Investigation of the Influence of Tool Rake Angles on Machining of Inconel 718

• Published in: Journal of Manufacturing and Materials Processing Vol. 5; no. 3; p. 100
• Main Authors: Xu, Dongdong, Ding, Liang, Liu, Yang, Zhou, Jinming, Liao, Zhirong
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.09.2021
• Subjects: Aerospace safety; Bearbetnings-, yt- och fogningsteknik; Carbide cutting tools; Composite materials; Cutting force; Cutting parameters; cutting temperature; Cutting tools; Deformation; Engineering and Technology; Experiments; Force distribution; Geometry; Inconel 718; Integrity; Machine tools; Machining; Manufacturing, Surface and Joining Technology; Materials Engineering; Materialteknik; Mechanical properties; Metallurgy; Methods; nano-hardness; Nickel base alloys; Numerical analysis; Numerical methods; Rake angle; Rake faces; Residual stress; Safety critical; Scanning electron microscopy; Simulation; Strain hardening; Superalloys; surface integrity; Teknik; Temperature distribution; Tool wear; Workpieces
• ISSN: 2504-4494; 2504-4494
• DOI: 10.3390/jmmp5030100

It is essential for superalloys (e.g., Inconel 718) to obtain an anticipated surface integrity after machining, especially for safety critical areas (e.g., aerospace). As one of the main characteristics for cutting tools, the rake angle has been recognized as a key factor that can significantly influence the machining process. Although there are large research interests and outcomes in the machining of nickel-based superalloys, most of them focus on the surface integrity and macroscale temperature observation, whereas the temperature distribution in the tool rake face is not clear. Thus, it is necessary to investigate the basic role of rake angles and the tool–workpiece interaction mechanism to determine the machining condition variations and surface integrity. In the present study, both experimental and numerical methods are employed to explore the cutting force, thermal distribution, and shear angles during the process and the metallurgy characteristics of the subsurface after machining, as well as the mechanical properties. The research has emphasized the importance of rake angles on both the cutting process and machined surface integrity, and has revealed the microscale temperature distribution in the tool rake face, which is believed to have a close relationship with the tool crater wear. In addition, it is clearly presented that the surface generated with positive rake angle tools generates the minimum subsurface deformation and less strain hardening on the workpiece.