Numerical simulation of the film casting process

The film casting process is widely used to produce polymer film: a molten polymer is extruded through a flat die, then stretched in air and cooled on a chill roll. This study is devoted to the extensional flow between the die and the chill roll. The film shows a lateral neck‐in as well as an inhomog...

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Bibliographic Details
Published in:International journal for numerical methods in fluids 1999-05, Vol.30 (1), p.1-18
Main Authors: Silagy, D., Demay, Y., Agassant, J.F
Format: Article
Language:English
Subjects:
Applied sciences
Aspect ratio
Computational methods in fluid dynamics
Computer simulation
Engineering Sciences
Exact sciences and technology
Extrusion
Extrusion moulding
film casting process
Finite element method
Fluid dynamics
Fundamental areas of phenomenology (including applications)
Galerkin methods
Machinery and processing
Materials
Mathematical models
Molten materials
Moulding
numerical simulation
Physics
Plastic films
Plastics
Plastics forming dies
Polymer industry, paints, wood
Rolls (machine components)
stability
Technology of polymers
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Summary:The film casting process is widely used to produce polymer film: a molten polymer is extruded through a flat die, then stretched in air and cooled on a chill roll. This study is devoted to the extensional flow between the die and the chill roll. The film shows a lateral neck‐in as well as an inhomogeneous decrease of the thickness. An isothermal and Newtonian membrane model, constituted of an elastic‐like equation for velocity coupled to a transport equation for thickness and a free surface computation, is used. These equations are solved via the finite element method (continuous Galerkin for velocity and discontinuous Galerkin for thickness). Both tracking and capturing strategies are used to determine the position of the free surface (lateral neck‐in). The influence of the processing parameters (Draw ratio and Aspect ratio) on the film geometry is first determined. The onset of the Draw Resonance instability is then studied through the dynamic response of the process to small perturbations. A critical curve splitting the processing conditions into a stable and an unstable zone is derived. It is shown, consistently, with results of a 1D model, that an increase of the air‐gap between the die and the roll improves the stability of the process. Numerical results concerning periodic fluctuations of the flow in unstable conditions are compared with previous experimental results. Copyright © 1999 John Wiley & Sons, Ltd.
ISSN:0271-2091
1097-0363
DOI:10.1002/(SICI)1097-0363(19990515)30:1<1::AID-FLD833>3.0.CO;2-Q