Abstract
The interaction of a superheated surface with a drop impinging upon it is treated in the quasistationary approximation, neglecting dissipative effects.
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V. M. Breitman, “Rapid steady heat removal by streams of gas-liquid dispersoids,” in: Heat and Mass Transfer, Vol. 3 [in Russian], Nauka i Tekhnika, Minsk (1965), pp. 166–173.
H. A. Kearsey, “Steam-water heat transfer-postburnout conditions,” Chem, Progr. Eng.,46, 455–459 (1965).
R. P. Forslund and W. M. Rohsenow, “Dispersed flow film boiling,” Trans. ASME, jK), Ser. C, J. Heat Transfer, 399–407 (1968).
C. Bonacina, G. Comini, and S. del Giudice, “Evaporation from cryogenic liquids sprayed on flat surfaces,” Proc. Fifth Int. Heat Trans. Conf., Tokyo, (1974), pp. 130–134.
S. Viannay and J. C. Moreau, “Cooling by spraying,” Houille Blanche,34, 367–375 (1979).
V. M. Breitman, “Results of experimental study of steady rapid heat removal by a stream of air-water dispersoid,” in: Heat and Mass Transfer, Vol. 3 [in Russian], Nauka 1 Tekhnika, Minsk (1965), pp. 174–183.
C. J. Hoogendoorn and R. den Hond, “Leidenfrost temperature and heat-transfer coefficients for water sprays impinging on a hot surface,” Proc. Fifth Int. Heat Trans. Conf. Tokyo (1974), pp. 135–138.
M. Bieth, F. Moreaux, and G. Beck, “Characteristics of heat transfer between a hot solid and a two-phase jet,” Entropie,71, 42–49 (1976).
L. Ch. Kokorev, A. A. Smirnov, and N. V. Smirnova, “Investigation of interaction of liquid spheroids with a superheated solid surface,” in: Problems of Thermal Physics of Nuclear Reactions, No. 6 [in Russian], Atomizdat, Moscow (1977), pp. 60–64.
E. N. Ganic and W. M. Rohsenow, “Dispersed flow heat transfer,” Int. J. Heat Mass Trans.20, 855–866 (1977).
L. I. Urbanovich, V. A. Goryainov, and V. V. Sevost'yanov, et al., “Investigation of heat transfer by water spray cooling of hot metal surfaces,” Inzh. Fiz. Zh.,39, 315–322 (1980).
L. H. J. Wachters and N. A. J. Westerling, “The heat transfer from a hot wall to impinging water drops in the spheroidal state,” Chem. Eng. Sci.,21, 1047–1056 (1966).
L. H. J. Wachters, J. R. Smulders, L. Vermeulen, and H. C. Kleiweg, “The heat transfer from a hot wall to impinging mist droplets in the spheroidal state,” Chem. Eng. Sci.,21, 1231–1238 (1966).
D. M. Harvey, “The impact and rebound of a small water drop striking a hot surface,” Ph. D. Thesis, McMaster Univ., Canada (1967).
C. O. Pedersen, “An experimental study of the dynamic behavior and heat-transfer characteristics of water droplets impinging upon a heated surface,” Int. J. Heat Mass Transfer,13, 369–381 (1970).
Sh. Nishio and M. Hirata, “Direct contact phenomenon between a liquid droplet and a high temperature solid surface,” Proc. Sixth Int. Heat Trans. Conf. Toronto,1, 245–250 (1978).
Y. Iida and T. Takashima, “Direct-contact heat-transfer characteristics: Evaporation of a drop dropped onto a hot liquid surface,” Int. J. Heat Mass. Transfer,23, 1263–1271 (1980).
M. Seki, H. Kawamura, and K. Sanokawa, “Unsteady state heat transfer of impinging droplets,” Proc. Ninth Japan. Heat Trans. Symp., Tokyo (1972), pp. 459–462.
G. Zigler, Extremum Principles of the Thermodynamics of Irreversible Processes and the Mechanics of a Continuous Medium [in Russian], Mir, Moscow (1966), p. 135.
Yu. A. Buyevich and I. N. Shchelchkova, “Flow of dense suspensions,” Prog. Aerospace Sci.,18, 121–150 (1978).
M. A. Brich, “Interaction of a stream of dispersed liquid with a heated surface,” Inzh. Fiz. Zh.,40, 35–40 (1981).
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Translated from Inzhenerno-Fizicheskii Zhurnal, Vol. 43, No. 6, pp. 945–955, December, 1982.
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Buevich, Y.A., Mankevich, V.N. Impact of an evaporating drop on a heated wall. Journal of Engineering Physics 43, 1362–1369 (1982). https://doi.org/10.1007/BF00824795
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DOI: https://doi.org/10.1007/BF00824795