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Abstract

Pultrusion is a crucial method for continuous production of fiber-reinforced composites. It was developed several years ago for thermosetting polymer matrices, but the challenge is now to extend it to thermoplastic matrices, with a much higher viscosity. In this paper, we propose an analysis of the parameters influencing fiber impregnation in the conditions of this process. A semi-analytical one-dimensional axisymmetric model based on Darcy’s law and Stokes equations is developed to predict the impregnation profile inside the fibrous phase in the case of a natural impregnation governed by capillary forces. Thanks to a dimensional analysis, it enables to quantify the influence of all the material and testing parameters under the assumption of a slow variation of the geometry of the impregnation die. The cases of a straight and conical dies are discussed. For the first case, an exhaustive numerical study enables to define the optimal processing conditions for a perfect impregnation. Those results are shown to be useful tools for finding an optimal pulling velocity and die length for a given fluid/fibers pair. For the second case, we show that section reductions do not improve impregnation.

Keywords

Pultrusion modeling simplified model axisymmetric die optimisation

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References

Velda

KVD

Kiekens

. Thermoplastic pultrusion of natural fibre reinforced composites. Compos Struct 2001; 54: 355–360.

Han

. Development of mathematical model for the pultrusion of unsaturated polyester resin. Polymer Eng Sci 1988; 28: 11–19.

Liu

Hillier

. Heat transfer and cure analysis for the pultrusion of a fiberglass vinyl ester beam. Compos Struct 1999; 47: 11–19.

Raper

Roux

McCarty

. Investigation of the pressure behavior in a pultrusion die for graphite/epoxy composites. Compos Part A 1999; 30: 1123–1132.

Luisier

Bourban

Manson

JAE

. Reaction injection pultrusion of PA12 composites: process and modelling. Compos Part A 2003; 34: 583–595.

Adams

Miller

Rebenfeld

. Forced in-plane flow of an epoxy resin in fibrous networks. Polym Eng Sci 1986; 26: 1434–1441.

Carlsson

Aström

. Experimental investigation of pultrusion of glass fibre reinforced polypropylene composites. Compos Part A 1998; 29: 585–593.

Sharma

McCarty

Roux

. Investigation of dy- namic pressure behavior during the pultrusion of composites. J Compos Mater 1998; 32: 929–950.

Simacek

Advani

. A numerical model to predict fiber tow saturation during liquid composite molding. Compos Sci Technol 2002; 60: 1725–1736.

10.

Bechtold

Wiedmer

Friedrich

. Pultrusion of thermoplastic composites-new developments and modelling studies. J Thermoplast Compos Mater 2002; 15: 443–465.

11.

Zhou

Kuentzer

Simacek

. Analytic characterization of the permeability of dual scale fibrous porous media. Compos Sci Technol 2006; 66: 2795–2803.

12.

Zhou

Alms

Advani

. A closed form solution for flow in dual scale fibrous porous media under constant injection pressure conditions. Compos Sci Technol 2007; 68: 699–708.

13.

Sala

Cutolob

. The pultrusion of powder-impregnated thermo- plastic composite. Composites Part A 1996; 28: 637–646.

14.

Haffner

Friedrich

Hogg

. Finite element assisted modelling of a thermoplastic pultrusion process for powder-impregnated yarn. Compos Sci Technol 1998; 58: 1371–1380.

15.

Kim

Lee

WII

Friedrich

. A model for a thermoplastic pultru sion process using commingled yarns. Compos Sci Technol 2000; 61: 1065–1077.

16.

Amico

Lekakou

. An experimental study of the permeability and capillary pressure in resin-transfer moulding. Compos Sci Technol 2001; 61: 1945–1959.

17.

Agassant

Avenas

Sergent

. La mise en forme des matières plastiques, Paris: Tec and Doc Lavoisier, 1996, pp. 355–369.

18.

Lundström

. The permeability of non-crimp stitched fabrics. Compos Part A 2000; 12: 1345–1353.

19.

Ahn

Seferis

Berg

. Simultaneous measurements of perme- ability and capillary pressure of thermosetting matrices in woven fabric reinforcements. Polym Compos 1991; 12: 146–152.

20.

Dullien

FAL

. Porous media: Fluid transport and pore structure, San Diego, CA, USA: Academic Press, 1992.

21.

Adams

Rebenfeld

. In-plane flow of fluids in fabrics: Structure/flow characterization. Text Res J 1987, pp. 647–654.

22.

Parnas

Salem

Wang

. The interaction between micro- and macroscopic flow in RTM preforms. Compos Struct 1994; 27: 93–107.

23.

Liu

Hwang

. Transient filling simulations in unidirectional fibrous porous media. Korea-Australia Rheology J 2009; 21: 71–79.

24.

Wang

. Dynamic capillary impact on longitudinal micro-flow in vacuum assisted impregnation and the unsaturated permeability of inner fiber tows. Compos Sci Technol 2010; 70: 1628–1636.

Thermoplastic pultrusion process: Modeling and optimal conditions for fibers impregnation

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