Abstract
This paper presents a comprehensive study on the complex drill-exit temperature characteristics in the drilling of unidirectional (UD) and multidirectional (MD) CFRPs using a state-of-art microscopy infrared imaging system. For the first time, temperature variation and distribution at drill exit have been revealed in full detail, associated with the CFRP material properties and drilling conditions. Results suggest that the actual drill/CFRP interactions have critical but similar effects on the drill-exit temperatures for UD and MD CFRPs. Specifically, three distinct cutting regions with varying temperature characteristics are evident when the main cutting edge is acting on the drill exit material. In all cases, the temperature distribution features elliptical shape, of which the eccentricity depends on the lay-up sequence and the drilling depth. In addition, the real-time temperature profiles and 2D/3D maximum temperature distribution maps are created with high visualization. With the aid of those findings, the relationships between drilling temperature maxima, their locations and drilling depths have been discovered and temperature effects on drill-exit damages have been elucidated for the first time. MD CFRP is proven more difficult to achieve high drilling qualities at certain fiber cutting angles than UD CFRP due to the associated temperature effects. Such important knowledge enables the identification of the heat affected zones and subsequently informs strategies for reducing the negative temperature effects.
Highlights
Due to their superior specific strength/stiffness and excellent fatigue resistance, carbon fiber reinforced polymer/plastic (CFRP) composites are highly favorable in the manufacturing of lightweight components with enhanced structural efficiency in the fields of aerospace, transportation and energy, etc
This paper presents a comprehensive study on the complex drill-exit temperature characteristics in the drilling of unidirectional (UD) and multidirectional (MD) CFRPs using a state-of-art microscopy infrared imaging system
This paper presents a comprehensive experimental study on the complex temperature characteristics at drill exit in the drilling of UD and MD CFRPs based on infrared thermography
Summary
Due to their superior specific strength/stiffness and excellent fatigue resistance, carbon fiber reinforced polymer/plastic (CFRP) composites are highly favorable in the manufacturing of lightweight components with enhanced structural efficiency in the fields of aerospace, transportation and energy, etc. The cutting temperature usually reaches the maxima at the CFRP drill exit [4,7] This further worsens the drill-exit damages [14] and the serious drilling damages will degrade the International Journal of Machine Tools and Manufacture 135 (2018) 24–37 mechanical properties of the machined CFRP components [15,16]. Those direct and indirect negative effects of high drilling temperatures have brought great challenges to quality control. The in-depth knowledge will enable effective evaluation and optimization of the drilling process, inform the design and analysis of composites and cutting tools, and advance the future CFRP manufacturing technology towards greater manufacturing efficiency and cost reduction
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