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Rheologica Acta

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01-10-2012 | Original Contribution

Determination of axial forces during the capillary breakup of liquid filaments – the tilted CaBER method

Authors: Dirk Sachsenheimer, Bernhard Hochstein, Hans Buggisch, Norbert Willenbacher

Published in: Rheologica Acta | Issue 10/2012

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Abstract

The capillary breakup extensional rheometry (CaBER) is a versatile method to characterize the elongational behavior of low-viscosity fluids. Commonly, data evaluation is based on the assumption of zero normal stress in axial direction (\(\upsigma_{\rm zz}=0\)). In this paper, we present a simple method to determine the axial force using a CaBER device rotated by 90° and analyzing the deflection of the filament due to gravity. Forces in the range of 0.1–1,000 μN could be assessed. Our study includes experimental investigations of Newtonian fructose solutions and silicon oil mixtures (viscosity range, 0.9–60 Pa s) and weakly viscoelastic polyethylene oxide (PEO, \(M_{\rm w}=10^{6}\) g/mol) solutions covering a concentration range from c ≈ c* (critical overlap concentration) up to c > c _e (entanglement concentration). Papageorgiou’s solution for the stress ratio \(\upsigma_{\rm zz}/\upsigma_{\rm rr}\) in Newtonian fluids during capillary thinning is experimentally confirmed, but the widely accepted assumption of vanishing axial stress in weakly viscoelastic fluids is not fulfilled for PEO solutions, if c _e is exceeded.

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Title: Determination of axial forces during the capillary breakup of liquid filaments – the tilted CaBER method
Authors: Dirk Sachsenheimer
Bernhard Hochstein
Hans Buggisch
Norbert Willenbacher
Publication date: 01-10-2012
Publisher: Springer-Verlag
Published in: Rheologica Acta / Issue 10/2012
Print ISSN: 0035-4511
Electronic ISSN: 1435-1528
DOI: https://doi.org/10.1007/s00397-012-0649-3

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Other articles of this Issue 10/2012

Measuring yield stress: a new, practical, and precise technique derived from detailed penetrometry analysis

Flow characteristics and mixing performance of electrokinetically driven non-Newtonian fluid in contraction–expansion microchannel

Determining the true slip of a yield stress material with a sliding plate rheometer

Origin of the echo phenomenon upon flow reversal in low molecular weight nematic liquid crystals

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