Surfactant and viscoelastic effects on drop deformation in 2-D extensional flow

Surfactant and viscoelastic effects on drop deformation in 2-D extensional flow

The deformation and breakup of polymeric drops suspended in an immiscible Newtonian fluid are examined for planar extensional flow in a computer controlled four roll mill are examined. Previous work from this lab with aqueous polymeric drops showed an increase in the degree of deformation compared t...

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Bibliographic Details
Published in:AIChE journal Vol. 45; no. 5; pp. 929 - 937
Main Authors: Tretheway, Derek C., Leal, L. Gary
Format: Journal Article
Language:English
Published: Hoboken Wiley Subscription Services, Inc., A Wiley Company 01-05-1999
Wiley Subscription Services
American Institute of Chemical Engineers
Subjects:
Drops and bubbles
Exact sciences and technology
Fluid dynamics
Fundamental areas of phenomenology (including applications)
Non-newtonian fluid flows
Nonhomogeneous flows
Physics
Viscoelastic fluid
Geometrical shape
Ruptures
Aqueous solutions
Drops
Surfactants
Experimental study
Polymers
Elongational flow
Roll mill
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Summary:The deformation and breakup of polymeric drops suspended in an immiscible Newtonian fluid are examined for planar extensional flow in a computer controlled four roll mill are examined. Previous work from this lab with aqueous polymeric drops showed an increase in the degree of deformation compared to Newtonian drops, and two distinct breakup mechanisms, tip streaming, and tip streaming with stretch. This led to the conclusion that breakup for non‐Newtonian drops occurred at a lower capillary number and by a distinctly different mechanism than for a Newtonian drop with a similar ratio of internal to external viscosity. This conclusion was puzzling, because numerical computations with the Chilcott‐Rallison model showed that the influence of viscoelasticity for that model was to decrease the degree of deformation rather than increasing it. In this work, the results for aqueous polymer solutions are compared with results for ethylene glycol polymer solutions. The results suggest that tip streaming and tip streaming with stretch in the original experiments resulted from an undetected surfactant effect, which acts to produce a more pointed drop shape that destabilizes the drop to tip streaming. Viscoelasticity, on the other hand, acts to decrease the deformation of polymeric drops at a given capillary number and increases the critical capillary number, as predicted numerically, when compared to Newtonian drops with an equivalent viscosity ratio.
Bibliography:ark:/67375/WNG-ZRBL6P21-P
ArticleID:AIC690450503
istex:2F25D12EDB5AFEFA58B7D61A174ACF40AB51EFB0
ISSN:0001-1541
1547-5905
DOI:10.1002/aic.690450503