Экспериментальное исследование гидродинамики пленок жидкости с контактной линией

Список литературы

1. Алсксеенко С.В., Антипин В. А., Гузанов В. В., Маркович Д. М., Харламов С. М., 2005. Стационарные уединенные трехмерные волны на вертикально стекающей пленке жидкости // Доклады Академии Наук. Т. 405, № 2, — С. 193 — 195.
2. Алексеенко С.В., Бобылев А. В., Евсеев А. Р., Маркович Д. М., Карстен В. М., Тарасов Б. В., 2003. Измерение толщины пленки жидкости волоконно-оптическим датчиком //ПТЭ. -№ 2, С. 130−134.
3. Алексеенко С.В., Накоряков В. Е., Покусаев Б. Г., Христофоров В. В., 1973. Трение при стекании плёнки по вертикальной стенке // Инж. -физ. журн. Т. 24, № 5. -С. 824−830.
4. Зайцев Д.В., Кабов О. А., Чеверда В. В., Буфетов Н. С., 2004. Влияние волнообразования и краевого угла смачивания на термокапиллярпый разрыв стекающей пленки жидкости // Теплофизика высоких температур. Т. 42, № 3, — С. 449¹⁵⁵.
5. Максутов Д.Д., 1934. Теневые методы исследования оптических систем. М.- Л.- ОНТИ.
6. Моисеев В.В., Потапов В. Т., 1988. Исследование стабильности волоконно-оптического датчика отражательного типа // Радиотехника. № 8, — С. 37¹⁰.
7. Капица П.Л., 1948. Волновое течение тонких слоев вязкой жидкости // ЖЭТФ. -Т. 18, вып. 1,-С. 3−28.
8. Капица П.Л., Капица С. П., 1949. Волновое течение тонких слоев вязкой жидкости//ЖЭТФ. Т. 19, вып. 2.-С. 105−120.
9. Накоряков В.Е., Покусаев Б. Г., Алексеенко С. В., Орлов В. В., 1977. Мгновенный профиль скорости в волновой плёнке жидкости // Инж. -физ. журн. Т. 33, № 3. -С. 399¹⁰⁵.
10. Накоряков В.Е., Бурдуков А. П., Кашинский О. Н., Гешев П. И., 1986. Электродиффузионный метод исследования локальной структуры турбулентных течений. Новосибирск: ИТ СО АН СССР.
11. Окоси Т., Окамото К., Оцу М., Нисихара X., Кюма К., Хататэ К., 1990. Волоконно-оптические датчики. Под ред. Т. Окоси: Перевод с японского Г. Н. Горбунова, (Л.: Энергоатомиздат. Ленингр. отд-ние).
12. Покусаев Б.Г., Малков В.А, Алексеенко С. В., Беседин С. М., 1978. Экспериментальное исследование работы датчика проводимости в случае волнового течения плёнки жидкости: Отчёт ИТ СО АН СССР. Новосибирск.
13. Семенов П.А. 1944. Течение жидкости в тонких слоях // ЖТФ. Т. 14, № 7−8. -С. 427¹³⁷.14.. Шпигель Л., Майер В., 1994. Характеристики работы насадки «Меллапак» различных типов // Химическое и нефтяное машиностроение. — № 3. С. 16.
14. Adomeit P., Renz U., 2000. Hydrodynamics of three-dimensional waves in laminar falling films // Int. J. Multiphase Flow. Vol. 26. — P. 1183−1208.
15. Alekseenko S.V., Antipin V.A., Bobylev A.V., Markovich D.M., 2007. Application of PIV to velocity measurements in a liquid film flowing down an inclined cylinder // Exp. Fluids. Vol. 43, № 2 — 3. — P. 197−207.
16. Alekseenko S.V., Antipin V.A., Guzanov V.V., Kharlamov S.M., Markovich D.M., 2005. Three-dimensional solitary waves on falling liquid film at low Reynolds numbers // Phys. Fluids. Vol. 17, 121 704.
17. Alekseenko S.V., Antipin V.A., Kulikov A.S., Markovich D.M., 1999. Rivulet flow of liquids with different physical properties // Proc. of 2nd Int. Symp. on Two-phase Flow Modelling and Experimentation, Pisa, Italy.
18. Alekseenko S.V., Geshev P.I., Kuibin P.A., 1995. Liquid flow on inclined cylinders // Proc. of the 2nd Int. Conf. on Multiphase Flow, Kyoto, Japan.
19. Alekseenko S.V., Markovich D.M., Evseev A.R., el al., 2003. Measurement of the liquid film thickness by the fiber-optic sensor // Instr. Exp. Tech. Vol. 46, № 2, — P. 260−264.
20. Alekseenko S.V., Markovich D.M., Shtork S.I., 1996a. Wave flow of rivulets on the outer surface of an inclined cylinder // Phys. Fluids. Vol. 8. — P. 3288−3299.
21. Alekseenko S.V., Nakoryakov V.E., Pokusaev B.G., 1985. Wave formation on vertically liquid film // AIChE J. Vol. 32. — P. 1446−1460.
22. Alekseenko S.V., Nakoryakov V.E., Pokusaev B.G., 1994. Wave flow of liquid films. Begell House, New York.
23. Alekseenko S.V., Nakoryakov V.E., Pokusaev B.G., 1996b. Wave effect on the transfer processes in liquid films // Chem. Eng. Comm. Vol. 141(142). — P. 359−385.
24. Behrens M., Saraber P.P., Yamsen H., Olujic Z., 2001. Performance characteristics of a monolith-likc structured packing // Chem. Biochem. Eng. Q. Vol. 15, № 2. — P. 4957.
25. Benjamin, T.B., 1957. Wave formation in laminar flow down an inclined plane // J. Fluid Mech. Vol. 2. — P. 554−574.
26. Binnie A.M., 1957. Experiments on the onset of wave formation on a film of water flowing down a vertical plate // J. Fluid Mech. Vol. 2. — P. 551−553.
27. Binnie A.M., 1959. Instability in a slightly inclined water channel // J. Fluid Mech. -Vol. 5.-P. 561−570.
28. Birnir В., Mertens K., Putkaradze V., Vorobieff P., 2008. Meandering fluid streams in the presence of flow-rate fluctuations // Phys. Review Letters. Vol. 101. — P. 114 501.
29. Brunazzi E., Paglianti A., 1997. Mechanistic pressure drop model for columns containing structured packings // AIChE J. Vol. 43. — P. 317−327.
30. Carey V.P., 1992. Liquid-vapor phase-change phenomena // Hemisphere Publ. Co., London. -P. 95.
31. Carlos A., Perazzo A., Gratton J., 2004. Navier-Stokes solutions for parallel flow in rivulets on an inclined plane // J. Fluid Mech. Vol. 507, — P. 367−379.
32. Chang H.-C., Demekhin E.A., 2002. Complex wave dynamics on thin films. Elsevier, Amsterdam.
33. Chu K.J., Dukler A.E., 1974. Studies of the substrate and its wave structure // AIChE J. Vol. 20, № 4. — P. 695−706.
34. Chu K.J., Dukler A.E., 1975. Structure of large waves and their resistance to gas films // AIChE J. Vol. 21, № 3. — P. 583−593.
35. Cohen L.S., Hanratty T.J., 1968. Effect of waves at a gas-liquid interface on a turbulent air flow // J. Fluid Mech. Vol. 31. — P. 467−479.
36. Craik A.D.D., 1966. Wind generated waves in thin liquid films // J. Fluid Mech. -Vol. 26.-P. 369−392.
37. Daerr A., Le Grand N., Limat L., Stone H.A., 2003. Drops sliding along an inclinedthplane: Experiments versus 3D hydrodynamical model // Proc. of the 5 European Coating Symp. Polytype converting, Friburg, 2004, edited by P. M. Schweizer.
38. Dani O., Ghezzehei T.A., 2000. Dripping into subterranean cavities from unsaturated fractures under evaporative conditions // Water Resources Research. Vol. 36, № 2. -P.381−393.
39. Eres M.H., Schwartz L.W., Roy R.V., 2000. Fingering phenomena for driven coating films. Phys. Fluids. Vol. 12, № 6. — P. 1278−1295.97
40. Geshev P.I., Kuibin P.A., 1995. Waves on rivulet flow along inclined cylinder // Proc. of the 9lh International Conference on Numerical Methods in Laminar and Turbulent Flow, Atlanta, USA.
41. Goshawk J.A., Waters N.D., Staples E.J., Rcnnie G.K., 1996. The use of interferome-try of measure flow characteristics of an oscillating draining film // J. of Non-Newtonian Fluid Mech. Vol. 64, № 1. — P. 1−17.
42. Grand-Piteira N. Le" Daerr A., Limat L., 2006. Meandering rivulets on a plane: a simple balance between inertia and capillarity? // Phys. Rev. Lett. Vol. 96. — P. 254 503.
43. Guguchkin V.V., Demekhin E.A., Kalugin G.N., Markovich E.E., Pikin V.G., 1975. Wavy motion of liquid films flowing concurrently with a gas stream // Fluid Dynamics. -Vol. 10, № 4.-P. 689−692.
44. Gunn D.I., Al-Saffar H.B.S., 1993. Liquid distribution in packed column // Chem. Eng. Sci. Vol. 48, № 22. — P. 3845−3854.
45. Hanratty T.J., Engen J.M., 1957. Interaction between a turbulent air stream and moving water surface // AIChE J. Vol. 3. — P. 299−304.
46. Hirt C.W., 1998. Simulating the wetting and drying of shallow flows // Flow Science. -TN54.
47. Hewitt G.F., King R.D., Lovegrove P.C., 1964a. Liquid film and pressure drop studies //Chem. Proc. Eng. -Vol. 45. P. 191.
48. Holland D., Duffy B.R., Wilson S.K., 2001. Thermocapillary effects on a thin viscous rivulet draining steadily down a uniformly heated or cooled slowly varying substrate // J. Fluid Mech.-Vol. 441,-P. 195−221.
49. Inada F., Drew D.A., Lahey R.T. Jr., 2004. An analytical study on interfacial wave structure between the liquid film and gas core in a vertical tube // Int. J. Multiphase Flow. Vol. 30. — P. 827−851.
50. Indeikina A., Veretennikov I., Chang H.C., 1997. Drop fall-off from pendent rivulets // J. Fluid Mech. Vol. 338. — P. 173−201.
51. Ishigai S., Nakanisi S., Koizumi Т., Oyabi Z., 1972. Hydrodynamics and heat transfer of vertical falling liquid films // Bull. JSME. Vol. 15, № 83. — P. 594−602.
52. Jensen A., Pedersen G.K., 2004. Optimization of acceleration measurements using PIV // Measurement Science Technology. Vol. 15. — P. 2275−2283.
53. Johnson M.F.G., Schluter R.A., Bankoff S.G., 1997. Fluorescent imaging system for global measurement of liquid film thickness and dynamic contact angle in free surface flows // Rev. Sci. Instrum. Vol. 68, №. 11. — P. 4097−4102.
54. Johnson M.F.G., Schluter R.A., Miksis M.J., Bankoff S.G., 1999. Experimental study of rivulet formation on an inclined plate by fluorescent imaging // J. Fluid Mech. Vol. 394.-P. 339−354.
55. Kabov O.A., Gatapova E.Ya., Zaitsev D.V., 2008. Cooling technique based on evaporation of thin and ultra thin liquid films // 11th Int. Conf. on Thermal and Thermomech. Phenomena in Electronic Systems, Orlando, Florida.
56. Kalbassi M.A., Zone I., 2002. Large industrial-scale demonstration of structured packing distillation system // Int. Cong, on Process Industries, Achem, America, Mexico City.
57. Kim H., Kim J., Kang B.H., 2004. Meandering instability of a rivulet // J. Fluid. Mech. Vol. 498. — P. 245−256.
58. Kister H.Z., 1992. Distillation design. McGrew-Hill, NY.62. ' Krohn D.A., 1986. Fiber optic and laser sensor IV, SPIE. Vol. 718. — P. 2−11.
59. Kuibin P.A., 1996. An asymptotic description of the rivulet flow along an inclined cylinder // J. Eng. Thermophys. Vol. 6. — P. 33—45.
60. Lilleleht L.U., Hanratty T.J., 1961a. Relation of interfacial shear stress to the wave height for concurrent air-water flow // AIChE J. Vol. 7. — P. 548−560.
61. Lilleleht L.U., Hanratty T.J., 1961b. Measurement of interfacial structure for co-current air-water flow // J. Fluid Mech. Vol. 11. — P. 65−81.
62. Liu J., Gollub J.P., 1994. Solitary wave dynamics of film flows // Phys. Fluids. Vol. 6, № 5.-P. 1702−1712.
63. Liu J., Paul J. D., Gollub J.P., 1993. Measurement of the primary instabilities of film flow // J. Fluid Mech. Vol. 250. — P. 69−101.
64. Liu J., Schneider J.В., Gollub J.P., 1995. Three-dimensional instabilities of film flow // Phys. Fluids. Vol.7, № 1. — P. 55−67.
65. Marchot P., Toye D., Pclsser A-M. et al., 2001. Liquid distribution images on structured packing by X-ray computed tomography // AIChE J. Vol. 47. — P. 1471−1476.
66. Marshall B.W., Tiederman W.G., 1972. A capacitance depth gauge for thin liquid films // Rev. Sci. Instrum. Vol.43. — P. 344−547.
67. Marshall E., 1975. Das messen charakteristischer eigenschaften von rieselfilmen // Chem. Ing. Tech. Vol. 47, № 21. — P. 879−882.
68. Marshall J.S., Ettema R., 2004. Rivulet dynamics with variable gravity and wind shear // Final report to NASA office of biological and physical research. 98 NRA Grant NAG3−2368. IIHR Technical Report № 440.
69. Meier W., Hunkeler R., Stocker W.D., 1979, Sulzer Mellapak-eine neue, Geordnete packung fur stoffaustausch-apparate // Chem. Ing. Tech. Vol. 51. — P. 119.
70. Mitchell J.E., Hanratty T.J., 1966. A study of turbulence at a wall using an electrochemical wall shear stress meter // J. Fluid Mech. Vol. 26. — P. 199−221.
71. Miyara A., 1999. Numerical analysis of flow dynamics and heat transfer of falling liquid films with interfacial waves // Int. J. Heat Mass Transfer, Vol. 35. — P. 298 306.
72. Miyara A., 2000. Numerical analysis on heat transfer enhancement by waves on falling liquid film // J. .Thermal Science. Vol. 9, № 3. — P. 236−242.
73. Moran K., Inumaru J., Kawaji M., 2002. Instantaneous hydrodynamics of a laminar wavy liquid film // Int. J. Multiphase Flow. Vol. 28. — P. 731−755.
74. Myers T.G., Liang H.X., Wetton В., 2004. The stability and flow of a rivulet driven by interfacial shear and gravity // Int. J. Nonlinear Mechanics. Vol. 39. — P. 12 391 249.
75. Nakaya C., 1989. Waves on a viscous fluid film down a vertical wall // Phys. Fluids. -Vol. 1, № 7. P. 1143−1154.
76. Nakoryakov, V.E., Pokusaev B.G., Alekseenko, S.V., 1976. Stationary two-dimensional rolling waves on a vertical film of fluid // Inzh.-Fiz. Zh. Vol. 30, №. 5. — P.780−785.
77. Nakoryakov V.E., Pokusaev E.G., Alekseenko S.V., Orlov V.V., 1977. Instantaneous velocity profile in a wavy liquid film // Inzh.-Fiz. Zh. Vol. 33, № 3. — P. 399⁴⁰⁵.
78. Nakoryakov V.E., Pokusaev E.G., Khristoforov V.V., Alekseenko S.V., 1974. Experimental investigation of film on vertical wall // Inzh.-Fiz. Zh. — Vol. 27, №. 3. P. 397−401.
79. Nakoryakov V.E., Pokusaev E.G., Radev K.B., 1987. Waves and their effect on con-vective gas diffusion in falling films // Zhurn. Mekh. Tekh. Fiz. №. 3. P. 95−104.
80. Nicolaiewsky E.M.A., Fair J.R., 1999a. Liquid flow over textured surfaces. I. Contact Angles // Ind. Eng. Chem. Res. Vol. 38. — P. 284−291.
81. Nicolaiewsky E.M.A., Tavares F.W., Rajagopal K., Fair J.R., 1999b. Liquid film flow and area generation in structured packing columns // Powder Tech. Vol. 104. — P. 8494.
82. Nozhat W.M., 1997. Measurement of liquid-film thickness by laser interferometry // Appl. Opt. Vol. 36. — P. 7864−7869.
83. Nusselt W., 1916. Die oberflachenkondensation des wasserdampfes // Zeitschrift VDI. Bd 60. — P. 541−546.
84. Olujic Z., Kamerbeek A.B. de Graauw J., 1999. A corrugation geometry based model for efficiency of structured distillation packing // Chem. Eng. Processing. Vol. 38. — P. 683−695.
85. Olujic Z., Seibert A.F. Fair J.R., 2000. Influence of corrugation geometry on the performance of structured packings: an experimental study // Chem. Eng. Processing. -Vol. 39.-P. 335−342.
86. Pavlenko A.N., Pecherkin N.I., Chekhovich V.Yu., et al., 2005. Large industrial-scale model of structured packing distillation column // J. Eng. Thermophysics. Vol. 13, № 1.-P. 1−18.
87. Pavlenko A.N., Pecherkin N.I., Zhukov V.E., et al., 2006. Separation of mixtures and liquid distribution over the structured packing of the large-scale model of a distillation column // Theoretical Foundations of Chem. Eng. Vol. 40, № 4. — P. 329−338.
88. Park C.D., Nosoko Т., 2003. Three-dimensional wave dynamics on a falling film and associated mass transfer // AlChE J. Vol. 49, № 11. — P. 2715−2727.
89. Portalsky S., 1964. Velocities in film flow of liquids on vertical plates // Chem. Eng. Sci. Vol. 19.-P. 575−582.
90. Portalsky S., Clegg A.J., 1972. An experimental study of falling liquid films // Chem. Eng. Sci.-Vol. 27.-P. 1257−1265.
91. Raffel M., Willert C., Kompenhans J., 1998. Particle image velocimetry. A practical guide. Springer.
92. Rastaturin A.- Demekhin E.- Kalaidin E.- 2006. Optimal regimes of heat-mass transfer in a falling film // J. Non-equilibrium Thermodyn. Vol. 31, № 1. — P. 1−10.
93. Rossum J.J., 1959. Experimental investigation of horizontal film flow // Chem. Eng. Sci.-Vol. 11.-P. 35−52.
94. Roy R.P., Jain S., 1989. A study of thin water film flow down an inclined plate without and with countercurrent air flow // Exp. Fluids. Vol. 7. — P. 318−328.
95. Schmuki P., Laso M., 1990. On the stability of rivulet flow // J. Fluid Mech. Vol. 215.-P. 125−143.
96. Seno K., Ishioka Т., Harata A., Hatano Y., 2001. Photoionization of rhodamine dyes adsorbed at the aqueous solution surfaces investigated by synchrotron radiation // Anal. Sci.-Vol. 17.-P. il 177—i 1179.
97. Shedd T.A., Newell T.A., 2001. The development of thin film PIV for the study of the liquid film distribute’ion in annular flow // Proc. of 4lh Int. Conf. on Multiphase Flow, New Orleans, Louisiana, USA.
98. Smith T.N., Tait R.W.F., 1966. Interfacial shear stress and momentum transfer in horizontal gas-liquid flow // Chem. Eng. Sci. Vol. 21. — P. 63−73.
99. Snoeijer J.H., Rio E., Le Grand N., Limat L., 2005. Self-similar flow and contact line geometry at the rear of cornered drops // Phys. Fluids. Vol. 17. — P. 72 101−72 112.
100. Spiegel L., Meier W., 2002. Distillation column with structured packing in the next decade // Proc. of 7th Int. Conf. on Distillation and Absorption, Baden-Baden, Germany.
101. Stichlmair J.L., Fair J.R., 1998. Distillation, principles and practices. Wiley-VCH, NY.
102. Strigle R.F. Jr., 1994. Packed tower design and applications: Random and structured packing. Gulf Publ. Co. Houston, TX.
103. Stainthorp F.P., Allen J.M., 1965. The development of ripples on the surface of liquid film flowing inside a vertical tube // Trans. Inst. Chen Eng. Vol. 43. — P. T85-T91.
104. Stainthorp F.P., Batt R.S.W., 1967. The effect of co-current and counter-current air flow on the wave properties of falling liquid films // Trans. Inst. Chem. Eng. Vol. 45. -P. T372-T382.
105. Tailby S.R., Portalski S., 1960. The hydrodynamics of liquids films flowing on vertical surface // Trans. Instn. Chem. Eng. Vol. 38. — P. 324−330.
106. Tihon J., Tovchigrechko V., Sobolik V., Wein O., 2003. Electrodiffiision detection of the near-wall flow reversal in liquid films at the regime of solitary waves // J. Applied Electrochem. Vol. 33. — P. 577−587.
107. Trifonov Yu.Ya., 2004. Viscous film flowing over the corrugated surfaces // J. Applied Mech. Tech. Phys. Vol. 45, № 3 — P. 389−400.
108. Trifonov Yu.Ya., 2007. Stability of a viscous liquid film flowing down a periodic surface//Int. J. Multiphase flow.-Vol. 33, № 11.-P. 1186−1204.
109. Towell G.D., Rothfeld L.B., 1966. Hydrodynamics of rivulet flow // AIChE J. Vol. 12.-P. 972−980.
110. Vazquez-Una G., Chenlo-Romero F., Sanchez-Barral M., Perez-Munuzuri V., 2000. Mass transfer enhancement due to surface wave formation at a horizontal gas-liquid interface//Chem. Eng. Sci. Vol. 55, № 23.-P. 5851−5856.
111. Vlachogiannis M., Bontozoglou V., 2002. Experiments on laminar film flow along a periodic wall // J. Fluid Mech. Vol. 457. — P. 133−156.
112. Vlachogiannis M., Bontozoglou. V., 2001. Observations of solitary wave dynamics of film flows. //J. Fluid Mech. Vol. 435. — P. 191−215.
113. Volosatov V.A., 1988. Hand-Book on Electrochemical and Electrophysical Methods of Treatment. Mashinostroenie, Leningrad. P. 719.
114. Wang C.Y., 2005. Low Reynolds number film flow down a three-dimensional bumpy surface Tran. ASME. Vol. 127. — P. 1122−1127.
115. Wierschem A., Scholle M., Aksel N., 2002. Comparison of different theoretical approaches to experiments on film flow down an inclined wavy channel // Exp. Fluids. -Vol. 33. -P. 429−442.
116. Wierschem A., Scholle M., Aksel N., 2003. Vortices in film flow over strongly undulated bottom profiles at low Reynolds numbers // Phys. Fluids. Vol. 15. — P. 426−435.
117. Wierschem A., Aksel N., 2004. Influence of inertia on eddies created in films creeping over strongly undulated substrates // Phys. Fluids. Vol. 16. — P. 4566−4574.
118. Wilkes J.O., Nedderman P., 1962. The measurement of velocities in thin films of liquid//Chem. Eng. Sci.-Vol. 17. P. 177−187.
119. Wilson S.K., Duffy B.R., 1998. On the gravity-driven draining of a rivulet of viscous fluid down a slowly varying substrate with variation transverse to the direction of flow // Phys. Fluids Vol. 10. — P. 13−22.
120. Wilson S.K., Duffy B.R., 2002a. On the gravity-driven draining of a rivulet of fluid with temperature-dependent viscosity down a uniformly heated or cooled substrate // J. Engineering Mathematics. Vol. 42. — P. 359−372.
121. Wilson S.K., Duffy B.R., 2002b. A slender rivulet of a power-low fluid driven by either gravity or a constant shear stress at the free surface // Q. J. Mech. Appl. Math. -Vol. 55.-P. 385−408.
122. Wilson S.K., Duffy B.R., 2005. A rivulet of perfectly wetting fluid draining steadily down a slowly varying substrate // J. Applied Mathematics. Vol. 70. — P. 293−322.
123. Yih C.-S., 1963. Stability of liquid flow down an inclined plane // Phys. Fluids. Vol. 6, № 3.-P. 321−334.
124. Yoshimura P.N., Nosoko Т., Nagata Т., 1996. Enhancement of mass transfer into a falling laminar liquid film by two-dimensional surface waves some experimental observations and modeling // Chem. Eng. Sci. — Vol. 51, № 8. — P. 1231−1240.
125. Zaitsev D.V., Kabov O.A., Evseev A.R., 2003. Measurement of locally heated liquid film thickness by a double-fiber optical probe // Experiments Fluids. Vol. 34. — P. 748−754.
126. Zhao-L., Cerro R.L., 1992. Experimental characterization of viscous film flows over complex surfaces // Int. J. Multiphase Flow. Vol. 18, № 4. — P. 495−516.