Pendant drop formation of shear-thinning and yield stress fluids
Contribuinte(s) |
Mark Cross |
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Data(s) |
01/01/2006
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Resumo |
A volume-of-fluid numerical method is used to predict the dynamics of shear-thinning liquid drop formation in air from a circular orifice. The validity of the numerical calculation is confirmed for a Newtonian liquid by comparison with experimental measurements. For particular values of Weber number and Froude number, predictions show a more rapid pinch-off, and a reduced number of secondary droplets, with increasing shear-thinning. Also a minimum in the limiting drop length occurs for the smallest Weber number as the zero-shear viscosity is varied. At the highest viscosity, the drop length is reduced due to shear-thinning, whereas at lower viscosities there is little effect of shear-thinning. The evolution of predicted drop shape, drop thickness and length, and the configuration at pinch-off are discussed for shear-thinning drops. The evolution of a drop of Bingham yield stress liquid is also considered as a limiting case. In contrast to the shear-thinning cases, it exhibits a plug flow prior to necking, an almost step-change approach to pinch-off of a torpedo shaped drop following the onset of necking, and a much smaller neck length; no secondary drops are formed. The results demonstrate the potential of the numerical model as a design tool in tailoring the fluid rheology for controlling drop formation behaviour. (c) 2006 Elsevier Inc. All rights reserved. |
Identificador | |
Idioma(s) |
eng |
Publicador |
Elsevier Science Inc |
Palavras-Chave | #Engineering, Multidisciplinary #Mathematics, Interdisciplinary Applications #Mechanics #Satellite Drops #Reynolds-number #Capillary-tube #Viscous-fluid #Free-surface #Pinch-off #Dynamics #Flows #Breakup #Bifurcation #C1 #290600 Chemical Engineering #670705 Plastic products (incl. construction materials) |
Tipo |
Journal Article |