Towards understanding the hole making performance and chip formation mechanism of thermoplastic carbon fibre/ polyetherketoneketone composite

Here, we report the first study on the hole making performance of thermoplastic carbon fibre/polyetherketoneketone (CF/PEKK) composite. Different hole making methods (conventional drilling vs. helical milling) have been compared and the effect of different feed rates has been investigated. The effect of thermalmechanical interaction on the resulting hole damage has been elucidated for the first time for carbon fibre reinforced thermoplastics (CFRTPs) hole making. In the material science dimension, advanced material characterization techniques have been deployed to reveal the material removal mechanisms at microscopic scale and unveil the underlying material structural change at a molecular level. Results show that the delamination damage of CF/PEKK is a result of the thermal-mechanical interaction. For conventional drilling, the high machining temperature (at low feed rate 0.1 mm/rev) has a stronger influence on the delamination damage and the delamination starts to show stronger dependence on the thrust force at high feed rate 0.1 mm/rev. In contrast, helical milling generates a much higher machining temperature which plays a more predominant role in the associated delamination damage. Microstructural analysis shows that all the hole surfaces feature matrix smearing, as a result of combined in-plane shear stress and high machining temperature. Conventional drilling leads to more severe hole wall microstructural damage (matrix loss and surface cavity) as compared to helical milling. Finally, thermal analysis reveals that the hole making process has led to significantly increased crystallinity in the PEKK matrix as a result of the strain-induced crystallization under the combined effect of shear stress and high temperature.

Automated summary

This study investigates the hole making performance of thermoplastic carbon fibre/polyetherketoneketone (CF/PEKK) composite, comparing different methods (conventional drilling vs. helical milling) and feed rates. The research also reveals the effect of thermal-mechanical interaction on hole damage and utilizes advanced material characterization techniques to analyze material removal mechanisms and structural changes. Results show that delamination damage is influenced by machining temperature and thrust force, with helical milling generating higher temperatures and more severe microstructural damage compared to conventional drilling.