Erosion in extruder flows: Analytical and Numerical Study

Petru S Fodor; Miron Kaufman

Erosion in extruder flows: Analytical and Numerical Study

Petru S Fodor
, Miron Kaufman

Physics

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

We consider the erosion of particles (e.g. carbonblack agglomerates) advected by the polymeric flow in a single screw extruder. We assume a particle to be made of primary fragments bound together. In the erosion process a primary fragment breaks out of a given particle. Particles disperse because of the shear stresses imparted by the fluid. The time evolution of the numbers of particles of different sizes is described by the Bateman coupled differential equations developed a century ago to model radioactivity. Using the particle size distribution we compute an entropic fragmentation index which varies from 0 for a monodisperse system to 1 for an extreme poly-disperse system. The time dependence of the index exhibits a maximum at some intermediate time as the system starts monodisperse (large size particle) and evolves through a poly-disperse regime at intermediate times to a monodisperse (small size particle) at late times

Original language	English
Title of host publication	Unknown book
State	Published - 2016
Event	32nd International Conference of the Polymer Processing Society - Duration: Jan 1 2016 → …

Conference

Conference	32nd International Conference of the Polymer Processing Society
Period	01/1/16 → …

Cite this

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title = "Erosion in extruder flows: Analytical and Numerical Study",

abstract = "We consider the erosion of particles (e.g. carbonblack agglomerates) advected by the polymeric flow in a single screw extruder. We assume a particle to be made of primary fragments bound together. In the erosion process a primary fragment breaks out of a given particle. Particles disperse because of the shear stresses imparted by the fluid. The time evolution of the numbers of particles of different sizes is described by the Bateman coupled differential equations developed a century ago to model radioactivity. Using the particle size distribution we compute an entropic fragmentation index which varies from 0 for a monodisperse system to 1 for an extreme poly-disperse system. The time dependence of the index exhibits a maximum at some intermediate time as the system starts monodisperse (large size particle) and evolves through a poly-disperse regime at intermediate times to a monodisperse (small size particle) at late times",

author = "Fodor, \{Petru S\} and Miron Kaufman",

year = "2016",

language = "English",

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note = "32nd International Conference of the Polymer Processing Society ; Conference date: 01-01-2016",

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TY - GEN

T1 - Erosion in extruder flows: Analytical and Numerical Study

AU - Fodor, Petru S

AU - Kaufman, Miron

PY - 2016

Y1 - 2016

N2 - We consider the erosion of particles (e.g. carbonblack agglomerates) advected by the polymeric flow in a single screw extruder. We assume a particle to be made of primary fragments bound together. In the erosion process a primary fragment breaks out of a given particle. Particles disperse because of the shear stresses imparted by the fluid. The time evolution of the numbers of particles of different sizes is described by the Bateman coupled differential equations developed a century ago to model radioactivity. Using the particle size distribution we compute an entropic fragmentation index which varies from 0 for a monodisperse system to 1 for an extreme poly-disperse system. The time dependence of the index exhibits a maximum at some intermediate time as the system starts monodisperse (large size particle) and evolves through a poly-disperse regime at intermediate times to a monodisperse (small size particle) at late times

AB - We consider the erosion of particles (e.g. carbonblack agglomerates) advected by the polymeric flow in a single screw extruder. We assume a particle to be made of primary fragments bound together. In the erosion process a primary fragment breaks out of a given particle. Particles disperse because of the shear stresses imparted by the fluid. The time evolution of the numbers of particles of different sizes is described by the Bateman coupled differential equations developed a century ago to model radioactivity. Using the particle size distribution we compute an entropic fragmentation index which varies from 0 for a monodisperse system to 1 for an extreme poly-disperse system. The time dependence of the index exhibits a maximum at some intermediate time as the system starts monodisperse (large size particle) and evolves through a poly-disperse regime at intermediate times to a monodisperse (small size particle) at late times

M3 - Conference contribution

BT - Unknown book

T2 - 32nd International Conference of the Polymer Processing Society

Y2 - 1 January 2016

ER -