Development of a methodology for determining heat transfer coefficients under the existence of various boiling modes on a finned wall
Creators
- 1. National Technical University of Ukraine "Igor Sikorsky Kyiv Polytechnic Institute"
- 2. Institute of Engineering Thermophysics of National Academy of Sciences of Ukraine
Description
The object of research is the computational-experimental method of determining and identifying the heat transfer coefficients on the finned wall under the conditions of coexistence of different modes of boiling water that is forced to move. The peculiarity of cooling finned surfaces during boiling is that boiling is carried out on a non-isothermal surface. In this regard, the surface elements – «fin-wall», in the General case, can simultaneously coexist convective heat transfer, bubble, transient and film boiling. One of the problems that needs to be solved is the substantiation and development of a new method for determining the distribution of heat transfer coefficients on the surface of the fin during the coexistence of different boiling regimes on the finned wall.
Most methods of calculating heat transfer on finned surfaces are based on the assumption that the heat transfer coefficient at a given point of the non-isothermal surface is a function of only the temperature pressure between the surface and the liquid at this point. Experimental studies of heat transfer on the finned wall were carried out to test the method of calculation of heat transfer coefficients. The calculation part of the proposed method is based on the numerical method of determining the temperature field in the system «fin-wall» with a constant supply of heat from the smooth wall. Transferring, from both sides, to heat the heat flow – permanently, with given geometric dimensions, cooling, and efficiency of heat conduction material – fins to rotate the heat transfer.
The main stages of realization of computational-experimental technique are given in the work. Unlike most of the known methods for solving inverse problems, the proposed method, based on the use of three-diagonal matrix algorithm, makes it possible not to apply an iterative process to determine the heat transfer coefficients on the surfaces of the fins, which provides a quick result with a higher accuracy
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Development of a methodology for determining heat transfer coefficients under the existence of various boiling modes on a finned wall.pdf
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Additional details
References
- Haley, K. W., Westwater, J. W. (1966). Boiling heat transfer from single fins. Proceedings of the Third International Heat Transfer Conference AJChE – ASME, 3, 245–253. doi: https://doi.org/10.1615/ihtc3.300
- Kovalev, S. A., Smirnova, L. F. (1968). O temperaturnom pole rebra, omyvaemogo kipiaschei zhidkostiu. Teplofizika vysokikh temperatur, 4 (6), 698–701.
- Dulkin, I. N., Rakushina, N. I., Roizen, L. I., Fastovskii, V. G. (1970). Teploobmen pri kipenii vody i freona-113 na neizotermicheskoi poverkhnosti. Inzhenerno-fizicheskii zhurnal, 19 (4), 637–645.
- Rubin, I. R., Dulkin, I. N., Roizen, L. I. (1978). Teploobmen pri kipenii zhidkosti na poverkhnosti koltsevogo rebra postoiannoi tolschiny. Teplofizika vysokikh temperatur, 16 (2), 365–369.
- Roizen, L. I., Evteev, B. N., Dulkin, I. N. (1970). Raschet teploperedachi v priamougolnom rebre. Elektronnaia tekhnika. Seriia I. Elektronika SVCH, 7, 81–84.
- Kern, D., Kraus, A. (1977). Razvitye poverkhnosti teploobmena. Moscow: Energiia, 464.
- Bosyi, V. V., Marynenko, V. I. (1996). Modeliuvannia teplovykh rezhymiv reber pry riznykh umovakh teploobminu. Kyiv: Ministerstvo osvity Ukrainy, 116.
- Zverev, V. G., Nazarenko, V. A., Panko, S. V., Teploukhov, A. V. (2010). Opredelenie parametrov konvektivnogo teploobmena po izmereniiam temperatury materiala. Teplofizika vysokikh temperatur, 48 (5), 779–784.
- Formalev, V. F., Kolesnik, S. A. (2013). A methodology for solving inverse coefficient problems of determining nonlinear thermophysical characteristics of anisotropic bodies. High Temperature, 51 (6), 875–883. doi: http://doi.org/10.7868/s0040364413050062
- Marynenko, V. I., Davydenko, B. V. (2002). Metodyka vyznachennia koefitsiienta teploviddachi na orebrenii stintsi. Enerhetyka: ekonomika, tekhnolohii, ekolohiia, 1, 40–44.
- Marinenko, V. I., Davydenko, B. V. (2002). Opredelenie koeffitsienta teplootdachi na orebrennoi stenke. Energetika i elektrotekhnika, 3, 40–42.