Abstract
In order to illustrate the influence of thermophysical properties of a solid body on the experimental heat transfer coefficient (EHTC) under conditions where heat transfer intensity is subjected to periodic oscillations, a special model experiment has been designed and carried out. Its purpose was to determine a dependence of the function \(\epsilon (\langle \tilde{h}\rangle )\) for a semi-infinite body under conditions of a time-dependent problem. This dependence has been theoretically computed in (3.56) and shown in Fig. 3.10. The basic element of the experimental rig (Fig. 7.1) was a long brass electrically heated rod (1) thermally insulated on its lateral cylindrical surface, with the end face being periodically washed with a colder water jet from the nozzles (2) of various diameters.
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- 1.
Apparently, for the first time the specified problem with the reference to a problem of liquid film evaporation was theoretically and experimentally investigated by the authors of the work [27]. Later the model of an evaporating liquid film was used by Straub at a research of a problem of vapor bubble dynamics on a solid wall at boiling of a liquid (see survey work [28]).
References
B.B. Mikic, On mechanism on dropwise condensation. Int. J. Heat Mass Transfer 12, 1311–1323 (1969)
P. Griffith, M.S. Lee, The effect of surface thermal properties and finish on dropwise condensation. Int. J. Heat Mass Transfer 10, 697–707 (1967)
D. Wilkins L. Bromley, Dropwise condensation phenomena. AIChE J. 19 839–845 (1973)
R.J. Hannemann, B.B. Mikic, An analysis of the effect of surface thermal conductivity on the rate of heat transfer in dropwise condensation. Int. J. Heat Mass Transfer 19, 1299–1307 (1976)
R.J. Hannemann, B.B. Mikic, An experimental investigation into the effect of surface thermal conductivity on the rate of heat transfer in dropwise condensation. Int. J. Heat Mass Transfer 19, 1309–1317 (1976)
R.J. Hannemann, Condensing surface thickness effects in dropwise condensation. Int. J. Heat Mass Transfer 21, 65–66 (1978)
J.W. Rose, Further aspects of dropwise condensation theory. Int. J. Heat Mass Transfer 10, 697–707 (1967)
J.W. Rose, Dropwise condensation theory and experiment: a review.Proc. Inst. Mech. Eng. A J. Power Ener. 2, 115–128 (2002)
J.W. Rose, Heat-transfer coefficients, Wilson plots and accuracy of thermal measurements. Exp Therm Fluid Sci 28 3–12 (2003)
K. Stephan, Heat Transfer in Condensation and Boiling (Springer, Berlin, 1992)
D.A. Labuntsov, Physical Principles of Energetics. Selected Papers (Power Engineering Institute, Moscow, 2000) (in Russian)
H. Schlichting, K. Gersten, Grenzschicht-Theorie (Springer, Berlin, 1997)
I.L. Pioro, W. Rohsenow, S.S. Doerffer, Nucleate pool-boiling heat transfer. I: review of parametric effects of boiling surface Int. J. Heat Mass Transfer 47, 5033–5044 (2004)
D. Kenning, I. Golobi, H. Xing, M. Baselj, V. Lojk, J. von Hardenberg, Mechanistic models for pool nucleate boiling heat transfer: input and validation. Int. J. Heat Mass Transfer 42, 511–527 (2006)
V.K. Dhir, Mechanistic prediction of nucleate boiling heat transfer–achievable or a hopeless task? ASME J. Heat Transfer 123, 1–12 (2006)
V.K. Dhir, Numerical simulations of pool-boiling heat transfer. AIChE J. 47, 813–834 (2001)
B. Yu, P. Cheng, A fractal model for nucleate pool boiling heat transfer. ASME J. Heat Transfer 124, 1117–1124 (2002)
B.B. Mandelbrot, The Fractal Geometry of Nature (W.H. Freeman New York, 1982)
R.A. Eanshaw (ed.), Application of Fractals and Chaos (Springer, Berlin, 1993)
T. Cebeci, Turbulence Models and Their Application (Springer, Berlin, 2003)
K. Stephan Mechanismus und modellgesetz des wärmeübergangs bei der blasenverdampfung. Chem. Ing. Tech. 35(11) 775–784 (1963)
D. Gorenflo, Behältersieden (Sieden bei freier Konvektion). VDI – Wärmeatlas, Hab (Springer, Berlin, 2002)
Y. Qi, J.F. Klausner, Comparison of nucleation site density for pool boiling and gas nucleation. ASME J. Heat Transfer 128, 13–20 (2006)
R.J. Benjamin, A.R. Balakrishnan, Nucleation site density in pool boiling of saturated pure liquids: effect of surface microroughness and surface and liquid physical properties. Exp. Thermal Fluid Sci 15, 32–42 (1997)
F.S. Sherman, Viscous Flow (McGraw-Hill, New York, 1990)
J.W. Rose, Surface tension effects and enhancement of condensation heat transfer. Trans IChemE A Chem. Eng. Res. Design 82, 419–429 (2004)
P.C. Wayner, Y.K. Kao, L.V. LaCroix, The interline heat transfer coefficient on an evaporating wetting film. Int. J. Heat Mass Transfer 19, 487–492 (1976)
J. Straub, Boiling heat transfer and bubble dynamics in microgravity. Adv. Heat Transfer 35, 57–172 (2001)
A.C. Dudkevich, F.D. Akhmedov, Experimental study of influence of thermophysical properties of heating surface on boiling of nitrogen at elevated pressures. Works Moscow Power Eng Instit. 198, 41–47 (1974) (in Russian)
Y.A. Kirichenko, K.V. Rusanov, E.G. Tyurina, Effect of pressure on heat exchange in nitrogen boiling under conditions of free motion in an annular channel. J. Eng. Phys. Thermophys. 49, 1005–1010 (1985)
A.K. Gorodov, O.N. Kabankov, Y.K. Martynov, V.V. Yagov, Effect of material and of the thickness of the heating surface on the heat transfer rate in boiling of water and ethanol at subatmospheric pressures. J. Heat Transfer Sov. Res. 11(3), 44–52 (1979)
Y.B. Zudin, Analog of the Rayleigh equation for the problem of bubble dynamics in a tube. J. Eng. Phys. Thermophys. 63, 672–675 (1992)
Y.B. Zudin, The calculation of parameters of the evaporating meniscus a thin liquid film. High Temp. 31, 714–716 (1993)
Y.B. Zudin, The use of the model of evaporating macrolayer for determining the characteristics of nucleate boiling High Temp. 35, 565–571 (1997)
Y.B. Zudin, Calculation of critical thermal loads under extreme intensities of mass forces. Heat Transfer Res. 28, 481–483 (1997)
Y.B. Zudin, Influence of the coefficient of thermal activity of a wall on heat transfer in transient boiling. J. Eng. Phys. Thermophys. 71, 696–698 (1997)
Y.B. Zudin, Law of vapor-bubble growth in a tube in the region of low pressures. J. Eng. Phys. Thermophys. 70, 714–717 (1997)
Y.B. Zudin, The distance between nucleate boiling sites. High Temp. 36, 662–663 (1998)
Y.B. Zudin, Calculation of the surface density of nucleation sites in nucleate boiling of a liquid. J. Eng. Phys. Thermophys. 71, 178–183 (1998)
Y.B. Zudin, Boiling of liquid in the cell of a jet printer. J. Eng. Phys. Thermophys. 71, 217–220 (1998)
Y.B. Zudin, Burn-out of a liquid under conditions of natural convection. J. Eng. Phys. Thermophys. 72, 50–53 (1999)
Y.B. Zudin, Wall non-isothermicity effect on the heat exchange in jet reflux. J. Eng. Phys. Thermophys. 72, 309–312 (1999)
Y.B. Zudin, Model of heat transfer in bubble boiling. J. Eng. Phys. Thermophys. 72, 438–444 (1999)
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Zudin, Y.B. (2012). Practical Applications of the Theory. In: Theory of Periodic Conjugate Heat Transfer. Mathematical Engineering, vol 5. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-21421-9_7
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