Uniaxial extensional flows in liquid bridges

EBERHARD BÄNSCH; CHRISTIAN P. BERG; ANTJE OHLHOFF

doi:10.1017/S0022112004001193

Abstract

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In this paper we consider the possibility of generating homogeneous flows with a nearly constant strain rate. This is achieved by stretching an almost cylindrical liquid bridge under microgravity. One key issue is the adjustability of the disk diameters, necessary for maintaining ideal boundary conditions. We first study the stretching of two different fluids by both numerical and experimental means. The numerical results are compared with the experimental data and very good agreement is found. The numerical method is then used to study the behaviour of liquid bridges for quite a large range of the flow parameters (capillary number $\Ca$ and Weber number $\We$) in order to detect those regimes with most suitable flow conditions.

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Uniaxial extensional flows in liquid bridges

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