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The collapse time of a closed cavity

Published online by Cambridge University Press:  28 March 2006

John W. Miles
John W. Miles
Affiliation:
University of California, La Jolla, California
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Abstract

The collapse time of a closed cavity that is initially at rest in an incompressible, inviscid fluid of density ρ and ambient pressure p has the form \[ t_1 = \{\rho/(p_{\infty} - p_c)\}^{\frac{1}{2}}\ell, \] where pc is the internal pressure, which is assumed to remain constant during collapse, and [ell ] is a length that depends only on the geometry of the cavity. A variational formulation of the dynamical problem is constructed from Jacobi's statement of the principle of least action. A single-degree-of-freedom approximation is developed from the similarity hypothesis that the cavity collapses through a family of similar surfaces with volume as the generalized co-ordinate. Two-degree-of-freedom approximations are given for both prolate and oblate spheroidal cavities and are used to obtain error estimates for the similarity approximation (approximately 2% for the limiting case of a needle-like, prolate spheroid and approximately ½ % for a disk-like, oblate spheroid). A perturbation analysis is developed for an approximately spherical cavity, which is found to have the same collapse time as a spherical cavity of equal volume within a factor 1 + O(e4), where e is a representative eccentricity. A first-order correction for surface tension is obtained.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 25 , Issue 4 , August 1966 , pp. 743 - 760
Copyright
© 1966 Cambridge University Press

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References

Benjamin, T. B. 1964 J. Fluid Mech. 19, 137144.
Benjamin, T. B. & Ellis, A. 1965 Proc. Roy. Soc. A (in the Press.)
Besant, H. 1859 Hydrostatics and Hydrodynamics. Cambridge University Press.
Birkhoff, G. & Zarantonello, E. 1957 Jets, Wakes and Cavities. New York: Academic Press.
Demtchenko, B. 1926 J. l’École Polytechnique, 27, 113121.
Hobson, E. W. 1931 Spherical and Ellipsoidal Harmonics. Cambridge University Press.
Jeans, J. 1948 The Mathematical Theory of Electricity and Magnetism, p. 247. Cambridge University Press.
Lamb, H. 1932 Hydrodynamics. Cambridge University Press.
May, A. 1952 J. Appl. Phys. 23, 136272.
May, A. & Hoover, W. R. 1965 A Study of the Water-Entry Cavity. Ballistics Res. Rep. no. 121, U.S. Naval Ord. Lab., White Oak, Maryland.Google Scholar
Plesset, M. S. & Mitchell, T. P. 1955 Quart. Appl. Math. 13, 419430.
Pölya, G. & Szegö, G. 1951 Isoperimetric Inequalities in Mathematical Physics. Princeton University Press.
Poncin, H. 1932 Publ. Sci. et Tech. du Ministere de l'Air, no. 18, Paris.
Poncin, H. 1939a J. Math. Pures Appl. 18, 385404.
Poncin, H. 1939b Acta Math. 71, 162.
Rayleigh, Lord 1916 Phil. Mag. 31, 177186; Scientific Papers, 6, 383–392.
Rayleigh, Lord 1917 Phil. Mag. 34, 9498; Scientific Papers, 6, 504–507.
Rayleigh, Lord 1945 Theory of Sound. New York: Dover.
Synge, J. L. 1960 Classical Dynamics. Principles of Classical Mechanics and Field Theory, vol. III of Encyclopedia of Physics. Berlin: Springer-Verlag.
Tuck, E. O. 1964 J. Fluid Mech. 18, 619635.
Whittaker, E. T. 1944 Analytical Dynamics. New York: Dover.