Abstract
The paper is devoted to the results of experimental research on bubbly cluster interaction with free surfaces that arises on reflection of underwater shock waves. For the first time, the effect of anomalous behaviour of a free surface with such an interaction was found in calculating the structure of the shock wave reflected (V Kedrinskii, S Plaksin, 1984): a characteristic time of its relaxation turned out to be much longer than the length of the strong incident shock wave. The recent experiments performed in a hydrodynamic shock tube have shown that the behaviour of the free surface reflects main peculiarities of the bubbly cavitation zone dynamics developing near it.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
References
Besov AS, Kedrinskii VK, Pal’chikov EI (1984) Study of initial stage of cavitation by diffraction optic technique. Letters in J of Tech Physics , v. 10(4).
Besov AS, Kedrinskii VK, Pal’chikov EI (1989) On threshold effects in pulse rarefaction waves. Letters in J of Tech Physics, v. 15(16).
Carlson GA, Henry KW (1973) Technique for studying tension failure in application to glycerol. J Appl Physics 42(5):
Hammitt FG, Koller A, Ahmed O, Pyun J, Yilmaz E (1976) Cavitation threshold and superheat in various fluids. In: Cavitation Proc Int Conf, Mech Eng Publ Ltd London NY, Edinburg, September 3–5
Van de Hulst H (1957) Light scattering by small particles. John Wiley and Sons, Inc. New York, Chap 9, 10.
Kedrinskii VK (1968) Wave propagation in liquid with gas bubbles. . J Appl Mechanics and Tech Physics 4:29–34 (Shock wave transformation in bubbly liquid (1980). In: Cavitation and Inhomogeneities. Springer Ser. in Electrophysics 4, Berlin, New York:
Kedrinskii VK (1976) Negative pressure profile in cavitation zone at underwater explosion near a free surface. Acta Astronautica 3:623–632
Kedrinskii VK, Plaksin SI (1984) Interaction of nonstationary shock wave with free surface in real liquid. In: Proc 10th Int Symp on Nonlinear Acoustics, Osaka Univ, Japana: 181–184
Kedrinskii VK (1985) Peculiarities of bubble spectrum behavior in cavitation zone and its effect on wave field parameters. In: Ultrasonics Int 85 Proc Int Conf, Butterworth Sci Ltd London: 225–230
Kedrinskii VK (1986) On multiplication mechanism of cavitation nuclei. In: ICA, Proc 12th Int Cong on Acoust, Toronto, July 24–31:14–8
Kedrinskii VK (1993) Nonlinear problems of cavity liquid fracture at explosive loading (review). J Appl Mechanics and Tech Physics 3:74–91
Sirotyuk MG (1968) Experimental study of ultrasonic cavitation. In: Power ultrasonic fields, Nauka Moscow: 167–220
Trevena D (1987) Cavitation and tension in liquids. Adam Hilger, Bristol and Philadelphia
Voevodin AF, Shugrin SM (1981) Numerical methods for calculation of one-dimensional systems. Nauka, Novosibirsk.
Wilson DA, Hoyt JW, McKune JW (1975) Measurement of tensile strength of liquid by explosion technique. Nature 253:723–5
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 1994 Springer Science+Business Media Dordrecht
About this paper
Cite this paper
Besov, A., Kedrinskii, V. (1994). Dynamics of bubbly clusters and free surfaces at shock wave reflection. In: Blake, J.R., Boulton-Stone, J.M., Thomas, N.H. (eds) Bubble Dynamics and Interface Phenomena. Fluid Mechanics and Its Applications, vol 23. Springer, Dordrecht. https://doi.org/10.1007/978-94-011-0938-3_9
Download citation
DOI: https://doi.org/10.1007/978-94-011-0938-3_9
Publisher Name: Springer, Dordrecht
Print ISBN: 978-94-010-4404-2
Online ISBN: 978-94-011-0938-3
eBook Packages: Springer Book Archive