A relatively new capability available to the researchers and practitioners of heat transfer is the ability to simulate physical phenomena on a computer. The simulation of heat transfer, fluid flow, and related processes is achieved via numerical solution of the governing equations. Such computational simulation is now widely used in fundamental research and in industrial applications. New and improved numerical methods are being developed to improve their accuracy, efficiency, and range of applicability. Contributions in the current year are subdivided here into the following categories: (1) Heat conduction—This includes direct and inverse problems in heat conduction, boundary element methods, as well as finite-difference and finite-element methods; (2) Phase change—heat conduction is sometimes accompanied by solid–liquid phase change with the associated complexity; (3) Convection and diffusion—an important aspect of calculating scalar variables (such as temperature and velocity components) in the presence of fluid flow is the proper treatment of convection and diffusion over the whole range of flow rates; (4) Fluid flow—a very large number of heat transfer applications involve fluid flow. Numerical methods need to address the complex task of calculating fluid flow under the conditions of multidimensionality, irregular geometry, compressibility, body forces, and turbulence; (5) Other Studies—This subcategory includes complex industrial applications, non-standard techniques, simulation of radiation, and other studies. Contributions in the current year 2005 1. Heat conduction Studies cover improved techniques for steady and unsteady heat conduction, boundary element methods and inverse problems, and treatment of special boundary conditions [N1–N37]. 2. Phase change Melting/freezing problems in heat conduction are considered [N38–N42].
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laser flash [P8], photoacoustics [P9], 1-x, 2-x and 3-x methods [P26] and Monte Carlo (MC) simulations [P10]. New techniques, setups and models were also developed to estimate thermal conductivity and diffusivity or to extend the applicability of already existing techniques [P19–P22,P25,P27–P30]. In addition, the effects of parameters such as phonon transport and electrical resistivity on thermal conductivity were also studied [P13,P14]. 2. Diffusion Articles under this subsection included an experimental study to determine the diffusion coefficients of frake (wood) under different temperatures [P31] and a discussion on the applicability of the diffusion to model complex and even nondiffusive phenomena [P32]. 3. Heat capacity Studies included determination of heat capacities of various materials [P5,P22,P33,P34] through numerical simulations based on quantum kinetic equation approach [P22] and experimental methods like hot wire parallel technique [P5], temperature modulated calorimetry [P33] and group contribution method [P34]. 1-x, 2-x and 3-x methods for determination of specific heat were also analyzed [P26]. 4. Thermophysical properties Some new techniques and models [P22,P35–P41] to calculate thermophysical parameters such as heat transfer coefficients, temperature jump coefficients and vapor–liquid equilibrium properties of various materials [P37–P39,P42] were developed.
Q. Heat transfer applications—heat exchangers and thermosyphons
The papers in this category relate to heat exchanger theory, operation, fouling, and heat pipes. Like the previous years, a major effort is directed toward the design, modeling, analysis, and correlation of existing data on heat exchangers.
This section deals with the studies undertaken to investigate the behavior of various thermophysical and thermodynamic properties. The following classifications have been made:
1. Heat exchangers Performance studies were conducted using LMTD and NTU methodologies [Q1–Q11]. Several optimization studies were performed [Q12–Q22]. Analytical modeling of heat transfer was conducted using various approaches [Q12–Q17]. The types of heatexchangers studied include shell-and-tube [Q18–Q22], finned-tube [Q23–Q32], plate [Q33–Q39], plate-fin [Q40–Q48], regenerative systems [Q49,Q50], multi-tube (concentric) [Q51–Q58], polymeric [Q59–Q63], spiral coils [Q64–Q66], rotating system [Q67], fallingbed [Q68] and fluidized heat exchangers [Q69]. Some novel studies include development of fractal exchangers [Q70], fibrous total exchangers (THXs) [Q71], ceramic exchangers [Q72,Q73], ring channel exchangers [Q74], thermoacoustic systems [Q75–Q77] and assessment of condensate damage [Q78]. Other studies involved direct contact exchangers [Q79,Q80], cooling-towers [Q8,Q9,Q15,Q81–Q87] and aircraft air-conditioning systems [Q88,Q89]. General heat transfer studies involved coupling of a heat-exchanger with a household furnace [Q90], correlation between flow and temperature heterogeneities in a scaled model of an industrial exchanger [Q91] and modeling of a mantle exchanger [Q92].
1. Thermal conductivity, diffusivity and effusivity Thermal conductivity and diffusivity investigations drew a lot of attention. Some well established experimental and numerical techniques were used to estimate the thermal conductivity and diffusivity for a wide variety of materials [P1–P24]. These methods are Transient Plane Source (TPS) [P1], pulsed and thermal quadruples [P2], electrical resistance thermometry [P3], transient and parallel hot wire techniques [P4–P6,P25], infrared thermography [P7],
2. Heat transfer enhancement A variety of approaches have been explored to enhance heat transfer. These include vortex generators [Q58,Q93], louvered fins [Q94,Q95], microchannels [Q96,Q97], thermoelectric coolers [Q98,Q99], pin elements [Q100], winglets [Q101], EHD [Q102], surface coatings [Q103] and nanofluids [Q104,Q105]. Heat transfer enhancement in a spray evaporator has been discussed [Q106].
3. Convection and diffusion The use of streamline upwind techniques is studied in the context of conjugate heat transfer [N43,N44]. 4. Fluid flow The studies in this subcategory include improvements in flowcalculation techniques, turbulence models, and multi-phase flows [N45–N91]. 5. Other studies These include a variety of applications involving microwave radiation, MEMS structures, pulse-tube refrigerator, meshless methods, furnaces, and fires [N92–N122]. P. Properties
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3. Fouling Fouling of heat exchangers can significantly hinder the performance of a plant and its elements. Efforts continue to understand, prevent or mitigate the phenomenon. Articles related to fouling involve modeling [Q107–Q113], control/mitigation [Q114–Q119] and performance studies [Q120]. 4. Thermosyphons (heat pipes) In this sub-section, design, modeling and analysis of a number of heat-pipe applications are included. Thermal performance of various wick materials [Q121,Q122] and working fluids [Q123– Q125] have been analyzed. Special types of heat pipes which have been studied include loop heat pipes (LHPs) [Q126–Q132], pulsating heat pipes [Q132–Q137], sorption heat pipes [Q132,Q138] and annular heat pipes [Q139]. Several design studies for heat pipes have been conducted [Q140–Q143]. A few analytical models [Q144–Q149] and CFD simulations [Q150,Q151] have been discussed. Performance studies of various thermosyphons have been conducted [Q80,Q152–Q160]. S. Heat transfer applications—general
This section includes the articles related to heat transfer studies in general applications, which include nuclear reactors, buildings, thermodynamic cycles, electronics cooling, manufacturing, fuel cells and gas-turbines. This year’s summary is divided into the following subcategories. 1. Nuclear reactors This topic includes papers related to heat transfer in reactor vessels [S1–S3], and fuel rod elements [S4–S8]. Thermal-hydraulic characteristics of an encapsulated nuclear heat source were analyzed [S9]. Heat transfer in research and breeder reactors were studied [S7,S10–S13]. Heat and fission product transport in a molten core material pool was studied [S14]. 2. Buildings Determination of wall surface temperatures and heat transfer coefficients in buildings were studied [S15,S16]. Other types of studies include building envelopes [S17–S20], moisture control [S21], cooling systems [S22–S27], thermal bridges [S28], outdoor environments [S29,S30] and air distribution systems [S31,S32]. 3. Refrigeration This topic includes papers related to thermodynamic refrigeration cycles [S33–S38], sorption cooling systems [S39–S54], and thermoelectric cooling [S55,S56]. Heat transfer in air-conditioning systems [S57] and distillation systems were studied [S58]. Some general heat transfer concepts in refrigeration were also covered [S59–S65]. 4. Heat engines This topic includes articles related to thermodynamic heatengine cycles [S66–S77], performance (power/efficiency) studies [S78–S80], thermoacoustic engines [S81], reciprocating engines [S82], engine combustion [S83,S84] and knock detection [S85]. 5. Heat pumps Articles in this subcategory relate to heat-pumps. Several performance based studies were conducted [S86,S87]. Sorption heatpump cycle models were analyzed [S88,S89]. Thermodynamic characteristics of heat pump cycles were studied [S90–S93]. 6. Electronic packaging Articles in this section can be broadly subdivided into air-cooled and liquid-cooled systems. Forced convection air-cooled studies include wavy-plates [S94], heat sinks [S95,S96], and microjets [S97]. Various liquid-cooled systems were studied [S98–S103].
Some CFD modeling studies were conducted [S104–S107]. Other packaging studies involve heat spreader structures [S108], coldplates [S109], heat pipes [S110–S115], fins [S116–S118], phasechange materials [S119], 3D packaging [S120], closed-loop refrigeration systems [S121–S123] and graphite foams [S124]. Miscellaneous studies in this subcategory include cellular phone thermal management [S125], LEDs [S126], computer chassis [S127] and underground electronics shelters [S128]. Next generation devices for electronics cooling were proposed [S129,S130]. 7. Geophysics This section contains papers related to heat and moisture transport in geophysical entities. These include radiometric and infrared measurements [S131,S132], ground (soil, rock) systems [S133– S142], water surfaces (seas, oceans) [S131,S143], geological storage reservoirs [S144], and snow [S145]. 8. Manufacturing and processing This section contains papers which studied heat transfer in a wide variety of manufacturing processes, which include casting [S146–S156], annealing [S157], welding [S158,S159], machining [S160–S164]. Some other manufacturing processes which were studied include glass-bending [S165], drawing [S166], hot-rolling [S167,S168], cold-rolling [S169], laser heating [S170–S173], chemical vapor deposition (CVD) [S174], calendering [S175], creep-feed grinding [S176], hot-metal coiling [S177], lithography [S178,S179] and paper-machines [S180]. Heat transfer in furnaces and catalytic processes was analyzed [S181–S188]. Cooling-down processes were studied [S189–S194]. Several numerical studies in heat processing were conducted [S195–S197]. Thermal behavior of coatings and composites were studied [S198–S202]. 9. Food processing Control of process parameters during thermal treatments of food was studied [S203,S204]. Transport phenomena in food engineering was studied [S205–S207]. Thermal treatment of various food products was studied [S208–S215]. Cooling systems for food cabinets were described [S216]. 10. Fuel cells Heat transfer studies related to fuel cells include polymer electrolyte membrane fuel cells (PEMFC) [S217–S222], solid oxide fuel cells (SOFC) [S223,S224], and direct methanol fuel cells (DMFC) [S225]. Thermal management issues in fuel cells were also addressed [S226]. 11. Nano-systems Nano-scale heat transport in solids was simulated [S227–S230]. Thermal management using nanofluids was studied [S231,S232]. 12. Gas-turbines Velocity and heat transfer measurements were conducted in transonic cascades [S233,S234]. Various computational simulations were performed [S235–S238]. Other studies include fuselage temperature distribution [S239], flow structures [S240], tip leakage [S241], blade cooling [S242–S246], design issues (delta-winglets) [S247]. Waste heat recovery in a gas turbine system was studied [S248]. 13. Energy storage Several energy storage units were studied [S22,S249–S253]. 14. Miscellaneous This section contains general topics in heat transfer which do not fit in any of the above categories. These include supersonic nozzles [S254], regenerative wheels [S255], combustion [S256– S259], cryogenic fluids [S260], superfluids [S261], space systems [S254,S262], automobile units [S263–S266], CO2 heat transfer [S267], reinforced and composite materials [S268–S271], firing of
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reactive walls [S272], phase-change materials [S273], ultrasonic waves [S274], corrosion [S275], electric machines [S276], biocrystals [S277] and thermoelectric generators [S278]. T. Solar energy
Heat transfer studies in the field of solar energy address a broad range of topics covering a variety of applications for buildings to power plants. Papers are broadly divided into solar radiation fundamentals and measurement, low-temperature applications, high-temperature applications, building components, and storage technologies. Papers on solar energy that do not focus on heat transfer, for example, papers on photovoltaics (except for those that deal with combined thermal systems), wind energy, architectural aspects of buildings, and control of space heating or cooling systems are not included. Subcategories are summarized below. 1. Measurements and models of solar radiation Most papers in this category present modeling approaches to simulate, evaluate or use measured solar data [T1,T2]. Instrumentation is presented in [T3]. 2. Low temperature applications Low temperature solar applications include solar water and residential space heating [T4–T18], space cooling [T19–T21], desalination [T22–T27], water pumping [T28], cooking [T29], and agricultural (greenhouse) applications [T30–T32]. Papers on flat plate and low concentration solar collectors include heat transfer modeling and experiments of innovative concepts to improve efficiency [T33–T49]. 3. High temperature applications The majority of papers this area use concentrated solar thermal energy developed in parabolic trough, parabolic dish and heliostat fields combined with a central receiver to drive endothermic chemical reactions or power systems. Heat transfer investigations in encompass thermal design and analysis of heat transfer and chemical conversion in solar thermo-chemical reactors [T50– T54], electric power systems using volumetric receivers and linear absorbers [T55,T56], and a solar chimney [T57]. Temperature and radiative measurement techniques in concentrating systems are addressed in [T58]. Other papers consider heat sinks for high flux photovoltaic concentrators [T59] and thermal analysis of a co-generation biomass plant [T60]. 4. Building components This section is restricted to modeling and measurement of heat transfer and moisture transport in building components [T61– T66], and building integrated solar thermal and PV collectors [T67,T68] as well building energy use models and data [T69–T71]. 5. Storage Papers in this section address both capacity and power of a variety of storage media and storage devices for low and high temperature solar thermal applications. Thermal processes during charging and discharge of phase change materials [T72–T74]. Other efforts for low temperature storage consider longer term storage in-ground water storage [T75]. Papers on conventional sensible heat storage in water tanks are included in low temperature applications. Study of high temperature storage considers thermocline filler materials and molten salt [T76]. U. Plasma heat transfer and MHD
This chapter includes the characterization of discharge plasmas through modeling and diagnostics of the fluid flow and heat transfer in a variety of plasma generating devices. These characteriza-
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tions address the fundamental interactions of plasmas with solids (heat and momentum transfer), as well as the description of specific plasma processes. Because of the multitude of physical effects and the strong non-linearity of any such process, a continuous improvement in the descriptions is seen on the removal of simplifying assumptions and by becoming more and more realistic. This holds for the modeling description and for the experimental process characterization. The MHD section is usually devoted to description of different modeling approaches for heat and mass transfer in the presence of electric and magnetic fields with electrically conducting fluids. Different geometries, different fluid properties and different accelerating forces are considered. This year’s summary is divided into the following sub-sections. 1. Modeling of plasma properties, plasma generating devices, and specific plasma processes This includes determination of plasma transport properties [U1], simulation of plasma jets in different flow regimes [U2,U3], and plasma generating devices for different applications [U4–U7]. 2. Fundamentals of plasma—solid interaction This topic includes electrode effects [U8], surface heating [U9,U10] and plasma particle interaction [U11]. 3. Plasma process characterization This section includes characterization of the plasma spray process including the characterization of the coatings [U12–U15], the welding process [U16–U19] and of discharges as encountered in electric discharge machining [U20–U22]. 4. Magneto hydro dynamics (MHD) This section contains a number of modeling approach descriptions for heat and mass transfer with non-Newtonian fluids [U23–U27], for different geometries and fluid properties [U28– U35], and for different accelerating forces, e.g. flow inside porous media, with free convection or with suction or mass addition through porous boundaries [U36–U43]. References [A1] V.Y. Gubarev, Y.V. Shatskikh, Heat transfer between a gas-droplet medium and a high-temperature surface, High Temperature 43 (5) (2005) 775–780. [A2] Y. Heichal, S. Chandra, Predicting thermal contact resistance between molten metal droplets and a solid surface, Journal of Heat Transfer 127 (11) (2005) 1269–1275. [A3] L. Afferrante, M. Ciavarella, Separated steady state solutions for two thermoelastic half-planes in contact with out-of-plane sliding, Journal of the Mechanics and Physics of Solids 53 (7) (2005) 1449–1475. [A4] J.F. Lin et al., Thermal analysis of the transient temperatures arising at the contact spots of two sliding surfaces, Journal of Tribology 127 (4) (2005) 694–704. [A5] S.Y. Mesnyankin, Modern approach to the account of contact thermal resistances in power plants, Heat Transfer Research 36 (8) (2005) 703–711. [A6] J.F. Zhao, A.L. Wang, C.X. Yang, Prediction of thermal contact conductance based on the statistics of the roughness profile characteristics, International Journal of Heat and Mass Transfer 48 (5) (2005) 974–985. [A7] K.R. Naqvi, S. Waldenstrom, Brownian motion description of heat conduction by phonons, Physical Review Letters 95 (6) (2005) 1–4. [A8] Y.M. Ali, L.C. Zhang, Relativistic heat conduction, International Journal of Heat and Mass Transfer 48 (12) (2005) 2397–2406. [A9] C.O. Horgan, R. Quintanilla, Spatial behaviour of solutions of the dual-phaselag heat equation, Mathematical Methods in the Applied Sciences 28 (1) (2005) 43–57. [A10] F. Jiang, A.C.M. Sousa, Analytical solution for hyperbolic heat conduction in a hollow sphere, Journal of Thermophysics and Heat Transfer 19 (4) (2005) 595–598. [A11] A. Saidane et al., A transmission line matrix (TLM) study of hyperbolic heat conduction in biological materials, Journal of Food Engineering 68 (4) (2005) 491–496. [A12] C.S. Tsai, Y.C. Lin, C.I. Hung, A study on the non-Fourier effects in spherical media due to sudden temperature changes on the surfaces, Heat and Mass Transfer/Waerme- und Stoffuebertragung 41 (8) (2005) 709–716. [A13] M. Xu, L. Wang, Dual-phase-lagging heat conduction based on Boltzmann transport equation, International Journal of Heat and Mass Transfer 48 (25– 26) (2005) 5616–5624.
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[A14] C.Y. Yang, Direct and inverse solutions of hyperbolic heat conduction problems, Journal of Thermophysics and Heat Transfer 19 (2) (2005) 217– 225. [A15] G. Domingues et al., Heat transfer between two nanoparticles through near field interaction, Physical Review Letters 94 (8) (2005). [A16] R. Prasher, Thermal boundary resistance of nanocomposites, International Journal of Heat and Mass Transfer 48 (23–24) (2005) 4942–4952. [A17] X.S. Yang, Modelling heat transfer of carbon nanotubes, Modelling and Simulation in Materials Science and Engineering 13 (6) (2005) 893–902. [A18] S.V.J. Narumanchi, J.Y. Murthy, C.H. Amon, Comparison of different phonon transport models for predicting heat conduction in silicon-on-insulator transistors, Journal of Heat Transfer 127 (7) (2005) 713–723. [A19] R. 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