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Университетский научный журнал №8, 2014 (физико-математические, технические и биологические науки)

Теория интенсифицированного теплообмена в областях присоединения потока при турбулентном течении в трубах с турбулизаторами

И. Е. Лобанов, Л. М. Штейн
Цена: 50 руб.
 В работе рассматриваются аспекты теоретической модели интенсифицированного теплообмена в областях присоединения потока
при турбулентном течении в каналах с турбулизаторами на базе уравнения баланса турбулентной пульсационной энергии для открытых впадин и для относительно больших и малых высот турбулизаторов, что может
использоваться в теплообменных аппаратах с интенсифицированным теплообменом для металлургического производства.

Ключевые слова:
теория теплообмена, моделирование теплообмена, присоединение потока, уравнение баланса; турбулентный поток, пульса-
ционная энергия, интенсификация теплообмена.

REFERENCES
1. Effective Surfaces of Heat Exchange / Kalinin, E., Dreitser, G., Kopp, I., et al.
1998, Мoscow: Energoatomizdat. 408 p.
2. Lobanov, I. Maximum Isothermal Heat Exchange Modeling during Turbulent
Flow in Channels due to Flow Turbulization on the Basis of Balance Equation of Turbulent Pulsating Energy. In Problems of Gas Dynamics and Heat Exchange in Energy Plants: Papers of 15 Seminar of Young Scientists and Specialists under the supervision of the academician of the Russian Academy of Science A. Leontiev. 2005, Moscow: Moscow Energy Institute. Vol. 1. Pp. 99–102.
3. Lobanov, I. Maximum Heat Exchange during Turbulent Flow in Channels due
to Flow Turbulizationon the Basis of Balance Equation of Turbulent Pulsating Energy.
In Papers of the Fourth Russian National Conference on Heat Exchange. In 8 volumes.
Vol. 2. Forced convection of one phase liquid. 2002, Мoscow. Pp. 191–194.
4. Shlikhting, G. Theory of Boundary Layer. 1974, Мoscow: Nauka. 712 p.
5. Webb, R.L., Eckept, E.R. & Goldstein, R.J. Heat Transfer and friction in tubes
with Repeated–Rib Ronghness. International Journal of Heat and Mass Transfer, 1971, vol. 14, No. 4, 601–617.
6. Kutateladze, S. Fundamentals of Heat Exchange Theory. 1979, Мoscow: Atomizdat. 416 p.
7. Migai, V. Increased Effi ciency of Modern Heat Exchangers. 1980, Leningrad:
Energia. Leningrad branch. 144 p.
8. Migai, V. Heat Exchange Equipment Modeling. 1987, Leningrad: Energoatomizdat. Leningrad branch. 263 p.
9. Lobanov, I., Myakochin, A., Nizovitin, A. Intensi fi ed Heat Exchange Modeling
during Turbulent Flow in Pipes with Turbulators on the Basis of Balance Equation
of Turbulent Pulsating Energy. Bulletin of Moscow Aviation Institute, 2007, vol. 14,
No. 4, 13–22.
10. Lobanov, I., Paramonov, N. Mathematical Modeling of Heat Exchange in Pipes
with Turbulators during Turbulent Flow on the Basis of Balance Equation of Turbulent
Pulsating Energy. In Papers of the Fifth Russian National Conference on Heat Exchange. In 8 volumes. Vol. 2. Forced convection of one phase liquid. 2010, Мoscow: Moscow Energy Institute. Pp. 162–165.
11. Lobanov, I. Application of Balance Equation of Turbulent Pulsating Energy for
Mathematic Modeling of Intensi fi ed Heat Exchange during Turbulent Flow in Pipes
with Turbulators. Aerospace engineering, 2011, 5, 19–24.
12. Lobanov, I. Theory of Intensi fi ed Heat Exchange during Turbulent Flow in
Pipes with Turbulators on the basis of Balance Equation of Turbulent Pulsating Energy. In Materials of the 9th International Conference on Non-Equilibrium Processes in Jet
Nozzles and Flows (NPNJ’2012), 25–31 May 2012, Alushta. 2012, Мoscow: Publisher
of Moscow Aviation Institute. Pp. 245–247.
13. Lobanov, I. Theory of Intensi fi ed Heat Exchange during Turbulent Flow in
Pipes with Turbulators on the Basis of Balance Equation of Turbulent Pulsating Energy.
Industry aspects of technical sciences, 2012, 5, 7–14.
14. Praudte, L. Über ein neues Formelsystem für die ausgebildete Turbulenz. In
Nachrichten von der Akademie der Wissenschaften in Göttingen. 1945, Göttingen:
Mathphys. P. 6.
15. Spolding, D.B. Heat transfer for turbulent separated flows. Journal Fluid
Mechanics, 1967, vol. 27, pt. 1, 97–109.
16. Guinsburg, I. Theory of Resistance and Heat Transfer. 1970, Leningrad: Leningrad State University. 375 p.
17. Lobanov, I., Stein, L. Prospective Heat Exchange Devices with Intensi fi ed Heat
Exchange for Metallurgy (General theory of intensi fi ed heat exchange for heat exchange devices used in modern metallurgy.) In 4 volumes. Vol. 4. Special aspects of mathematical modeling of fl uid dynamics, heat exchange and heat transfer in heat exchange devices with intensi fi ed heat exchange. 2011, Moscow: MGAK-HiS. 343 p.
18. Kutateladze, S., Leontiev, A. Heat and Mass Exchange and Friction in Turbulent
Boundary Layer. 1985, Мoscow: Energoatomizdat. 320 p.
19. Townsend, A. The Structure of Turbulent Flow with Transverse Shear. 1959,
Foreign literature publisher. 399 p.
20. Richardson, P.D. Heat and mass transfer in turbulent separated fl ows. Chemical
Engineering Science, 1963, vol. 18, p. 149.
21. Migai, V. To the Theory of Heat Exchange in Turbulent Flow with Break
Down. Bulletin of the Academy of Science of the USSR. Fluid mechanics, 1976, 2,
170–171.
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