In‐Situ Fiberized Poly(ethylene terephthalate) as a Reinforcement to Poly(propylene) Matrix

The reinforced poly(propylene) (PP)/poly(ethylene terephthalate) (PET) in‐situ fiberized composites were prepared by extrusion‐drawing‐injection molding. The influences of PET weight fraction ( f w ) on the PET fiberization, phase morphology, and mechanical properties of the composites, together with their functional mechanisms were studied by contrast to the normal‐blended materials without drawing. The results show that as the f w rises from 0 to 20%, the number of PET fibers increases, whereas their diameter and dispersity decrease till f w  = 15% and then increase, and the number of remained PET particles tends to rise. These changes of PET fiberization and phase morphology with f w were attributed to the consequence of the combined actions of breakup, coalescence, and deformation of the PET dispersed phase in the PP matrix during the extrusion drawing. Correspondingly, the tensile strength ( σ t ) and Young's modulus ( E ) of the in‐situ composites increase till f w  = 15% and then decrease, with maximum gains of σ t and E of about 20 and 70% relative to the neat PP, respectively. This σ t / f w relation was ascribed to the counterbalanced result between the reinforcing effect of the dispersed phase on matrix and the interfacial flaw effect of two immiscible phases, while the E / f w relation was considered as a representation of the rigidizing effect of the fibers on the matrix being controlled by both their number and diameter.In‐situ PET fibres (PET/PP = 85/15) in an as‐drawn filament.