Propagation of the rim under a liquid-curtain breakup. (English) Zbl 1506.76039
Summary: The propagation speed, shape and stability of the rim generated by a liquid-curtain breakup are studied. In the experiment, a liquid curtain surrounded by a slot die, edge guides and the surface of a roller breaks at the contact point between the edge guide and roller in a low-Weber-number range, and the rim propagates in the horizontal direction. Except for the initial time, the rim is almost straight and has a nearly constant propagation speed. For an Ohnesorge number much smaller than 1, unevenness occurs on the rim and the droplets separate from it. When the Ohnesorge number is of the order of unity, the rim becomes convex vertically downward, and the liquid lump flows down. The shape, propagation speed and surface stability of the rim are discussed by analysing the equation proposed by V. M. Entov and A. L. Yarin [J. Fluid Mech. 140, 91–111 (1984; Zbl 0551.76039)]. It is shown that the volume flow rate condition at the slot die exit is important to explain the propagation of the rim. Additionally, in the initial stage of the curtain breakup, the Plateau-Rayleigh instability causes unevenness on the rim surface, and after the rim reaches the slot die exit, the Rayleigh-Taylor instability generates a liquid lump on the rim, which grows into droplets when the Ohnesorge number is much less than 1.
MSC:
| 76E17 | Interfacial stability and instability in hydrodynamic stability |
| 76D45 | Capillarity (surface tension) for incompressible viscous fluids |
| 76M20 | Finite difference methods applied to problems in fluid mechanics |
| 76-05 | Experimental work for problems pertaining to fluid mechanics |
Keywords:
Plateau-Rayleigh instability; Rayleigh-Taylor instability; liquid bridge; capillary wave; central finite difference scheme; experimental verificationCitations:
Zbl 0551.76039References:
| [1] | Agbaglah, G., Josserand, C. & Zaleski, S.2013Longitudinal instability of a liquid rim. Phys. Fluids25, 022103. |
| [2] | Balestra, G., Brun, P.-T. & Gallaire, F.2016Rayleigh-Taylor instability under curves substrates: an optimal transient growth analysis. Phys. Rev. Fluids1, 083902. |
| [3] | Blake, T.D. & Ruschak, K.J.1979A maximum speed of wetting. Nature282 (5738), 489-491. |
| [4] | Brenner, M.P. & Gueyffier, D.1999On the bursting of viscous films. Phys. Fluids11, 737-739. · Zbl 1147.76338 |
| [5] | Chepushtanova, S.V. & Kliakhandler Igor, L.2007Slow rupture of viscous films between parallel needles. J. Fluid Mech.573, 297-310. · Zbl 1108.76306 |
| [6] | Chomaz, J.-M.2005Global instabilities in spatially developing flows: non-normality and nonlinearity. Annu. Rev. Fluid Mech.37, 357-392. · Zbl 1117.76027 |
| [7] | Culick, F.E.C.1960Comments on a ruptured soap film. J. Appl. Phys.31, 1128-1129. |
| [8] | Drazin, P.G. & Reid, W.H.1982Hydrodynamic Stability. . Cambridge University Press. · Zbl 0513.76031 |
| [9] | Entov, V.M. & Yarin, A.L.1984The dynamics of thin liquid jets in air. J. Fluid Mech.140, 91-111. · Zbl 0551.76039 |
| [10] | Entov, V.M., Rozhkov, A.N., Feizkhanov, U.F. & Yarin, A.L.1986Dynamics of liquid films. Plane films with free rims. J. Appl. Mech. Tech. Phys.27, 41-47. |
| [11] | Karim, A.M., Suszynshi, W.J. & Francis, L.F.2018Effect of viscosity on liquid curtain stability. AIChE J. 64-4, 1448-1457. |
| [12] | Kistler, S.F.1985 The fluid mechanics of curtain coating and related viscous free surface flows with contact lines. PhD thesis, University of Minnesota. |
| [13] | Kyotoh, H., Fujita, K., Nakano, K. & Tsuda, T.2014Flow of a falling liquid curtain into a pool. J. Fluid Mech.741, 350-376. |
| [14] | Liu, C.-Yu., Vandre, E. , Carvalho, M.S. & Kumar, S.2016Dynamic wetting failure and hydrodynamic assist in curtain coating. J. Fluid Mech.808, 290-315. · Zbl 1383.76157 |
| [15] | Liu, C.-Yu., Carvalho, M.S. & Kumar, S.2019Dynamic wetting failure in curtain coating: comparison of model predictions and experimental observations. Chem. Engng Sci.195, 74-82. |
| [16] | Liu, Y., Itoh, M. & Kyotoh, H.2017Flow of a falling liquid curtain onto a moving substrate. Fluid Dyn. Res.49, 055501. |
| [17] | Marston, J.O., Thoroddsen, S.T., Thompson, J., Blyth, M.G., Henry, D. & Uddin, J.2014Experimental investigation of hysteresis in the break-up. Chem. Engng Sci.117, 248-263. |
| [18] | Miyamoto, K. & Katagiri, Y.1997 Curtain coating. In Liquid Film Coating (ed. S. Kistler & P.M. Schweizer), pp. 463-494. Chapman & Hall. |
| [19] | Oron, A., Davis, S.H. & Bankoff, S.G.1997Long-scale evolution of thin liquid films. Rev. Mod. Phys. 69-3, 931-980. |
| [20] | Rayleigh, Lord1882Investigation of the character of the equilibrium of an incompressible heavy fluid of variable density. Proc. Lond. Math. Soc.14, 170-177. · JFM 15.0848.02 |
| [21] | Roche, J.S. & Le Grand, N.2006Perturbations on a liquid curtain near break-up: wakes and free edges. Phys. Fluids18, 082101. · Zbl 1185.76550 |
| [22] | Roisman, I.V.2010On the instability of a free viscous rim. J. Fluid Mech.661, 206-228. · Zbl 1205.76118 |
| [23] | Savva, N. & Bush, J.W.2009Viscous sheet retraction. J. Fluid Mech.626, 211-240. · Zbl 1171.76326 |
| [24] | Sunderhauf, G., Raszillier, H. & Durst, F.2002The retraction of the edge of a planar liquid sheet. Phys. Fluids14 (1), 198-208. · Zbl 1184.76538 |
| [25] | Takagi, M.2010 Study on a free falling liquid curtain onto a roller and a pool. Master’s thesis, University of Tsukuba, in Japanese. |
| [26] | Taylor, G.I.1950The instability of liquid surfaces when accelerated in a direction perpendicular to their planes. Proc. R. Soc. Lond. A201, 192-196. · Zbl 0038.12201 |
| [27] | Taylor, G.I.1959The dynamics of thin sheets of fluid II. Waves on fluid sheet. Proc. R. Soc. Lond. A253, 296-312. · Zbl 0087.19602 |
| [28] | Weinstein, S.J. & Ruschak, K.J.2004Coating flows. Annu. Rev. Fluid Mech.36, 29-53. · Zbl 1081.76009 |
| [29] | Yarin, A.L.1993Free Liquid Jets and Films: Hydrodynamics and Rheology. Longman & Wiley. · Zbl 0872.76002 |
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