Effect of tool wear on machining quality in milling Cf/SiC composites with PCD tool

• Published in: Journal of manufacturing processes Vol. 105; pp. 370 - 385
• Main Authors: Kang, Renke, Ma, Haonan, Wang, Zhongwang, Dong, Zhigang, Bao, Yan
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 03.11.2023
• Subjects: Cf/SiC composites; Machining quality; Polycrystalline diamond (PCD) tool; Tool wear; Wear mechanism; Cf/SiC composites; Wear mechanism; Polycrystalline diamond (PCD) tool; Machining quality; Tool wear
• ISSN: 1526-6125; 2212-4616
• DOI: 10.1016/j.jmapro.2023.08.055

Carbon fiber reinforced silicon carbide ceramic matrix (Cf/SiC) composites have great application potential in aerospace. But their high hardness and anisotropy cause rapid tool wear during machining, which affects machining quality and efficiency. However, tool wear mechanisms in milling Cf/SiC composites are still unclear. There is a lack of research on the relationship between tool wear and cutting performance. In this paper, milling experiments on 2.5D Cf/SiC composites were conducted using polycrystalline diamond (PCD) cutters. The tool wear mechanisms and effect of tool wear on surface roughness, milling force, burr damage, surface microstructure and chips were explored. The results show that abrasive wear caused by chips continuously scraping tool material and diamond particle fragmentation and falling off caused by sprouting and expansion of cracks inside grain were primary causes of tool failure. The formation mechanism of burr damage was analyzed. It was proved that the peak radius of cutting edge Rpeak and flank wear VB could reflect cutting capabilities. It was found that increasing flank wear had regrinding effects on the cutting edge, which affects the peak radius. The degree of burr damage was related to these two parameters. Tool wear changed the surface formation mechanism. Before tool wear, carbon fibers were primarily removed through the micro-brittle fracture, with low surface roughness. The flank face and chips scratched the workpiece like abrasive grains after tool wear, leaving scratches on the surface and increasing surface roughness from 1.27 μm to 2.25 μm.