Aerodynamic web forming: process simulation and material properties

In this paper we present a chain of mathematical models that enables the numerical simulation of the airlay process and the investigation of the resulting nonwoven material by means of virtual tensile strength tests. The models range from a highly turbulent dilute fiber suspension flow to stochastic...

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Veröffentlicht in:	Journal of mathematics in industry 2016-12, Vol.6 (1), p.1, Article 13
Hauptverfasser:	Gramsch, Simone, Klar, Axel, Leugering, Günter, Marheineke, Nicole, Nessler, Christian, Strohmeyer, Christoph, Wegener, Raimund
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Sprache:	eng
Schlagworte:	Applications of Mathematics Homogenization Math. Appl. in Environmental Science Mathematical and Computational Biology Mathematical and Computational Engineering Mathematical Methods in Physics Mathematical Modeling and Industrial Mathematics Mathematics Mathematics and Statistics Simulation Tensile strength Tomography Turbulence models
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creator	Gramsch, Simone Klar, Axel Leugering, Günter Marheineke, Nicole Nessler, Christian Strohmeyer, Christoph Wegener, Raimund
description	In this paper we present a chain of mathematical models that enables the numerical simulation of the airlay process and the investigation of the resulting nonwoven material by means of virtual tensile strength tests. The models range from a highly turbulent dilute fiber suspension flow to stochastic surrogates for fiber lay-down and web formation and further to Cosserat networks with effective material laws. Crucial is the consistent mathematical mapping between the parameters of the process and the material. We illustrate the applicability of the model chain for an industrial scenario, regarding data from computer tomography and experiments. By this proof of concept we show the feasibility of future simulation-based process design and material optimization which are long-term objectives in the technical textile industry.
doi_str_mv	10.1186/s13362-016-0034-4
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subjects	Applications of Mathematics Homogenization Math. Appl. in Environmental Science Mathematical and Computational Biology Mathematical and Computational Engineering Mathematical Methods in Physics Mathematical Modeling and Industrial Mathematics Mathematics Mathematics and Statistics Simulation Tensile strength Tomography Turbulence models
title	Aerodynamic web forming: process simulation and material properties
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