Sage Journals: Discover world-class research

Abstract

In thermoplastic pultrusion process, unidirectional glass fibre bundles are very often used as reinforcement. This study was motivated by the industrial requirement to evolve from low viscosity thermoset resin processes to high viscosity thermoplastic polymers. The key parameters to control the impregnation process are the permeability of the fibrous reinforcement and the capillary pressure. The current study's objectives are threefold: (1) study the fibres arrangement by X-ray tomography, (2) determine the longitudinal and transversal permeabilities as well as capillary pressure to use them as input parameters of impregnation process in pultrusion and (3) carry out sensitivity analyses of the permeability measurements to the perturbation of fibre structure. To reach these purposes, two theoretical models were used to determine both axial and transversal tow permeability. The axial impregnation of aligned fibres was described by Washburn equation applied to 1D infiltration into the bundles. The in-plane impregnation was described by Darcy's law. The elliptical equation for highly anisotropic medium was resolved. Results show that permeability measurements are subjected to large variations, caused by perturbation of the fibre architecture during experiments. Besides, it was shown that the tensile force applied on fibres during pultrusion has a great effect on impregnation. Indeed, the permeability increases with the applied tension.

Keywords

Pultrusion impregnation X-ray microtomography permeability capillary pressure tensile force

Get full access to this article

View all access options for this article.

References

Koubaa

Le Corre

Burtin

. Thermoplastic pultrusion process: modeling and optimal conditions for fibers impregnation. J Reinforc Plast Compos 2012. DOI: 10.1177/0731684413489851.

Ken Han

William Lee

Rice

. Measurements of the permeability of fibre preforms and applications. Compos Sci Technol 2000; 60: 2435–2441.

Ouagne

Bréard

. Continuous transverse permeability of fibrous media. Compos: Part A 2010; 41: 22–28.

Salvo

Cloetens

Maire

. X-ray micro-tomography an attractive characterisation technique in materials science. Nucl Instrum Meth Phys Res 2003; 200: 273–286.

Taud

Martinez-Angeles

Parrot

J-F

. Porosity estimation method by X-ray computed tomography. Petrol Sci Eng 2005; 47: 209–217.

Adams

K-L

Miller

Rebenfeld

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

Amico

S-C

Lekakou

. Axial impregnation of a fibre bundle part 1: capillary experiments. Polym Compos 2002; 26: 249–263.

Verleye

Lomov

S-V

Long

. Permeability prediction for the meso-macro coupling in the simulation of the impregnation stage of resin transfer moulding. Compos: Part A 2010; 41: 29–35.

Bechtold

Lin

. Influence of fibre distribution on the transverse flow permeability in fibre bundles. Compos Sci Technol 2003; 63: 2069–2079.

10.

Simacek

Advani

S-G

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

11.

Van West

Byron Pipes

Advani

S-G

. The consolidation of commingled thermoplastic fabrics. Polym Compos 1991; 12: 417–427.

12.

Dullien

F-A-L

. Porous media: fluid transport and pore structure, 2nd ed. New York: Academic press, 1992.

13.

Sharabaty

Biguenet

Depuis

. Investigation on moisture transport through polyester/cotton fabrics. Indian J Fibre Textil Res 2008; 33: 419–425.

14.

Binetruy

Hilaire

Pabiot

. Tow impregnation model and void formation mechanisms during RTM. J Compos Mater 1998; 32: 223–245.

15.

Schell

JSU

Siegrist

Ermanni

. Experimental determination of the transversal and longitudinal fibre bundle permeability. Appl Compos Mater 2007; 14: 117–128.

16.

Schell

JSU

Deleglise

Binetruy

. Numerical prediction and experimental characterisation of meso-scale-voids in liquid composite moulding. Compos Part A: Appl Sci Manuf 2007; 38: 2460–2470.

17.

Masoodi

Pillai

K-M

. Darcy's law-based model for wicking in paper-like swelling porous media. Am Inst Chem Eng 2010; 56: 2257–2267.

18.

Siebold

Walliser

Nardin

. Capillary rise for thermodynamic characterization of solid particle surface. J Colloid Interface Sci 1997; 186: 60–70.

19.

Siebold

Nardin

Schultz

. Effect of dynamic contact angle on capillary rise phenomenon. J Colloid Interface Sci 1997; 161: 81–87.

20.

Wang

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

21.

Fisher

L-R

Lark

P-D

. An experimental study of the washburn equation for liquid flow in very fine capillaries. J Colloid Interface Sci 1979; 69: 486–492.

22.

Bayramli

Powell

R-L

. Experimental investigation of the axial impregnation of oriented fiber bundles by capillary forces. Colloids Surface 1991; 56: 83–100.

23.

Chan

A-W

Hwang

S-T

. Anisotropic in-plane permeability of fabric media. Polym Eng Sci 1991; 31: 1233–1239.

24.

Binetruy

Hilaire

Pabiot

. The influence of fiber wetting in resin transfer molding: scale effects. Colloids Surface 1991; 56: 83–100.

25.

Pillai

K-M

Advani

S-G

. Wicking across a fiber bank. Colloids Surface 1996; 183: 100–110.

26.

Chen

Papathanasiou

T-D

. Micro-scale modeling of axial flow through unidirectional disordered fiber arrays. Compos Sci Technol 2007; 67: 1286–1293.

27.

Chen

Papathanasiou

T-D

. On the variability of the Kozeny constant for saturated flow across unidirectional disordered fiber arrays. Compos: Part A 2006; 37: 836–846.

28.

Dungan

F-D

Senoguz

M-T

Sastry

A-M

. On the use of Darcy permeability in sheared fabrics. Reinf Plast Compos 1999; 18: 472–484.

29.

Skartsis

Khomami

Kardos

J-L

. Resin flow through fiber beds during composite manufacturing processes. Part II: numerical and experimental studies of Newtonian flow through ideal and actual fiber beds. Polym Eng 1992; 32: 231–239.

30.

Scholz

Gillepsie

J-W

Heider

. Measurement of transverse permeability using gaseous and liquid flow. Compos: Part A 2007; 38: 2034–2040.

31.

Slade

Pillai

K-M

Advani

S-G

. Investigation of unsaturated flow in woven, braided and stitched fiber mats during mold-filling in resin transfer molding. Polym Compos 2001; 22: 491–505.

32.

Sadiq

TA-K

Advani

S-G

Parnas

R-S

. Experimental investigation of transverse flow through aligned cylinders. Multiphas Flow 1995; 21: 755–774.

33.

Bayramli

Powell

R-L

. The normal (transverse) impregnation of liquids into axially oriented fiber bundles. Colloids Interface Sci 1989; 138: 346–353.

34.

Badel

Vidal-Sallé

Maire

. Simulation and tomography analysis of textile composite reinforcement deformation at the mesoscopic scale. Compos Sci Technol 2008; 68: 2433–2440.

35.

Klunker F and Ziegmann G. An approach for multiscale flow with a multidimensional model. SEICO 07, Paris, France, 2007.

36.

Breard

Henzel

Trochu

. Analysis of dynamic flows through porous media. Part I: comparison between saturated and unsaturated flows in fibrous reinforcements. Polym Compos 2003; 24: 391–408.

37.

Arbter

Beraud

Binetruy

. Experimental determination of the permeability of textiles: a benchmark exercise. Composites 2011; 12: 1157–1168.

Investigation of capillary impregnation for permeability prediction of fibrous reinforcements

Abstract

Keywords

Get full access to this article

References