Modelling ferromagnetic fiber alignment in viscous fluids under static magnetic fields

When conventional polymer processing methods (e.g. extrusion or injection molding) are used to process discontinuous fiber composites, the obtained fiber orientation distribution is often the result of the processing conditions, part geometry and flow behavior of the material. The current state of t...

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Bibliographic Details
Main Authors: De Schryver, CĂ©dric, Vanoost, Dries, Buffel, Bart, Pissoort, Davy, Desplentere, Frederik
Format: Conference Proceeding
Language:English
Subjects:
Diamagnetism
Extrusion molding
Ferromagnetism
Fiber composites
Fiber orientation
Field strength
High aspect ratio
Injection molding
Magnetic control
Magnetic fields
Magnetic properties
Modelling
Numerical models
Polydimethylsiloxane
Polymer melts
Polymers
Process parameters
Realignment
Viscous fluids
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Summary:When conventional polymer processing methods (e.g. extrusion or injection molding) are used to process discontinuous fiber composites, the obtained fiber orientation distribution is often the result of the processing conditions, part geometry and flow behavior of the material. The current state of the art in polymer processing does not allow a targeted control of the fiber distribution to improve the final part properties. Magnetic manipulation of a dispersed phase using a static magnetic field was already used for several types of fiber geometries and materials. Therefore, magnetic control of fiber orientation in a polymer melt would surpass the current state of the art. This paper used the technique to study the dynamical behavior of a single high aspect ratio ferromagnetic fiber submerged in a polydimethylsiloxane (PDMS) matrix. The magnetic response of the fiber as a function of the aspect ratio, the matrix viscosity and the magnetic field strength is discussed. To predict the rate of fiber realignment, two numerical models are evaluated. These models focus on the different forces acting on the solid fiber during the realignment and have shown to be effective for diamagnetic materials. The modelling results show a good prediction of the experiments for all variated parameters in the process.
ISSN:0094-243X
1551-7616
DOI:10.1063/5.0135916