Hostname: page-component-cd9895bd7-lnqnp Total loading time: 0 Render date: 2024-12-20T07:30:34.403Z Has data issue: false hasContentIssue false
  • English
  • Français

The shape and stability of liquid menisci at solid edges

Published online by Cambridge University Press:  26 April 2006

Dieter Langbein
Dieter Langbein
Affiliation:
Battelle-Institut e. V., Am Römerhof 56, Postfach 90, D-6000 Frankfurt am Main 90, West Germany
Get access Rights & Permissions [Opens in a new window]

Abstract

The shape and stability of liquid menisci attached to a solid edge with dihedral angle 2α is investigated. It is shown that in addition to the family of cylindrical menisci a family of azimuthally modified unduloids exists. A double Fourier series of the latter with respect to their axis (parallel to the extension of the edge) and with respect to the azimuth is derived. The dispersion relation between the axial wavenumber q, the azimuthal wavenumber s and the waviness parameter d is calculated. When the condition of constant contact angle γ along the contact lines with the solid is applied, a one-dimensional family of modified unduloids fitting to the edge is obtained. Their axial wavenumber q becomes independent of the waviness d at the bifurcation with the family of cylindrical menisci, such that this bifurcation limits the stability. The respective stability criteria are derived and evaluated. For α + γ > ½π the cylindrical menisci are convex. They reveal a maximum stable length, which quadratically tends to infinity when α + γ = ½π is approached. The smallest stable extension arises for the free cylindrical column (the Rayleigh jet), which is covered by the present investigations by assuming α = π, γ = ½π. For α + γ < ½π the cylindrical menisci are concave and stable: no bifurcation with the family of modified unduloids arises.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 213 , April 1990 , pp. 251 - 265
Copyright
© 1990 Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bauer, H. F. 1984 Natural damped frequencies of an infinitely long column of immiscible viscous liquids. Z. Angew. Math. Mech. 64, 475490.Google Scholar
Bauer, H. F. 1986a Experiments on fluid interfaces in cylinders and cylindrical sections during parabolic flights of the KC-135 aircraft. Forschungsber. LRT-WE-9, University d. BW. München.
Bauer, H. F. 1986b Free surface and interface oscillations of an infinitely long liquid column. Acta Astronautica 13, 922.Google Scholar
Boys, C. V. 1959 Soap bubbles: Their Colours and Forces which Mold Them, pp. 5862. Dover.
Cahn, J. W. 1977 Critical point wetting. J. Chem. Phys. 66, 36673672.Google Scholar
Cahn, J. W. 1979 Monotectic composite growth. Metall. Trans. 10A, 119121.Google Scholar
Carruthers, J. R., Gibson, E. G., Klett, M. G. & Facemire, B. R. 1975 Studies of rotating liquid floating zones in Skylab IV. AIAA-Paper 75–692.Google Scholar
Concus, P. & Finn, R. 1974 On capillary free surfaces in the absence of gravity. Acta Math. 132, 177198.Google Scholar
Coriell, S. R., Hardy, S. C. & Cordes, M. R. 1977 Stability of liquid zones. J. Colloid Interface Sci. 60, 126136.Google Scholar
Finn, R. 1986 Equilibrium Capillary Surfaces. Grundlehren der Mathematischen Wissenschaften. Vol. 284, pp. 1244 Springer.
Heywang, W. 1956 Zur Stabilität senkrechter Schmelzzonen. Z. Naturforschung 11a, 238243.Google Scholar
Langbein, D. 1987 The sensitivity of liquid columns to residual accelerations. ESA-SP 256, pp. 221228Google Scholar
Langbein, D., Grossbach, R. & Heide, W. 1989 Parabolic flight experiments on fluid surfaces and wetting. Appl. Microgravity Techn. II, issue 4.Google Scholar
Langbein, D. & Hornung, U. 1989 Liquid menisci in polyhedral containers. Proc. Workshop on Differential Geometry, Calculus of Variations and Computer Graphics. MSRI Book Series. Springer.
Langbein, D. & Rischbieter, F. 1984 Form, Schwingungen und Stabilität von Flüssigkeitsgrenzflächen. Schlussbericht für das BMFT, 01 QV 242, pp. 1130Battelle Frankfurt/M. Forschungsber. W 86–029 des BMFT.
Martinez, I. 1983 Stability of axisymmetric liquid bridges. ESA-SP 191, pp. 267273Google Scholar
Martinez, I. 1987 Stability of long liquid columns in Spacelab-D1. ESA-SP 256, pp. 235240Google Scholar
Martinez, I., Haynes, J. M. & Langbein, D. 1987 Fluid statics and capillarity. In Fluid Science and Materials Science in Space (ed. H. U. Walter), chap. II. Springer.
Meseguer, J. 1983 The breaking of axisymmetric slender liquid bridges. J. Fluid Mech. 130, 123151.Google Scholar
Padday, J. F. 1983 Fluid Physics in Space – The Kodak Ltd. Experiment aboard Spacelab-1. Kodak Ltd.
Preisser, F., Schwabe, F. & Scharmann, A. 1983 Steady and oscillatory thermocapillary convection in liquid columns with free cylindrical surface. J. Fluid Mech. 126, 545567.Google Scholar
Rayleigh, Lord 1879 On the capillary phenomena of jets. Proc. R. Soc. Lond. 29, 7197.Google Scholar
Rayleigh, Lord 1945 The Theory of Sound, vol. 2, sect. 364. Dover (Reprint).
Schwabe, D. & Scharmann, A. 1979 Some evidence for the existence and magnitude of a critical Marangoni-number for the onset of oscillatory flow in crystal growth melts. J. Cryst. Growth 46, 124131.Google Scholar
Soo, D. N. 1984 Study of slosh dynamics of fluid filled containers on 3-axis stabilized spacecraft. Final Report of ERNO/ESTEC, Contract 5238/83/NL/Bi(SC).Google Scholar
Supplementary material: PDF

Langbein supplementary material

Table 1 and 2

Download Langbein supplementary material(PDF)
PDF 1.8 MB