Resin transfer molding (RTM) has become a popular technique for fabrication
of composite parts. During the mold Ailing stage, the resin is forced to f
low into pore spaces between tow filaments and the between the tows themsel
ves. Voids trapped in the composite during the filling stage are believed t
o be the consequence of the non-uniform micro-flows inside fiber bundles an
d macro-flows between them. Thus, to minimize the void formation, the proce
ssing parameters should be determined to generate a uniform front. In this
case, the flow inside tows Is driven by both the injection pressure and the
capillarity forces and matches the flow outside the tows, which is driven
only by pressure. To control such a flow, both viscous and capillarity flow
s have to be known at all scales of the fibrous structure. For this purpose
, the wetting effects at the different scales (ranging ii-om the individual
tow to the multi-layers reinforcements) are investigated. Original experim
ents are carried out to visualize micro-flows and to measure the capillarit
y flow rates. Wicking effects are quantified in terms of the overall and lo
cal effective permeabilities. A new parameter that accounts for interaction
s between flows splitting in macro- and micro-flows is introduced. Practica
l ways to reduce voids entrapment are also discussed.