Interface-dominated mechanical behavior of CF/PEKK composites according to different heating rate during thermoforming process
While thermoplastic polymers exhibit several desirable properties, their applicability is limited by their high viscosity and extreme processing conditions. To overcome these limitations, in this study, we used the thermoforming process to produce carbon fiber/polyetherketoneketone (CF/PEKK) laminates, which were pre-made through an oven-based consolidation process using prepregs. The laminates were produced at three different heating rates ([Formula: see text]C/min, [Formula: see text]C/min and [Formula: see text]C/min). The laminates produced at the heating rate of [Formula: see text]C/min showed improved interlaminar shear strength, [Formula: see text] tensile strength, and average interlaminar fracture toughness. On the other hand, heating at rates higher than [Formula: see text]C/min increased the initiation value of the interlaminar fracture toughness ([Formula: see text] but resulted in nonuniform composites of poor quality. This is because increasing the heating rate reduced the uniformity of the heat distribution with the laminates, resulting in the polymer molecules exhibiting different binding rates and thus nonuniform cross-linking. Thus, the proposed method is a suitable one for producing high-quality thermoplastic composites.