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Main Authors: Arne, Walter, Marheineke, Nicole, Perez-Saborid, Miguel, Rivero-Rodriguez, Javier, Wegener, Raimund, Wieland, Manuel
Format: Preprint
Published: 2017
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Online Access:https://arxiv.org/abs/1702.04347
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author Arne, Walter
Marheineke, Nicole
Perez-Saborid, Miguel
Rivero-Rodriguez, Javier
Wegener, Raimund
Wieland, Manuel
author_facet Arne, Walter
Marheineke, Nicole
Perez-Saborid, Miguel
Rivero-Rodriguez, Javier
Wegener, Raimund
Wieland, Manuel
contents An electrified visco-capillary jet shows different dynamic behavior, such as cone forming, breakage into droplets, whipping and coiling, depending on the considered parameter regime. The whipping instability that is of fundamental importance for electrospinning has been approached by means of stability analysis in previous papers. In this work we alternatively propose a model framework in which the instability can be computed straightforwardly as the stable stationary solution of an asymptotic Cosserat rod description. For this purpose, we adopt a procedure by Ribe (Proc. Roy. Soc. Lond. A, 2004) describing the jet dynamics with respect to a frame rotating with the a priori unknown whipping frequency that itself becomes part of the solution. The rod model allows for stretching, bending and torsion, taking into account inertia, viscosity, surface tension, electric field and air drag. For the resulting parametric boundary value problem of ordinary differential equations we present a continuation-collocation method. On top of an implicit Runge-Kutta scheme of fifth order, our developed continuation procedure makes the efficient and robust simulation and navigation through a high-dimensional parameter space possible. Despite the simplicity of the employed electric force model the numerical results are convincing, the whipping effect is qualitatively well characterized.
format Preprint
id arxiv_https___arxiv_org_abs_1702_04347
institution arXiv
publishDate 2017
record_format arxiv
spellingShingle Whipping of electrified visco-capillary jets in airflows
Arne, Walter
Marheineke, Nicole
Perez-Saborid, Miguel
Rivero-Rodriguez, Javier
Wegener, Raimund
Wieland, Manuel
Fluid Dynamics
Dynamical Systems
Computational Physics
34B08, 65Lxx, 76-XX
An electrified visco-capillary jet shows different dynamic behavior, such as cone forming, breakage into droplets, whipping and coiling, depending on the considered parameter regime. The whipping instability that is of fundamental importance for electrospinning has been approached by means of stability analysis in previous papers. In this work we alternatively propose a model framework in which the instability can be computed straightforwardly as the stable stationary solution of an asymptotic Cosserat rod description. For this purpose, we adopt a procedure by Ribe (Proc. Roy. Soc. Lond. A, 2004) describing the jet dynamics with respect to a frame rotating with the a priori unknown whipping frequency that itself becomes part of the solution. The rod model allows for stretching, bending and torsion, taking into account inertia, viscosity, surface tension, electric field and air drag. For the resulting parametric boundary value problem of ordinary differential equations we present a continuation-collocation method. On top of an implicit Runge-Kutta scheme of fifth order, our developed continuation procedure makes the efficient and robust simulation and navigation through a high-dimensional parameter space possible. Despite the simplicity of the employed electric force model the numerical results are convincing, the whipping effect is qualitatively well characterized.
title Whipping of electrified visco-capillary jets in airflows
topic Fluid Dynamics
Dynamical Systems
Computational Physics
34B08, 65Lxx, 76-XX
url https://arxiv.org/abs/1702.04347