A brief review of research on the intensification of heat transfer during boiling using modification of the heating surface, dedicated to the 90th anniversary of the birth of Vladimir Mikhailovich Zhukov

Аuthors

Kuzma-Kichta Y. A.^1*, Lenkov V. A.², Vasil’ev N. V.^2**

1. National Research University “Moscow Power Engineering Institute”, 14, Krasnokazarmennaya str., Moscow, 111250 Russia
2. Joint Institute for High Temperatures of the Russian Academy of Sciences, 13, Izhorskaya str., Moscow, 125412, Russia

*e-mail: kuzma@itf.mpei.ac.ru
**e-mail: nikvikvas@mail.ru

Abstract

The article is dedicated to the memory (90th anniversary of birth) of the outstanding scientist-thermophysicist, laureate of the USSR State Prize, candidate of technical sciences, senior researcher Vladimir Mikhailovich Zhukov, who for 20 years was the deputy head of the heat transfer department of the JIHT RAS. Vladimir Mikhailovich Zhukov made a significant contribution to the study of heat transfer during phase transformations of various coolants from liquid metal to cryogenic. This article presents the results of research in the last period of his activity, devoted to the study of the effect of surface modification on the intensification of heat transfer during boiling of various liquids (nitrogen, water, freon R113). The presented results were obtained on surfaces modified by applying dimples, coatings of nanoparticles obtained by boiling a nanofluid and created by the microarc oxidation (MAO) method. The studies were conducted with non-stationary cooling of solid spheres and cylinders in the range of temperature differences covering bubble, transitional and film boiling modes at atmospheric pressure under free convection conditions. It was shown that the application of micro- and nanoporous coatings of the types under consideration leads to a significant reduction in the cooling time of spheres heated above the Leidenfrost temperature, an increase in the heat transfer coefficients, the second critical heat flux density and the corresponding temperature difference during the boiling of nitrogen, water and freon R113. During his long and fruitful scientific life, V.M. Zhukov studied the boiling of a wide range of liquids - sodium, helium, nitrogen, various freons, water on surfaces with relief on the macro-, micro- and nanoscales under conditions of free and forced convection, as well as the boiling of cryogenic liquids in the field of action of centrifugal forces. He managed to discover and explain the features of unstable boiling of liquid metal and these unique results were reflected in many domestic and foreign monographs. Overcoming multiple experimental difficulties tempered V.M. Zhukov and allowed him to develop a strong and purposeful character. Colleagues noted his outstanding pedagogical abilities, intolerance to manifestations of lack of will in assistants. His scientific supervisor was the head of the heat exchange department of the Institute of Heat Transfer of the USSR Academy of Sciences, Corresponding Member of the USSR Academy of Sciences Petukhov B.S., and his closest associate was an outstanding specialist in the field of heat exchange during boiling, professor, Doctor of Technical Sciences Sergei Alekseevich Kovalev. As a feature of V.M. As a researcher, it should be noted that in his works Zhukov paid special attention to the novelty of the method of heat exchange intensification, its potential practical application and the reliability of the results obtained.

Keywords:

boiling, non-stationary cooling, heat transfer enhancement, surface modification, microarc oxidation, nanofluid

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