Skip to main content Accessibility help

We use cookies to distinguish you from other users and to provide you with a better experience on our websites. Close this message to accept cookies or find out how to manage your cookie settings.

Close cookie message
×
  1. Home
  2. Books
  3. Convective Heat and Mass Transfer
  • This book is no longer available to purchase from Cambridge Core
  • Cited by 46
Publisher:
Cambridge University Press
Online publication date:
June 2012
Print publication year:
2011
Online ISBN:
9780511800603
DOI:
https://doi.org/10.1017/CBO9780511800603
Subjects:
Engineering, Chemical Engineering, Thermal-Fluids Engineering
Information

Book description

This book was developed during Professor Ghiaasiaan's twelve years of teaching a graduate-level course on convection heat and mass transfer. It is ideal for a graduate course covering the theory and practice of convection heat and mass transfer. The book treats well-established theory and practice but is also enriched by its coverage of modern areas such as flow in microchannels, computational fluid dynamics-based design and analysis methods. It is primarily concerned with convection heat transfer, with the essentials of mass transfer also covered. The mass transfer material and problems are presented in such a way that they can be skipped if not required. The book is richly enhanced by examples and end-of-chapter exercises. A complete solutions manual is available to qualified instructors. The book includes eighteen appendices providing compilations of most essential property and mathematical information for analysis of convective heat and mass transfer processes.

Reviews

‘Throughout the whole book, the author has made large pedagogical efforts in order to help the reader who tries to assimilate the different notions which are presented. The book will be useful for students who want to be acquainted with the thermodynamics of fluid flows and to researchers who will find here a complete survey of this science.'

Alain Brillard Source: Zentralblatt MATH

'Intended primarily as a graduate-level text, this book strikes a balance between presenting the theory and practice of convective heat and mass transfer, and … flow in microchannels and CFD-based design analysis methods.'

Source: CEP

Refine List

Actions for selected content:

Select all | Deselect all
  • View selected items
  • Export citations
  • Download PDF (zip)
  • Save to Kindle
  • Save to Dropbox
  • Save to Google Drive

Save Search

You can save your searches here and later view and run them again in "My saved searches".

Please provide a title, maximum of 40 characters.
Cancel
×

Contents

Page 2 of 2

Contents

Page 2 of 2

References
References
Adams, T.M., Abdel-Khalik, S.I., Jeter, S.M., and Qureshi, Z.H. (1997). An experimental investigation of single-phase forced convection in microchannels. Int. J. Heat Mass Transfer 41, 851–857.
Adams, T.M., Ghiaasiaan, S.M., and Abdel-Khalik, S.I. (1999). Enhancement of liquid forced convection heat transfer in microchannels due to the release of dissolved noncondensables. Int. J. Heat Mass Transfer 42, 3563–3573.
Aggarwal, A. and Gangal, M.K. (1975). Laminar flow development in triangular ducts. Trans. Can. Soc. Mech. Eng. 3, 231–233.
Al-Arabi, M. (1982). Turbulent heat transfer in the entrance region of a tube. Heat Transfer Engineering 3, 76–83.
Aparecido, J.B. and Cotta, R.M. (1990). Thermally developing laminar flow inside rectangular ducts. Int. J. Heat Mass Transfer 33, 341–347.
Arkilic, E.B., Schmidt, M.A., and Breuer, K.S. (1997). Gaseous slip flow in long microchannels. J. MEMS 6, 167–178.
Arnold, J.N., Catton, I., and Edwards, D.K. (1976). Experimental investigation of natural convection in inclined rectangular regions of differing aspect ratios. J. Heat Transfer 98, 67–71.
Asako, Y., Pi, T., Turner, S., and Faghri, M. (2003). Effect of compressibility on gaseous flows in micro-channels. Int. J. Heat Mass Transfer 46, 3041–3050.
Aung, W. (1987). Mixed convection in external flow. In Kakac, S., Shah, R.K., and Aung, W., eds., Handbook of Single-Phase Convective Heat Transfer, Chap. 15, Wiley.
Awad, M.M. (2010). Heat transfer for laminar thermally developing flow in parallel-plates using the assymptotic method. Third Thermal Issues in Emerging Technologies (THETA 3) Conf., Cairo, Egypt, Dec. 19–22.
Aydin, O. and Avci, M. (2006). Analysis of micro-Graetz problem in a microtube. Nanoscale Microscale Thermophys. Eng. 10, 345–358.
Aziz, A. (1987). Perturbation methods. In Minkowycz, W.J., Sparrow, E.M., Schneider, G.E., and Pletcher, R.H., eds., Handbook of Numerical Heat Transfer, Chap. 15, Wiley.
Aziz, A. and Na, T.Y. (1984). Perturbation Methods in Heat Transfer, Hemisphere, New York.
Badr, H.M. (1983). A theoretical study of laminar mixed convection from a horizontal cylinder in a cross stream. Int. J. Heat Mass Transfer 26, 639–653.
Badr, H.M. (1984). Laminar combined convection from a horizontal cylinder – Parallel and contra flow regimes. Int. J. Heat Mass Transfer 27, 15–27.
Bar-Cohen, A. and Rohsenow, W.M. (1984). Thermally optimum spacing of vertical, natural convection cooled, parallel plates. J. Heat Transfer 106, 116–123.
Barron, R.F. (1999). Cryogenic Heat Transfer, Taylor & Francis.
Barron, R.F., Wang, X., Ameel, T.A., and Warrington, R.O. (1997). The Graetz problem extended to slip-flow. Int. J. Heat Mass Transfer 40, 1817–1823.
Batchelor, G.K. (1970). Theory of Homogeneous Turbulence, Cambridge University Press.
Bayraktar, T. and Pidugu, S.B. (2006). Characterization of liquid flows in microfluidic systems. Int. J. Heat Mass Transfer 49, 815–824.
Bayazitoglu, Y. and Ozisik, N. (1980). On the solution of Graetz type problem with axial conduction. Int. J. Heat Mass Transfer 23, 1399–1402.
Beavers, G.S., Sparrow, E.M., and Magnuson, R.A. (1970). Experiments on the breakdown of laminar flow in a parallel-plate channel. Int. J. Heat Mass Transfer 13, 809–815.
Beavers, G.S., Sparrow, E.M., and Lloyd, J.R. (1971). Low Reynolds number flow in large aspect ratio rectangular ducts. J. Basic Eng. 93, 296–299.
Bejan, A. (1993). Heat Transfer, John Wiley and Sons.
Bejan, A. (2004). Convection Heat Transfer, 3rd ed., Wiley.
Beskok, A. and Karniadakis, G.E. (1999). A model for flow in channels, pipes and duct in micro scale. Microscale Thermophys. Eng. 3, 43–77.
Bhatti, M.S. and Shah, R.K. (1987). Turbulent and transition flow convective heat transfer in ducts. In Kacac, S., Shah, R.S., and Aung, W., eds., Handbook of Single-Phase Convective Heat Transfer, Chap. 4, Wiley.
Bird, G.S. (1994). Molecular Gas Dynamics and the Direct Simulation of Gas Flows, Clarendon.
Bird, R.B., Stewart, W.E., and Lightfoot, E.N. (2002). Transport Phenomena, 2nd ed., Wiley.
Blasius, H. (1908). Grenzschichten in flussigkeiten mit kleiner reibug. Z. Math. Phys. 56, 1–37. (English translation in NACA TM 1256.)
Blasius, H. (1913). Das ähnlichkeitsgesetz bei reibungsvorgängeng in flüsigkeiten. Forschg. Arb. Ing.-Wes., No. 131, Berlin.
Blazek, J. (2005). Computational Fluid Dynamics: Principles and Applications, 2nd ed., Elsevier.
Boelter, L.M.K., Young, G., and Iverson, H.W. (1948). An investigation of air heaters XXXVII – Distribution of heat transfer rate in the entrance section of a circular tube. NACA TM 1451.
Bose, F., Ghiaasiaan, S.M., and Heindel, T.J. (1997). Hydrodynamics of dispersed liquid droplets in agitated synthetic fibrous slurries. Ind. Eng. Chem. Res. 36, 5028–5039.
Brown, G.M. (1960). Heat or mass transfer in a fluid in laminar flow in a circular or flat conduit. AIChE J. 6, 179–183.
Buhr, H.O. (1967). Heat transfer to liquid metals, with observations on the effect of superimposed free convection in turbulent flow. Ph.D. Thesis, University of Cape Town, South Africa.
Burmeister, L.C. (1993). Convective Heat Transfer, 2nd ed., Wiley.
Cammenga, H.K., Schulze, F.W., and Theuerl, W. (1977). Vapor pressure and evaporation coefficient of water. J. Chem Eng. Data 22, 131–134.
Carlson, G.A. and Hornbeck, R.W. (1973). A numerical solution for laminar entrance flow in a square duct. J. Applied Mech. 40, 25–30.
Catton, I. (1978). Natural convection in enclosures. In Proceedings of the Sixth International Heat Transfer Conference, Vol. 6, pp. 13–31, Hemisphere.
,CD-ADAPCO (2008). User Guide, STAR-CCM+, Version 3.04.009.
Cebeci, T. and Bradshaw, P. (1977). Momentum Transfer in Boundary Layers, Hemisphere.
Cebeci, T. and Cousteix, J. (2005). Modeling and Computation of Boundary-Layer Flows, 2nd ed., Springer.
Celata, G.P., D'Annibale, F., Chiaradia, A., and Maurizio, C. (1998). Upflow turbulent mixed convection heat transfer in vertical pipes, Int. Heat Mass Transfer 41, 4037–4054.
Cess, R.D. and Shaffer, E.C. (1959). Heat transfer to laminar flow between parallel plates with a prescribed wall heat flux. Appl. Sci. Res. A8, 339–344.
Chapman, S. and Cowling, T.G. (1970). The Mathematical Theory of Non-Uniform Gases, 3rd ed., Cambridge University Press.
Chen, R.Y. (1973). Flow in the entrance region at low Reynolds numbers. J. Fluids Eng. 95, 153–158.
Chen, T.S. and Armaly, B.F. (1987). Mixed convection in external flow. In Kakac, S., Shah, R.K., and Aung, W., eds., Handbook of Single-Phase Convective Heat Transfer, Chap. 14, Wiley.
Chen, C.J. and Chiou, J.S. (1981). Laminar and turbulent heat transfer in the pipe entrance region for liquid metals. Int. J. Heat Mass Transfer 24, 1179–1189.
Chen, C.-J. and Jaw, S.-Y. (1998). Fundamentals of Turbulence Modeling, Taylor & Francis.
Chen, T.S. and Yuh, C.F. (1979). Combined heat and mass transfer in natural convection on inclined surface. Numer. Heat Transfer 12, 233–250.
Chen, T.S. and Yuh, C.F. (1980). Combined heat and mass transfer in natural convection along a vertical cylinder. Int. J. Heat Mass Transfer 23, 451–461.
Cheng, K.C. and Wu, R.S. (1976). Viscous dissipation effects on convective instability and heat transfer in plane Poisseuille flow heated from below. Appl. Sci. Res. 32, 327–346.
Chilton, T.H. and Colburn, A.P. (1934). Mass transfer (absorption) coefficients. Ind. Eng. Chem. 26, 1183–1187.
Cho, C.H., Chang, K.S., and Park, K.H. (1982). Numerical simulation of natural convection in concentric and eccentric horizontal cylindrical annuli. J. Heat Transfer 104, 624–630.
Cho, C., Irvine, T.F. Jr., and Karni, J. (1992). Measurement of the diffusion coefficient of naphthalene into air. Int. J. Heat Mass Transfer 35, 957–966.
Cho, H.H. and Goldstein, R.J. (1994). An improved low-Reynolds-number k–ε turbulence model for recirculating flows. Int. J. Heat Mass Transfer 37, 1495–1508.
Choi, S.B., Barron, R.F., and Warrington, R.O. (1991). Fluid flow and heat transfer in microtubes. In Proceedings of the ASME 1991 Winter Annual Meeting, DSC, Vol. 32, pp. 123–134, American Society of Mechanical Engineers.
Churchill, S.W. (1977a). Friction-factor equation spans all fluid and flow regimes. Chem. Eng. 84, 91–92.
Churchill, S.W. (1977b). A comprehensive correlation equation for laminar, assisting forced and free convection. AIChE J. 23, 10–16.
Churchill, S.W. (1977c). New simplified models and formulations for turbulent flow and convection. AIChE J. 43, 1125–1140.
Churchill, S.W. (1990). Combined free and forced convection around immersed bodies. In Hewitt, G.F., ed., Hemisphere Heat Exchanger Design Handbook, Section 2.5.9, Hemisphere.
Churchill, S.W. (2000). The prediction of turbulent flow and convection in a round tube. Adv. Heat Transfer 34, 255–361.
Churchill, S.W. (2002). Free convection around immersed bodies. In Hewitt, G.F., exec. ed., Heat Exchanger Design Handbook, Begel House, New York.
Churchill, S.W. and Bernstein, M. (1977). Correlating equation for forced convection from gases and liquids to a circular cylinder in crossflow. J. Heat Transfer 99, 300–306.
Churchill, S.W. and Chu, H.H.S. (1975a). Correlating equations for laminar and turbulent free convection from a vertical plate. Int. J. Heat Mass Transfer 18, 1323–1329.
Churchill, S.W. and Chu, H.H.S. (1975b). Correlating equations for laminar and turbulent free convection from a horizontal cylinder. Int. J. Heat Mass Transfer 18, 1049–1053.
Churchill, S.W. and Ozoe, H. (1973a). Correlations for laminar forced convection with uniform heating in flow over a plate and in developing and fully developed flow in a tube. J. Heat Transfer 95, 78–84.
Churchill, S.W. and Ozoe, H. (1973b). Correlations for laminar forced convection in flow over an isothermal flat plate and in developing and fully developed flow in an isothermal tube. J. Heat Transfer 95, 416–419.
Churchill, S.W. and Usagi, R. (1972). A general expression for the correlation of rates of transfer and other phenomena. AIChE J. 18, 1121–1128.
Churchill, S.W., Yu, B., and Kawaguchi, Y. (2005). The accuracy and parametric sensitivity of algebraic models for turbulent flow and convection. Int. J. Heat Mass Transfer 48, 5488–5503.
Colebrook, C.F. (1939). Turbulent flow in pipes with particular reference to the transition region between the smooth and rough pipes laws. J. Inst. Civil. Eng. 11, 133–156.
Cotta, R.M. (1993). Integral Transforms in Computational Heat and Fluid Flow, CRC Press.
Cotton, M.A. and Jackson, J.D. (1990). Vertical tube air flows in the turbulent mixed convection regime calculated using a low Reynolds number k–ε model. Int. J. Heat Mass Transfer 33, 275–286.
Coulaloglou, C.A. and Tavralides, L.L. (1977). Description of interaction processes in agitated liquid-liquid dispersions. Chem. Eng. Science 32, 1289–1297.
Coutanceau, M. and Defaye, J.-R. (1991). Circular cylinder wake configurations: A flow visualization survey. Appl. Mech. Rev. 44, 255–305.
Crabtree, L.F., Küchemann, D., and Sowerby, L. (1963). Three-dimensional boundary layers. In Rosenhead, L., ed., Laminar Boundary Layers, Dover.
Curr, R.M., Sharma, D., and Tatchell, D.G. (1972). Numerical predictions of some three-dimensional boundary layers in ducts. Comput. Methods Appl. Mech. Eng. 1, 143–158.
Curtiss, C.F. and Bird, R.B. (1991). Multicomponent diffusion. Ind. Eng. Chem. Res. 38, 2515–2522.
Curtiss, C.F. and Bird, R.B. (2001). Errata. Ind. Eng. Chem. Res. 40, 1791.
Cussler, E.C. (2009). Diffusion Mass Transfer in Fluid Systems, 3rd ed., Cambridge University Press.
Daly, B.J. and Harlow, F.H. (1970). Transport equations in turbulence. Phys. Fluids 13, 2634–2649.
Dacles-Mariani, J. and Zilliac, G.G. (1995). Numerical/experimental study of a wingtip vortex in the near field. AIAA J. 33, 1561–1568.
Dean, R.B. (1978). Reynolds number dependence of skin friction coefficient and other bulk flow variables in two-dimensional rectangular duct flow. J. Fluids Eng. 100, 215–223.
Demirel, Y. and S.C., Saxena. (1996). Heat transfer through a low-pressure gas enclosure as a thermal insulator: Design considerations. Int. J. Energy Res. 20, 327–338.
Deissler, R.G. (1953). Analysis of turbulent heat transfer and flow in the entrance region of smooth passages. NACA TM 3016.
Deissler, R.G. (1955). Analysis of turbulent heat transfer, mass transfer, and friction in smooth tubes at high Prandtl and Schmidt numbers. NACA Tech. Rep. 1210.
Deissler, R.G. (1964). An analysis of second-order slip flow and temperature jump boundary conditions for rarefied gases. Int. J. Heat Mass Transfer 7, 681–694.
Demuren, A.O. and Rodi, W. (1984). Calculation of turbulence-driven secondary motion in non-circular ducts. J. Fluid Mech. 140, 189–xxx.
Dittus, P.W. and Boelter, L.M.K. (1930). Heat transfer in automobile radiators of the tubular type. University of California Pub. Eng. 2(2), 443–461.
Dong, Y.H., Lu, X.Y., and Zhuang, L.X. (2002). An investigation of the Prandtl number effect on turbulent heat transfer in channel flows by large eddy simulation. Acta Mech. 159, 39–51.
Duan, Z. and Muzychka, Y.S. (2007a). Slip flow in non-circular microchannels. Microfluid Nanofluid 3, 473–484.
Duan, Z. and Muzychka, Y.S. (2007b). Compressibility effect on slip flow in non-circular microchannels. Nanoscale Microscale Thermophys. Eng. 11, 259–272.
Durbin, P.A. and Medic, G. (2007). Fluid Dynamics with a Computational Perspective. Cambridge University Press.
Eames, I.W., Marr, N.J., and Sabir, H. (1997). The evaporation of water: A review. Int. J. Heat Mass Transfer 40, 2963–2973.
Ebadian, M.A. and Dong, Z.F. (1998). Forced convection, internal flow in ducts. In Rohsenwo, W.M., Hartnett, J.P., and Cho, Y.I., eds., 3rd ed., Mc-Graw-Hill.
Ebert, W.A. and Sparrow, E.M. (1965). Slip flow in rectangular and annular ducts. J. Basic Eng. 87, 1018–1024.
Eckert, E.R.G. and Drake, R.M. Jr. (1959). Heat and Mass Transfer, McGraw-Hill.
Eckert, E.R.G. and Drake, R.M. Jr. (1972). Analysis of Heat and Mass Transfer, Taylor & Francis.
Eckert, E.R.G. and Jackson, T.W. (1951). Analysis of turbulent free-convection boundary layer on flat plate. NACA Tech. Note 2207.
Edwards, D.K., Denny, V.E., and Mills, A.F. (1979). Transfer Processes, Hemisphere, New York.
Eggles, T.G.M., Ungar, F., Weiss, M.H., Westerweel, J., Adrian, R.J., Friedrich, R., and Nieuwstadt, F.T.M. (1994). Fully developed turbulent pipe flow: a comparison between direct numerical simulation and experiment. J. Fluid Mech. 268, 175–209.
Elenbaas, W. (1942). Heat dissipation of parallel planes by free convection. Physica IX(1), 2–28.
Escudier, M.P. (1966). The distribution of mixing length in turbulent flows near walls. Heat Transfer Section Rep. TWF/TN/1, Imperial College of Science and Technoloy, London. (Cited in Launder and Spalding, 1972.)
Ewart, T., Perrier, P., Graur, I., and Meolans, J.G. (2007). Tangential momentum accommodation in microtube. Microfluid Nanofluid 3, 689–695.
Falkner, V.M. and Skan, S.W. (1931). Some appropriate solutions of the boundary layer equations. Phil. Mag. 12, 865–896.
Fan, Y. and Luo, L. (2008). Recent applications of advances in microchannel heat exchangers and multi-scale design optimization. Heat Trans. Eng. 29, 461–474.
Ferziger, J.H. and Peric, M. (1996). Computational Methods for Fluid Dynamics. Springer-Verlag.
Fleming, D.P. and Sparrow, E.M. (1969). Flow in the hydrodynamic entrance region of ducts of arbitrary cross-section. J. Heat Transfer 91, 345–354.
Fluent 6.3 User's Manual, 2006.
Fujii, T. and Imura, H. (1972). Natural convection from a plate with arbitrary inclination. Int. J. Heat Mass Transfer 15, 755–767.
Gad-el-Hak, M. (1999). The fluid mechanics of microdevices – The Freeman Scholar Lecture. J. Fluid Eng. 121, 5–33.
Gad-el-Hak, M. (2003). Comments on “critical view on new results in micro-fluid mechanics.”Int. J. Heat Mass Transfer 46, 3941–3945.
Gad-el-Hak, M. (2006). Gas and liquid transport at the microscale. Heat Transfer Eng. 27, 13–29.
Gatski, T.B. and Speziale, C.G. (1993). On explicit algebraic stress models for complex turbulent flows. J. Fluid Mech. 254, 59–78.
Gebhart, B. (1981). Heat Transfer, 2nd ed., McGraw-Hill.
Gebhart, B. and Pera, I. (1971). The nature of vertical natural convection flows resulting from the combined buoyancy effects of thermal and mass diffusion. Int. J. Heat Mass Transfer 14, 2025–2050.
Ghiaasiaan, S.M. (2008). Two Phase Flow, Boiling and Condensation in Conventional and Miniature Systems. Cambridge University Press.
Ghiaasiaan, S.M. and Laker, T.S. (2001). Turbulent forced convection in microtubes. Int. J. Heat Mass Transfer 44, 2777–2782.
Ghodoossi, L. and Egrican, N. (2005). Prediction of heat transfer characteristics in rectangular microchannels for slip flow regime and H1 boundary condition. Int. J. Thermal Sci. 44, 513–520.
Giedt, W.H. (1949). Investigation of variation of point unit-heat-transfer coefficient around a cylinder normal to an air stream. Trans. ASME 71, 375–381.
Gilpin, R.R., Imura, H., and Cheng, K.C. (1978). Experiments on the onset of longitudinal vortices in horizontal Blasius flow heated from below. J. Heat Transfer 100, 71–77.
Gnielinski, V. (1976). New equations for heat and mass transfer in turbulent pipe and channel flow. Int. Chem. Eng. 16, 359–368.
Globe, S. and Dropkin, D. (1959). National convection heat transfer in liquids confined by two horizontal plates and heated from below. J. Heat Transfer 81, 24–28.
Goldstein, S. (1937). The similarity theory of turbulence and flow between parallel planes and through pipes. Proc. R. Soc. London Ser. A 159, 473–496.
Goldstein, S., ed. (1965). Modern Developments in Fluid Dynamics, Vol. II, Dover.
Gombosi, T.I. (1994). Gaskinetic Theory. Cambridge University Press.
Graetz, L. (1885). Uber die Warmeleitungsfahigkeiten von Flussigkeiten. Annal. Phys. Chem. Part 1, 18, 79–94; Part 2, 15, 337–357.
Grotzbach, G. (1983). Special resolution requirement for direct numerical simulation of Rayleigh–Bénard convection. J. Comput. Phys. 49, 241–264.
Haaland, S.E. (1983). Simple and explicit formulas for the friction factor in turbulent pipe flow. J. Fluids Eng. 105, 89–90.
Hadjiconstantinou, N.G. (2005). Validation of a second-order slip model for dilute gas flow. Microscale Thermophys. Eng. 9, 137–153.
Hadjiconstantinou, N.G. and Simek, O. (2002). Constant-wall-temperature Nusselt number in micro and nano-channels. J. Heat Transfer 124, 356–364.
Hanjalic, K. and Launder, B.E. (1976). Contribution towards a Reynolds-stress closure for low-Reynolds number turbulence. J. Fluid Mech. 74, 593–610.
Hanks, R.W. and Weissberg, H.L. (1964). Slow viscous flow of rarefied gases through short tubes. J. Applied Phys. 35, 142–144.
Hanna, O.T. and Myers, J.E. (1962). Heat transfer in boundary-layer flows past a flat plate with a step-in wall-heat flux. Chem. Eng. Sci. 17, 1053–1055.
Hartree, D.R. (1937). On an equation occurring in Falkner and Skan's approximate treatment of the boundary layer. Proc. Cambridge Philos. Soc. 33, 223–239.
Hausen, H. (1983). Heat Transfer in Counter Flow, Parallel Flow, and Cross-Flow, McGraw-Hill.
Hayashi, Y., Takimoto, A., and Hori, K. (1977). Heat transfer in laminar mixed convection flow over a horizontal flat plate [in Japanese]. In Proceedings of the 14th Japan Heat Transfer Symposium, pp. 4–6.
Herbert, L.S. and Stern, U.J. (1972). Heat transfer in vertical tubes – Interaction of forced and free convection. Chem. Eng. J. 4, 46–52.
Herwig, H. and Hausner, O. (2003). Critical view on new results in micro-fluid mechanics: an example. Int. J. Heat Mass Transfer 46, 935–937.
Hilpert, R. (1933). Wärmeabgabe von geheizten drähten und rohren. Forsch. Geb. Ingenieurwes. 4, 215.
Hindmarsh, A.C. (1980). LSODE and LSODI, two new initial value ordinary differential equation solvers. ACM Newslett. 15(5), 10.
Hinze, J.O. (1975). Turbulence. McGraw-Hill.
Hinze, J.O. (1955). Fundamentals of the hydrodynamic mechanism of splitting in dispersion processes. AIChE J. 1, 289–295.
Hirschfelder, J., Curtiss, C.F., and Bird, R.. (1954). Molecular Theory of Gases and Liquids, Wiley.
Hollands, K.G.T., Raithby, G.D., and Konicek, L. (1975). Correlation equations for free convection heat transfer in horizontal layers of air and water. Int. J. Heat Mass Transfer 18, 879–884.
Hollands, K.G.T., Unny, T.E., Raithby, G.D., and Konicek, L. (1976). Free convection heat transfer across inclined air layers. J. Heat Transfer 98, 189–193.
Howarth, L. (1938). On the solution of the laminar boundary layer equations. Proc. R. Soc. London Ser. A. 164, 547.
Hrycak, P. and Andrushkiw, R. (1974). Calculation of critical Reynolds number in round pipes and infinite channels and heat transfer in transition regions. Heat Transfer II, 183–187.
Hsu, C.J. (1965). Heat transfer in a round tube with sinusoidal wall heat flux distribution. AIChE J. 11, 690–695.
Inman, R.M. (1964a). Heat transfer for laminar slip flow of a rarified gas in a parallel plate channel or a circular tube with uniform wall temperature. NASA TN D-2213.
Inman, R.M. (1964b). Laminar slip flow heat transfer in a parallel plate channel or a round tube with uniform wall heating. NASA TN D-2393.
Inman, R.M. (1965). Heat transfer in thermal entrance region with laminar slip flow between parallel plates at unequal temperatures. NASA TN-D-2980.
Incropera, F.P., Dewitt, D.P., Bergman, T.L., and Lavine, A.S. (2007). Fundamentals of Heat and Mass Transfer, 6th ed., Wiley.
Jackson, J.D., Cotton, M.A., and Axcell, B.P. (1989). Studies of mixed convection in vertical tubes. Int. J. Heat Fluid Flow 10, 2–15.
Jackson, J.D. and Hall, W.B. (1979). Influence of buoyancy on heat transfer to fluids flowing in vertical tubes under turbulent conditions. In Kakac, S. and Spalding, D.B., eds. Turbulent Forced Convection in Channels and Bundles, Hemisphere, pp. 613–673.
Jaluria, Y. (2003). Natural convection, in Heat Transfer Handbook, Bejan, A. and Kraus, A.D., eds., Chap. 7, Wiley.
Jang, J. and Werely, S. (2007). Gaseous slip flow analysis of a micromachined flow sensor for ultra small flow applications. J. Micromech. Microeng. 17, 229–237.
Jayatilleke, C.L. (1969). The influence of Prandtl number and surface roughness on the resistance of the laminar sub-layer to momentum and heat transfer. Prog. Heat Mass Transfer 1, 193–330.
Jeong, H.-E. and Jeong, J.-T. (2006). Extended Graetz problem including streamwise conduction and viscous dissipation in microchannel. Int. J. Heat Mass Transfer 49, 2151–2157.
Jiang, L., Wang, Y., Wong, M., and Zohar, Y. (1999). Fabrication and characterization of a microsystem for microscale heat transfer study, J. Micromech. Microeng. 9, 422–28.
Jiji, L.M. (2006). Heat Convection. Springer.
Jischa, H. and Rieke, H.B. (1979). About the prediction of turbulent Prandtl and Schmidt numbers. Int. J. Heat Mass Transfer 2, 1547–1555.
Johnson, D.A. and King, L.S. (1985). Mathematically simple turbulence closure model for attached and separated turbulent boundary layers. AIAA J. 23, 1684–1692.
Jones, W.P. and Launder, B.E. (1973). The prediction of laminarization with a two-equation model of turbulence. Int. J. Heat Mass Transfer 15, 301–314.
Jones, C.W. and Watson, E.J. (1963). Two-dimensional boundary layers. In Rosenhead, L., ed., Laminar Boundary Layers, Dover.
Jones, O.C. Jr. (1976). An improvement in the calculation of turbulent friction in rectangular ducts. J. Fluids Eng. 98, 173–181.
Jones, O.C. Jr. and Leung, C.M. (1981). An improvement in the calculation of turbulent friction in smooth concentric annuli. J. Fluids Eng. 103, 615–623.
Kader, B.A. (1981). Temperature and concentration profiles in fully turbulent boundary layers. Int. J. Heat Mass Transfer 24, 1541–1544.
Kawamura, H, Ohsake, K., Abe, H., and Yamamoto, K. (1998). DNS of turbulent heat transfer in channel flow with low to medium-high Prandtl number fluid. Int. J. Heat Fluid Flow, 19, 482–481.
Kays, W.M., Crawford, M.E., and Weigand, B. (2005). Convective Heat and Mass Transfer, 4th ed., McGraw-Hill.
Kays, W.M. and London, A.L. (1984). Compact Heat Exchangers, 3rd ed., McGraw-Hill.
Kays, W.M. and Perkins, H.C. (1972). In Rohsenow, W.M. and Hartnett, J.P., eds., Handbook of Heat Transfer, Chap. 7, McGraw-Hill.
Khadem, M.H., Shams, M., and Hossainpour, S. (2008). Effects of rarefaction and compressibility on fluid flow at slip flow regime by direct simulation of roughness. In Proceedings of the World Academy of Science, Engineering and Technology 31.
Kitamura, K. and Inagaki, T. (1987). Turbulent heat and momentum transfer of combined forced and natural convection along a vertical flat plate – Aiding flow. Int. J. Heat Mass Transfer 30, 23–41.
Klebanoff, P.S. (1955). Characteristics of Turbulence in a Boundary Layer with Zero Pressure Gradient. NACA-1247.
Kobus, C.J. and Wedekind, G.L. (1996). Modeling the local and average heat transfer coefficient for an isothermal vertical flat plate with assisting and opposing combined forced and natural convection. Int. J. Heat Mass Transfer 39, 2723–2733.
Kohl, M.J., Abdel-Khalik, S.I., Jeter, S.M., and Sadowski, D.L. (2005). An experimental investigation of microchannel flow with internal pressure measurements. Int. J. Heat Mass Transfer 48, 1518–1533.
Kolmogorov, A.N. (1942). Equations of turbulent motion of an incompressible turbulent flow. Izv. Akad. Nauk SSSR Ser Phys. 4(1–2), [Cited in Launder B.E. and Spalding D.B. (1972), Mathematical Models of Turbulence, Academic.]
Kreith, F. (1970). Thermal design of high altitude balloons and instrument packages. J. Heat Transfer 92, 307–332.
Krishnamurthy, R. and Gebhart, B. (1989). Experimental study of transition to turbulence in vertical mixed convection flows. J. Heat Transfer 111, 121–130.
Krishnamoorthy, C., Rao, R.P., and Ghajar, A. (2007). Single-phase heat transfer in microtubes: A critical review. In Proceedings of the ASME-JSME Thermal Engineering Summer Heat Transfer Conference, American Society of Mechanical Engineers.
Kronig, R. and Brink, J.C. (1950). On the theory of extraction from falling droplets, Appl. Sci. Res. A 2, 142–154.
Kudo, K., Kato, T., Chida, H., Tagaki, S., and Tsui, N. (2003). Modeling of combined forcedand natural-convection heat transfer over upward-facing horizontal heated flat plates. Int. J. Energy Res. 27, 327–335.
Labbé, O. and Sagaut, P. (2002). Large eddy simulation of heat transfer over a backward – facing step. Numerical Heat Transfer: A, 42, 73–90.
Larkin, B.K. (1961). High-order eigenfunctions of the Graetz problem. AIChE J. 7, 530.
Latzko, H. (1921). Der warmeubergang and einen turbulenten flussigkeitsoder gasstrom. Z. Angew. Math. Mech. (ZAAM) 1, 268–290. [English translation: NACA TM 1068 (1944).]
Launder, B.E. (1988). On the computation of convective heat transfer in complex turbulent flows. J. Heat Transfer 110, 1112–1128.
Lauder, B.E., Reece, G.J., and Rodi, W. (1975). Progress in the development of a reynoldsstress turbulence closure. J. Fluid Mech. 68, 527–566.
Launder, B.E. and Sharma, B.I. (1974). Application of the energy dissipation model of turbulence to the calculation of flow near a spinning disc. Lett. Heat Mass Transfer 1, 131–138.
Lai, Y.G. and So, R.M.C. (1990). Near-wall modeling of turbulent heat fluxes. Int. J. Heat Mass Transfer 33, 1429–1440.
Launder, B.E. and Shima, N. (1989). Second-moment closure for near-wall sublayer: Development and application. AIAA J. 27, 1319–1325.
Launder, B.E. and Spalding, D.B. (1972). Lectures in Mathematical Models of Turbulence, Academic.
Launder, B.E. and Spalding, D.B. (1974). The numerical computation of turbulent flows. Comput. Methods Appl. Mech. Eng. 3, 269–289.
Lee, K.-T. (1999). Laminar natural convection heat and mass transfer in vertical rectangular ducts. Int. J. Heat Mass Transfer 42, 4523–4534.
LeFevre, E.J. (1956). Laminar free convection from a vertical plane surface. Proc. 9th Int. Congress on Applied Mech., Brussels, Vol. 4, p. 168.
LeFevre, E.J. and Ede, A.J. (1956). Laminar free convection from the outer surface of a vertical circular cylinder. In Proceeding of the Ninth International Congress on Applied Mechanics, Vol. III, pp. 175–183.
Levich, V.E. (1962). Physicochemical Hydrodynamics. Prentice-Hall.
Li, D. (2004). Electrokinetics in Microfluidics, Elsevier Academic.
Li, X., Lee, W.Y., Wong, M., and Zohar, Y. (2000). Gas flow in constriction microdevices. Sensors Actuators A 83, 277–283.
Lienhard, J.H., IV (1966). Synopsis of lift, drag and vortex frequency data for rigid circular cylinders. Bulletin 300, College of Engineering Research Division, University of Washington (available at http://www.uh.edu/engines/vortexcylinders.pdf).
Lienhard, J.H., IV and Lienhard, J.H.V. (2005). A Heat Transfer Textbook, 3rd ed., Phlogiston Press.
Lin, H.-T. and Wu, C.-M. (1995). Combined heat and mass transfer by laminar natural convection from a vertical plate. Heat Mass Transfer 30, 369–376.
Lin, H.-T. and Wu, C.-M. (1997). Combined heat and mass transfer by laminar natural convection from a vertical plate with uniform heat flux and concentration. Heat and Mass Transfer 32, 293–299.
Liou, W.M. and Fang, Y. (2006). Microfludic Mechanics, McGraw-Hill.
Liu, J. (1974). Flow of a Bingham fluid in the entrance region of an annular tube. M.S. Thesis, University of Wisconsin-Milwaukee.
Lloyd, J.R. and Sparrow, E.M. (1970). On the instability of natural convection flow on inclined plates. J. Fluid Mech. 42, 465–470.
Lundberg, R.E., McCuen, P.A., and Reynolds, W.C. (1963). Heat transfer in annular passages. Hydrodynamically developed laminar flow with arbitrary prescribed wall temperatures or heat fluxes. Int. J. Heat Mass Transfer 6, 495–529.
Lyons, S.L., Hanratty, T.J., and McLaughlin, J.B. (1991a). Large-scale computer simulation of fully developed turbulent channel flow with heat transfer. Numer. Methods Fluids 13, 999–1028.
Lyons, S.L., Hanratty, T.J., and McLaughlin, J.B.. (1991b). Direct numerical simulation of passive heat transfer in a turbulent channel flow. Int. J. Heat Mass Transfer 34, 1149–1161.
Maa, J.R. (1967). Evaporation coefficient of liquids. Ind. Eng. Chem. Fundamentals 6, 504–518.
Martinelli, R.C. (1947). Heat transfer to molten metals. Trans. ASME 69, 947–959.
Mathieu, J. and Scott, J. (2000). An Introduction to Turbulent Flow, Cambridge University Press.
Mathpati, C.S. and Joshi, J.B. (2007). Insight into theories of heat and mass transfer at the solid – fluid interface using direct numerical simulation and large eddy simulation. Ind. Eng. Chem. Res. 46, 8525–8557.
McAdams, W.H. (1954). Heat Transmission, 3rd ed., McGraw-Hill.
McGregor, R.K. and Emery, A.P. (1969). Free convection through vertical plane layers: Moderate and high Prandtl number fluids. J. Heat Transfer 91, 391.
Menter, F.R., 1993. Zonal two-equation k–ω model for aerodynamic flows. AIAA Paper 93-2903.
Menter, F.R. (1994). Two-equation eddy viscosity turbulence models for engineering applications. AIAA J. 32, 1598–1605.
Menter, F.R. (1996). A comparison of some recent eddy viscosity turbulent models. J. Fluids Eng. 118, 514–519.
Metais, B. and Eckert, E.R.G. (1964). Forced mixed and free convection regimes. J. Heat Transfer 86, 295–296.
Métais, O. and Lesieur, M. (1992). Spectral large-eddy simulation of isotropic and stably stratified turbulence. J. Fluid Mech. 239, 157–194.
Michelsen, M.L. and Villadsen, J. (1974). The Graetz problem with axial heat conduction. Int. J. Heat Mass Transfer 17, 1391–1402.
Miller, R.W. and Han, L.S. (1971). Pressure losses for laminar flow in the entrance region of ducts of rectangular and equilateral triangular cross section. J. Appl. Mech. 38, 1083–1087.
Mills, A.F. (1962). Experimental investigation of turbulent heat transfer in the entrance region of a circular conduit. J. Mech. Eng. Sci. 4, 63–77.
Mills, A.F. (2001). Mass Transfer. Prentice-Hall.
Mills, A.F. and Seban, R.A. (1967). The condensation coefficient of water. Int. J. Heat Mass Transfer 10, 1815–1827.
Misumi, T., Shigemaru, S., and Kitamura, K. (2007). Fluid flow and heat transfer of opposing mixed convection adjacent to upward-facing, inclined heated plates. Heat Transfer Asian Res. 36, 127–142.
Molki, M. and Sparrow, E.M. (1986). An empirical correlation for the average heat transfer coefficient in circular tubes. J. Heat Transfer 108, 482–484.
Mompean, G., Gavrilakis, S., Machiels, L., and Deville, M.O. (1996). On predicting the turbulence-induced secondary flows using non-linear k–ε models. Phys. Fluids 8, 1856–1868.
Moutsoglu, A., Chen, T.S., and Cheng, K.C. (1981). Vortex instability of mixed convection flow over a horizontal flat plate. J. Heat Transfer 103, 257–262.
Morcos, S.M. and Bergles, A.E. (1975). Experimental investigation of combined forced and free laminar convection in horizontal tubes. Int. J. Heat Mass Transfer 97, 212–219.
Mori, Y. and Futagami, K. (1967). Forced convection heat transfer in uniformly heated horizontal tubes (2nd report, theoretical study). Int. J. Heat Mass Transfer 10, 1801–1813.
Morini, G.L. (2004). Single-phase convective heat transfer in microchannels: a review of experimental results. Int. J. Thermal Sci. 43, 631–651.
Morini, G.L., Spiga, M., and Tartarini, P. (2004). The rarefaction effect on the friction factor of gas flow in microchannels. Superlattices Microstructures 35, 587–599.
Muzychka, Y.S. and Yovanovich, M.M. (2004). Laminar forced convection heat transfer in the combined entry region of non-circular ducts. J. Heat Transfer 126, 54–61.
Na, Y. and Hanratty, T.J. (2000). Limiting behavior of turbulent scalar transport close to a wall. Int. J. Heat Mass Transfer 43, 1749–1758.
Nagano, Y. and Shimada, M. (1996). Development of a two-equation heat transfer model based on direct numerical simulation of turbulent flows with different Prandtl numbers. Phys. Fluids 8, 3379–3402.
Narsimhan, G., Gupta, J.P., and Ramkrishna, D. (1979). A model for transitional breakage probability of droplets in agitated lean liquid-liquid dispersions. Chem. Eng. Sci. 34, 257–265.
Nelson, D.J. and Wood, B.D. (1989a). Combined heat and mass transfer natural convection between vertical parallel plates. Int. J. Heat Mass Transfer 32, 1779–1787.
Nelson, D.J. and Wood, B.D. (1989b). Fully-developed combined heat and mass transfer natural convection between vertical parallel plates with asymmetric boundary conditions. Int. J. Heat Mass Transfer 32, 1789–1792.
Nikuradse, J. (1932). Gesetzmässigkeiten der turbulenten Strömung in glatten Rohren. Forsch. Arb. Ing. Wes. 356. [English translation, NASA TT F-IO 359, 1966.]
Nikuradse, J. (1933). Strömungsgesetze in rauhen Rohnen. Forsch. Arb. Ing.-Wes. 361.
Norris, R.H. (1970). Some simple approximate heat-transfer correlations for turbulent flow in ducts with rough surfaces. In Augmentation of Convective Heat and Mass Transfer, pp. 16–26, American Society of Mechanical Engineers.
Notter, R.H. and Sleicher, C.A. (1971a). The eddy diffusivity in turbulent boundary layer near a wall. Chem. Eng. Sci. 26, 161–171.
Notter, R.H. and Sleicher, C.A. (1971b). A solution to the turbulent Graetz problem by matched asymptotic expansions-II. The case of uniform heat flux. Chem. Eng. Sci. 26, 559–565.
Notter, R.H. and Sleicher, C.A. (1972). A solution to the turbulent Graetz problem-III. Fully developed and entry region heat transfer rates. Chem. Eng. Sci. 27, 2073–2093.
Oosthuizen, P.H. and Hart, R. (1973). A numerical study of laminar combined convection over flat plates. J. Heat Transfer 96, 60–63.
Oosthuizen, P.H. and Naylor, D. (1999). Introduction to Convective Heat Transfer Analysis. McGraw-Hill.
Orszag, S.A., Yakhot, V., Flannery, W.S., Boysan, F., Choudhury, D., Manizewski, J., and Patel, B. (1993). Renormalization group modeling and turbulence simulation. In So, R.M.C., Speziale, C.G., and Launder, B.E., eds., Near Wall Turbulent Flows, pp. 1031–1046, Elsevier.
Ostrach, S. (1953). An analysis of laminar free convection flow and heat transfer about a flat plate parallel to the direction of the generating body force. NACA Tech. Rep. 1111.
Pahor, S. and Strand, J. (1961). A note on heat transfer in laminar flow through a gap. Appl. Sci. Res. A 10, 81–84.
Papautsky, I., Ameel, T., and Frazier, A.B. (2001). A review of laminar single-phase flow in microchannels. In Proceedings of the International Mechanical Engineering Congress and Exposition, ASME.
Papavassiliou, D. and Hanratty, T.J. (1997). Transport of a passive scalar in a turbulent channel flow. Int. J. Heat Mass Transfer 40, 1303–1311.
Patel, K., Armaly, B.F., and Chen, T.S. (1996). Transition from turbulent natural to turbulent forced convection adjacent to an isothermal vertical plate. ASME Heat Transfer Division (HTD) 324, 51–56.
Patel, K., Armaly, B.F., and Chen, T.S. (1998). Transition from turbulent natural to turbulent forced convection. J. Heat Transfer 120, 1086–1089.
Pellew, A. and Southwell, R.V. (1940). On maintained convective motion in a fluid heated from below. Proc. R. Soc. London Ser. A 176, pp. 312–343.
Peng, X.F. and Peterson, G.P. (1996). Convective heat transfer and flow friction for water flow in microchannel structures. Int. J. Heat Mass Transfer 39, 2599–2608.
Peng, X.F. and Wang, B.X. (1994). Liquid flow and heat transfer in microchannels with/without phase change. In Heat Transfer 1994, Proceedings of the Tenth International Heat Transfer Conference, Vol. 5, pp. 159–177, Institution of Chemical Engineers.
Peng, X.F. and Wang, B.X. (1998). Forced-convection and boiling characteristics in microchannels. In Proceedings of the 11th International Heat Transfer Conference, pp. 371–390, Korean Society of Mechanical Engineers.
Pera, I. and Gebhart, B. (1972). Natural convection flows adjacent to horizontal surfaces resulting from the combined buoyancy effects of thermal and mass diffusion. Int. J. Heat Mass Transfer 15, 269–278.
Perkins, K.R., Shade, K.W., and McEligot, D.M. (1973). Heated laminarizin gas flow in a square duct. Int. J. Heat Mass Transfer 16, 897–916.
Pletecher, R.H. (1987). External flow forced convection. In Kacac, S., Shah, R.S., and Aung, W., eds., Handbook of Single-Phase Convective Heat Transfer, Chap. 2, Wiley.
Petukhov, B.S. (1970). Heat transfer and friction factor in turbulent pipe flow with variable physical properties. Adv. Heat Transfer, 6, 503–565.
Prandtl, L. (1910). Z. Phys. 11, 1072.
Prandtl, A. (1925). Z. Angew. Math. Mech. 5, 136–139.
Prandtl, L. (1928). Z. Phys. 29, 487.
Prandtl, L. (1933). Neuere Ergebnisse der Turbulenzforschung. VDIZ. (77/5): 105–114, 1933. [English translation NACA TM 7320.]
Prandtl, L. (1945). Ube rein neues formelsystem fur die ausgebildete turbulenz. Nachr. Akad. Wiss. Gottinge Math.-Phys. II, p. 6.
Press, H.W., Teukolsky, S.A., Vetterling, W.T., and Flannery, B.P. (1992). Numerical Recipes for FORTRAN 77, Vol. 1, Cambridge University Press.
Press, H.W., Teukolsky, S.A., Vetterling, W.T., and Flannery, B.P. (1997). Numerical Recipes for C, 2nd Ed., Numerical Recipe Software.
Probstein, R.F. (2003). Physicohcemical Hydrodynamics, 2nd ed., Wiley.
Raithby, G.D. and Hollands, K.G.T. (1974). A General Method of Obtaining Approximate Solutions to Laminar and Turbulent Free Convection Problems. In Advances Heat Transfer, Academic Press, New York.
Raithby, G.D. and Hollands, K.G.T. (1998). Natural Convection, in Rohsenow, W.M., Hartnett, J.P., and Cho, Y.I., eds, Handbook of Heat Transfer, 3rd Ed., Chp. 4, McGraw-Hill.
Ramachandran, N., Armaly, B.F., and Chen, T.S. (1985). Measurement and prediction of laminar mixed convection flow adjacent to a vertical surface. J. Heat Mass Transfer 107, 636–641.
Ramachandran, N., Armaly, B.F., and Chen, T.S. (1987). Measurement of laminar mixed convection from an inclined surface. J. Heat Mass Transfer 109, 146–150.
Ranz, W.E. and Marshall, W.R. Jr. (1952). Evaporation from drops. Parts I and II, Chem. Eng. Progress, 48, 141–146 and 173–180.
Redjem-Saad, L., Ould-Rouiss, M., and Lauriat, G. (2007). Direct Numerical Simulation of Turbulent Heat Transfer in Pipe Flows: Effect of Prandtl Number. Int. J. Heat Mass Transfer, 28, 847–861.
Reed, C.B. (1987). Convective heat transfer in liquid metals. In Kakac, S., Shah, R.K., and Aung, W., eds., Handbook of Single-Phase Convective Heat Transfer, Chapter 8, Wiley.
Reichardt, H. (1951). Vollstandige darstellung der turbulenten geschwindigkeitsverteilung in glatten leitungen. Z. Angew. Math. Mech. 31, 208–219.
Renksizbulut, M. and Yuen, M.C. (1983). Experimental study of droplet evaporation in a high-temperature air stream. J. Heat Transfer 105, 384–388.
Renksizbulut, M. and Haywood, R.J. (1988). Transient droplet evaporation with variable properties and internal circulation at intermediate Reynolds numbers. Int. J. Multiphase Flow 14, 189–202.
Reshotko, E. and Cohen, C.B. (1955). Heat Transfer at Forward Stagnation Point of Blunt Bodies. National Advisory Committee for Aeronautics, Technical Note3513.
Reynolds, W.C., Lundberg, R.E., and McCuen, P.A. (1963). Heat transfer in annular passages. General formulation of problem for arbitrarily prescribed wall temperatures or heat fluxes. Int. J. Heat Mass Transfer 6, 483–493.
Roache, P.J. (1998). Fundamentals of Computational Fluid Dynamics, Hermosa Publishers.
Rodi, W. (1976). New algebraic relations for calculating the Reynolds stresses. Z. Angew. Math. Mech. 56, 219–221.
Rodi, W. (1982). Examples of turbulence models for incompressible flows. AIAA J. 20, 872–879.
Rokni, M. and Sunden, B. (2003). Calculation of turbulent fluid flow and heat transfer in ducts by a full Reynolds stress model. Int. J. Numer. Methods In Fluids 42, 147–162.
Rose, J., Uehara, H., Koyama, S., and Fujii, T. (1999). Film condensation. In Handbook of Phase Change, Kandlikar, S.G., Shoji, M., and Dhir, V.K., eds., pp. 523–580, Taylor & Francis.
Rowley, R.L. (1994). Statistical Mechanics for Thermophysical Property Calculations. Prentice Hall.
Rubinstein, R. and Barton, J.M. (1990). Nonlinear Reynolds stress models and the renormalization group. Phys. Fluids A 8, 1427–1476.
Rubinstein, R. and Barton, J.M. (1992). Renormalization group analysis of the Reynolds stress transport equation. Phys. Fluids A 4, 1759–1766.
Rutledge, J. and Sleicher, C.A. (1993). Direct simulation of turbulent flow and heat transfer in a channel. Part I. Smooth walls. Int. J. Numer. Methods Fluids 16, 1051–1078.
Sarkar, S. and Balakrishnan, L. (1990). Application of a Reynolds-stress turbulence model to the compressible shear layer. ICASE Report 90–18, NASA CR 182002.
Saxena, S.C. and Joshi, R.K. (1989). Thermal Accommodation and Adsorption Coefficients of Gases. Hemisphere.
Schaaf, S.A. and Chambré, P.L. (1961). Flow of Rarefied Gases. Princeton University Press.
Schlichting, H. (1968). Boundary Layer Theory, 6th ed., McGraw-Hill.
Schrage, R.W. (1953). A Theoretical Study of Interphase Mass Transfer, Columbia University Press.
Schultz-Grunow, F. (1941). New frictional resistance law for smooth plates. NACA TM-986.
Schulze, H.J. (1984). Physico-Chemical Elementary Processes in Flotation, pp. 123–129, Elsevier.
Seban, R.A. and Shimazaki, T.T. (1951). Heat transfer to fluid flowing turbulently in a smooth pipe with walls at constant temperature. Trans. ASME 73, 803–807.
Sellars, R.J., Tribus, M., and Klein, J.S. (1956), Heat transfer to laminar F in a round tube or flat conduit – Graetz problem extended. Trans. ASME 78, 441–448.
Shah, R.K. and Bhatti, M.S. (1987). Laminar convective heat transfer in ducts. In Kacac, S., Shah, R.S., and Aung, W., eds., Handbook of Single-Phase Convective Heat Transfer, Chap. 3, Wiley.
Shah, R.K. and London, A.L. (1978). Laminar Flow Forced Convection in Ducts, Academic.
Sharp, K.V. and Adrian, R.J. (2004). Transition from laminar flow to turbulent flow in liquid filled microtubes. Exp. Fluids 36, 741–747.
Shih, T., Zhu, J., and Lumley, J.L. (1993). A realizable Reynolds stress algebraic equation model. NASA TM-105993.
Shima, N. (1988). Reynolds stress model for near-wall and low-Reynolds-number regions. J. Fluids Eng. 110, 38–44.
Shinagawa, H., Setyawan, H., Asai, T., Sugiyama, Y., and Okuyama, K. (2002). An experimental and theoretical investigation of rarefied gas flow through circular tube of finite length. Chem. Eng. Sci. 57, 4027–4036.
Shinnar, R. (1961). On the behavior of liquid dispersions in mixing vessels. J. Fluid Mech. 10, 259–275.
Sieder, E.N. and Tate, G.E. (1936). Heat transfer and pressure drop of liquids in tubes. Ind. Eng. Chem. 28, 1429.
Siegel, R., Sparrow, E.M., and Hallman, T.M. (1958). Steady laminar heat transfer in a circular tube with prescribed wall heat flux. Appl. Sci. Res. A 7, 386–392.
Simpson, R.L. (1968). The Turbulent Boundary Layer on a Porous Wall. PhD Thesis. Stanford University, Stanford, California.
Skelland, A.H.P. (1974). Diffusional Mass Transfer, Krieger.
Skupinski, E., Tortel, J., and Vautrey, L. (1985). Determination des coefficients de convection d'un allage sodium-potassium dans un tube circulaire. Int. J. Heat Mass Transfer 8, 937–951.
Smagorinsky, J. (1963). General circulation experiments with the primitive equations I. The basic experiment. Month. Weather Rev. 91(3), 99–164.
Sohn, H.Y.Johnson, S.H., and Hindmarsh, A.C. (1985). Application of the method of lines to the analysis of single fluid-solid reactions in porous media. Chem. Eng. Sci. 40, 2185–2190.
Song, S. and Yovanovich, M.M. (1987). Correlation of thermal accommodation coefficient for engineering surfaces. In Fundamentals of Conduction and Recent Developments in Contact Resistance, M., ImberG.P., Peterson and M.M., Yovanovich, Eds., Vol. 69, p. 107, American Society of Mechanical Engineers.
Spalart, P.R. and Allmaras, S.R. (1992). A one-equation turbulence model for aerodynamic flows. AIAA-92-0439.
Spalart, P.R. and Allmaras, S.R. (1994). A one-equation turbulence model for aerodynamic flows. Recherche Aérospatiale 1, 5–21.
Spalart, P.R., Deck, S., Shur, M.L., Squires, K.D., Strelets, M., and Travin, A. (2006). A new version of detached eddy simulation, resistant to ambiguous grid densities. Theor. Comput. Fluid Dyn. 20, 181–195.
Spalding, D.B. (1961). A single formula for the law of the wall. J. Appl. Mech. 28, 455–457.
Sparrow, E.M. (1955). Laminar free convection on a vertical plate with prescribed nonuniform wall heat flux or prescribed nonuniform wall temperature. NACA TN 3508.
Sparrow, E.M. and Gregg, J.L. (1956a). Laminar free convection heat transfer from the outer surface of a vertical circular cylinder. Trans. ASME 78, 1823–1829.
Sparrow, E.M. and Gregg, J.L. (1956b). Laminar free convection from a vertical plate with uniform heat flux. Trans. ASME 78, 435–440.
Sparrow, E.M. and Gregg, J.L. (1956c). Buoyancy effects in forced-convection flow and heat transfer, J. Applied Mech. 26, 133–134.
Sparrow, E.M. and Gregg, J.L. (1958). Similar solutions for free convection from a non-isothermal vertical plate, J. Heat Transfer 80, 379–386.
Sparrow, E.M., Hallman, T.M., and Siegel, R. (1957). Turbulent heat transfer in the thermal entrance region of a pipe with uniform heat flux. Appl. Sci. Res. Sec. A 7, 37–52.
Sparrow, E.M. and Lin, S.H. (1962). Laminar heat transfer in tubes under slip-flow conditions. J. Heat Transfer 84, 363–369.
Sparrow, E.M., Novotny, J.L., and Lin, S.H. (1963). Laminar flow of a heat-generating fluid in a parallel-plate channel. AIChE J. 9, 797–804.
Sparrow, E.M., Husar, R.B., and Goldstein, R.J. (1970). Observations and other characteristics of thermals. J. Fluid Mech. 41, 793–800.
Sparrow, E.M. and Patankar, S.V. (1977). Relationships among boundary conditions and Nusselt numbers for thermally developed duct flows. J. Heat Transfer 99, 483–485.
Speziale, C.G. (1987). On nonlinear K–l and K–ε models of turbulence. J. Fluid Mech. 178, 459–475.
Springer, G.S. (1971). Heat transfer in rarefied gases. In Irvine, T.F. and Hartnett, J.P., eds., Advances in Heat Transfer Vol. 7, Academic.
Stanley, R. S., Barron, R. F., and Ameel, T. A. (1997). Two-phase flow in microchannels. In ASME Microelectromechanical Systems, DSC-Vol. 62/HTD-Vol. 354, pp. 143–152, American Society of Mechanical Engineers.
Sripada, R.K.L. and Angirasa, D. (2001). Simultaneous heat and mass transfer by natural convection above upward facing horizontal surfaces. Int. J. Nonlinear Mech. 36, 1019–1029.
Stephan, K. (1959). Wärmeübergang und druckabfall bei nicht ausgebildeter laminarströmung in rohen und in ebenen spalten. Chem. Ing. Tech. 31, 773–778.
Stevenson, T.N. (1963). A Law-of-the-Wall for Turbulent Boundary Layers with Suction or Injection. Cranfor College, Aero Report 166. (Cited in White, 2006).
Subbotin, V.I., Papovyants, A.K., Kirilov, P.L., and Ivanovskii, N.N. (1962). A study of heat transfer to molten sodium in tubes. At. Energiya (USSR) 13, 380–382.
Svehla, R.A. (1962). Estimated viscosities and thermal conductivities of gases at high temperatures. NASA TR R-132.
Tanaka, H., Muruyama, S., and Hatana, S. (1987). Combined forced and natural convection heat transfer for upward flow in a uniformly heated, vertical pipe, Int. J. Heat Mass Transfer 30, 165–174.
Tang, G.H., Li, Z., He, Y.L., and Tao, W.Q. (2007). Experimental study of compressibility, roughness, and rarefaction influences on microchannel flow. Int. J. Heat Mass Transfer 50, 2282–2295.
Tang, G.Y., Yang, C., Chai, C.K., and Gong, H.Q. (2004). Numerical analysis of the thermal effect on electroosmotic flow, Anal. Chim. Acta 507, 27–37.
Taylor, G.I. (1916). British Advisory Committee, Aero. Rep. Mem., 272, (31), 423–429.
Tiselj, I., Hetsroni, G., Mavko, B., Mosyak, A., Pogrebnyak, E., and Segal, Z. (2004). Effect of axial conduction on the heat transfer in micro-channels. Int. J. Heat Mass Transfer 47, 2551–2565.
Thakre, S.S. and Joshi, J.B. (2002). Momentum, mass and heat transfer in single-phase turbulent flow. Rev. Chem. Eng. 18, 83–293.
Thompson, J.F., Soni, B., and Weatherill, N., eds. (1999). Handbook of Grid Generation, CRC Press.
Tobin, T., Muralidhar, R., Wright, H., and Ramkrishna, D. (1990). Determination of coalescence frequencies in liquid-liquid dispersions: effect of drop size dependence. Chem. Eng. Sci. 45, 3491–3504.
Travin, A., Shur, M., Strelets, M., and Spalart, P.R. (2002). Physical and numerical upgrades in the detached eddy simulation of complex turbulence flows. In Advances in LES of Complex Flows, pp. 239–254. Kluwer Academic.
Tribus, M. and Klein, J. (1953). Forced convection from nonisothermal surfaces. In Heat Transfer: A Symposium, pp. 211–255, Engineering Research Institute, University of Michigan.
Tsouris, C. and Tavlarides, L.L. (1994). Breakage and coalescence models for drops in turbulent dispersions. AIChE J. 40, 395–406.
Tuckerman, D.B. and Pease, R.F.W. (1981). High-performance heat sinking for VLSI. IEEE Electron. Device Lett. EDL-2, 126–129.
Tunc, G. and Bayazitoglu, Y. (2001). Heat transfer in microtubes with viscous dissipation. Int. J. Heat Mass Transfer 44, 2395–2403.
Turner, S.E., Lam, L.C., Faghri, M., and Gregory, O.J. (2004). Experimental investigation of gas flow in microchannels. J. Heat Transfer 126, 753–763.
Tyagi, V.P. (1966). Laminar forced convection of a dissipative fluid in a channel. J. Heat Transfer 88, 161–169.
Turner, S.E., Lam, L.C., Faghri, M., and Gregory, O.J. (2004). Experimental investigation of gas flow in microchannels. J. Heat Transfer 126, 753–763.
Van Driest, E.R. (1956). On turbulent flow near a wall. J. Aerospace Sci. 23, 1007–1011.
Vliet, G.C. (1969). Natural convection local heat transfer on constant heat flux inclined surfaces. J. Heat Transfer 9, 511–516.
Vliet, G.C. and Liu, C.K. (1969). An experimental study of turbulent natural convection boundary layers. J. Heat Transfer 91, 517–531.
Vliet, G.C. and Ross, D. C. (1975). Turbulent, natural convection on upward and downward facing inclined heat flux surfaces, J. Heat Transfer 97, 549–555.
von Karman, T. (1939). The analogy between fluid friction and heat transfer. Trans. ASME 61, 705.
Wang, C. (1946). On the velocity distribution of turbulent flow in pipes and channels of constant cross-section. J. Appl. Mech. 68, A85–A90.
Wang, Z.Q. (1982). Study on correction coefficients of laminar and turbulent entrance region effect in round pipe. Appl. Math. Mech. 3, 433–446.
Weigand, B. (1996). An extract analytical solution for the extended turbulent Graetz problem with Dirichlet wall boundary conditions for pipe and channel flows. Int. J. Heat Mass Transfer 39, 1625–1637.
Weigand, B., Ferguson, J.R., and Crawford, M.E. (1997). An expanded Kays and Crawford turbulent Prandtl number model. Int. J. Heat Mass Transfer 40, 4191–4196.
Weigand, B., Kanzamar, M., and Beer, H. (2001). The extended Graetz problem with piecewise constant wall heat flux for pipe and channel flows. Int. J. Heat Mass Transfer 44, 3941–3952.
White, F.M. (2006). Viscous Fluid Flow, 3rd ed., McGraw-Hill.
Whitaker, S. (1972). Forced convection heat transfer correlations for flow in pipes, past flat plates, single cylinders, spheres, and for flow in packed beds and tube bundles. AIChE J. 18, 361–371.
Wibulswan, P. (1966). Laminar flow heat transfer in non-circular ducts. PhD Thesis, University of London. (Cited in Shah and Bhatti, 1987.)
Wilcox, D.C. (1988). Reassessment of scale – determining equation for advanced turbulence models. AIAA J. 26, 1299–1310.
Wilcox, D.C. (1993). Comparison of two-equation turbulence models for boundary layers with pressure gradient. AIAA J. 31, 1414–1421.
Wilcox, D.C. (1994). Simulation of transition with a two-equation turbulence model. AIAA J. 26, 247–255.
Wilke, C.R. (1950). A viscosity equation for gas mixtures. J. Chem. Phys. 18, 517–519.
Wilke, C.R. and Chang, P. (1954). Correlation of diffusion coefficients in dilute solutions, AIChE J. 1, 264–270.
Wolfshtein, M. (1969). The velocity and temperature distribution in one-dimensional flow with turbulence augmentation and pressure gradient. Int. J. Heat Mass Transfer 12, 301–318.
Wu, P. and Little, W.A. (1983). Measurement of friction factors for the flow of gases in very fine channels used for microminiature Joule–Thompson refrigerators. Cryogenics 23, 273–277.
Yakhot, V. and Orszag, S.A. (1986). Renormalization group analysis of turbulence. I. Basic theory, J. Sci. Comput. 1, 3–57.
Yakhot, V. and Smith, L.M. (1992). The renormalization group, the ε-expansion and derivation of turbulence models. J. Sci. Comput. 7, 35–61.
Yang, R.J., Fu, L.M., and Hwang, C.C. (2001). Electroosmotic entry flow in a microchannel, J. Colloid Interface Sci. 244, 173–179.
Yovanovich, M.M. (1987). On the effect of shape, aspect ratio and orientation upon natural convection from isothermal bodies of complex shape. ASME Heat Transfer Division (HTD) 82, 121–129.
Yu, D., Warrington, R., Barron, R., and Ameal, T. (1995). An experimental and theoretical investigation of fluid flow and heat transfer in microtubes. In Proceedings of the ASME/JSME Thermal Engineering Conference, Vol. 1, pp. 523–530, American Society of Mechanical Engineers.
Yu, S. and Ameel, T.A. (2001). Slip flow heat transfer in rectangular microchannels. Int. J. Heat Mass Transfer 44, 4225–4234.
Yu, S. and Ameel, T.A. (2002). Slip flow convection in isoflux rectangular microchannels. J. Heat Transfer 124, 346–355.
Yu, Z.-T., Fan, L.-W., Hu, Y.-C., and Cen, K.-F. (2010). Prandtl number dependence of laminar natural convection heat transfer in a horizontal cylindrical enclosure with an inner coaxial triangular cylinder. Int. J. Heat Mass Transfer 53, 1333–1340.
Yu, B., Ozoe, H., and Churchill, S.W. (2001). The characteristics of fully-developed turbulent convection in a round tube. Chem. Eng. Sci. 56, 1781–1800.
Yuge, T. (1960). Experiments on heat transfer from spheres including combined natural and forced convection. J. Heat Transfer 82, 214–220.
Zhi-qing, W. (1982). Study on correction coefficients of laminar and turbulent entrance region effects in round pipe. Appl. Math. Mech. 3, 433–446.
Zohar, Y. (2006). Microchannel heat sinks. In Gad El-Hak, M., ed., MEMS Handbook, 2nd ed., Taylor & Francis.
Zukauskas, A.A. (1972). Heat transfer from tubes in cross flow. Adv. Heat Transfer 8, 93–106.

Metrics

Full text views

Total number of HTML views: 0
Total number of PDF views: 0 *
Loading metrics...

Book summary page views

Total views: 0 *
Loading metrics...

* Views captured on Cambridge Core between #date#. This data will be updated every 24 hours.

Usage data cannot currently be displayed.