Compaction of e-glass fabric preforms in the vacuum infusion process: (a) use of characterization database in a model and (b) experiments

Abstract

Compaction of e-glass fabric preforms (random, woven and biaxial) embedded with a distribution medium (polypropylene) is coupled with 1D resin (polyester) flow during initial application of vacuum, mold filling and fiber relaxation stages of vacuum infusion. In our previous study,1 the compaction characterization procedure had been designed and conducted to realistically model the compaction behavior of fiber preforms in vacuum infusion such that the loading was done on a dry specimen; fiber settling was allowed under constant compaction pressure; unloading was done after the specimen was wetted and the fiber relaxation was characterized at constant pressure. To investigate the effects of characterization components on the part thickness evolution, two compaction models (“unloading only” and “unloading and time-dependent relaxation”) were coupled with two models of flow (“uncoupled” and “coupled” pressure-thickness-permeability). The results of the coupled model of “unloading and time-dependent relaxation” and “coupled pressure-thickness-permeability” was the closest to the vacuum infusion experiments.