Abstract
The effect of vertical wall vibrations on two-phase channel flow is examined. The basic flow consists of two superposed fluid layers in a channel whose walls oscillate perpendicular to themselves in a prescribed, time-periodic manner. The solution for the basic flow is presented in closed form for Stokes flow, and its stability to small periodic perturbations is assessed by means of a Floquet analysis. It is found that the pulsations have a generally destabilizing influence on the flow. They tend to worsen the Rayleigh–Taylor instability present for unstably stratified fluids; the larger the amplitude of the pulsations, the greater the range of unstable wave numbers. For stably stratified fluids, the pulsations raise the growth rate of small perturbations, but are not sufficient to destabilize the flow. In the latter part of the paper, the basic flow for arbitrary Reynolds number is computed numerically assuming a flat interface, and the motion of the interface in time is predicted. The existence of a time-periodic flow is demonstrated in which the ratio of the layer thicknesses remains constant throughout the motion.
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References
Yih CS (1968) Instability of unsteady flows or configurations Part 1. Instability of a horizontal liquid layer on an oscillating plane. J Fluid Mech 31:737–751
von Kerczek CH (1987) Stability characteristics of some oscillatory flows – Poiseuille, Ekman and films. In: Dwoyer DL, Hussaini MY (eds) Stability of time dependent and spatially varying flows. Springer, Berlin
Coward AV, Papageorgiou DT (1994) Stability of oscillatory two-phase Couette flow. IMA J Appl Math 54:75–93
Halpern D, Frenkel AL (2001) Saturated Rayleigh–Taylor instability of an oscillating Couette film flow. J Fluid Mech 446:67–93
Coward AV, Papageorgiou DT, Smyrlis YS (1995) Nonlinear stability of oscillatory core-annular flow: A generalized Kuramoto–Sivashinsky equation with time periodic coefficients. Z angew Math Phys 46:1–39
Halpern D, Grotberg JB (2003) Nonlinear saturation of the Rayleigh instability due to oscillatory flow in a liquid-lined tube. J Fluid Mech 492:251–270
Pozrikidis C, Blyth MG (2004) Effect of stretching on interfacial stability. Acta Mechanica A 170:149–162
Hall P, Papageorgiou DT (1999) The onset of chaos in a class of Navier–Stokes solutions. J Fluid Mech 393:59–87
Yih CS (1967) Instability due to viscosity stratification. J Fluid Mech 27:337–352
Blyth MG, Pozrikidis C (2004) Effect of surfactants on the stability of two-layer channel flow. J Fluid Mech 505:59–86
Drazin PG (1992) Nonlinear systems. Cambridge University Press, Cambridge
Pozrikidis C (1998) Numerical computation in science and engineering. Oxford University Press, Oxford
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Blyth, M.G. Effect of pulsations on two-layer channel flow. J Eng Math 59, 123–137 (2007). https://doi.org/10.1007/s10665-006-9084-8
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DOI: https://doi.org/10.1007/s10665-006-9084-8