Journal of Production Research & Management

As a propelled producing innovation, which has been created quickly as of late, rapid machining is generally connected in numerous commercial enterprises. The chip arrangement amid fast machining is a convoluted material twisting and expelling process. In examination region of fast machining, the expectation of chip morphology is a hot and troublesome subject. A limited component technique in light of the product ABAQUS which includes Johnson-Cook material model and crack foundation was utilized to mimic the serrated chip morphology and cutting power amid fast machining of AISI 1045 hardened steel. The serrated chip morphology and cutting power were observed and measured by fast machining trial of AISI 1045 hardened steel. The examination shows that the re-enactment results are steady with the trials and this limited component recreation technique exhibited can be utilized to foresee the chip morphology and cutting drive precisely amid rapid machining of hardened steel.

Astakhov VP, Shvets SV. A System Concept in Metal Cutting. J Mater Process Technol. 1997; 79: 189–199p.

Ibrahim Ciftci. Machining of Austenitic Stainless Steels Using CVD Multilayer Coated Cemented Carbide Tools. Tribol Int. 2005; 39: 565–569p.

Ozel T, Zeren E. Finite Element Modeling of Stresses Induced by High Speed Machining with Round Edge Cutting Tools. ASME International Mechanical Engineering Congress & Exposition, IMECE 2005-81046; Orlando, Florida. 2005.

Li Qian, Mohammad Robiul Hossan. Effect on Cutting Force in Turning Hardened Tool Steels with Cubic Boron Nitride Inserts. J Mater Process Technol. 2007; 191: 274–278p.

Saoubi RM, Outerio JC, Umbrello D. Experimental and Numerical Modelling of the Residual Stresses Induced in Orthogonal Cutting of AISI 316L Steel. Int J Mach Tool Manuf. 2006; 46: 1786–1794p.

Uhlmann E, Zettier R. Finite Element Modeling and Cutting Simulation of Inconel 718. Ann CIRP Manuf Technol. 2007; 56(1).

Maria H, Miguelez Jose, Canter L. An Efficient Implementation of Boundary Conditions in an Ale Model for Orthogonal Cutting. J. Theor Appl Mech. 2009; 47(3): 599–616p.

Maranhão C, Paulo Davim J. Finite Element Modelling of Machining of AISI 316 Steel: Numerical Simulation and Experimental Validation. Elsevier, Simul Model Pract Th. 2010; 18(2010): 139–156p.

Nikolas Galanis. Finite Element Analysis of the Cutting Force in Turning of AISI 316L Stainless Steel. Int J Mach Tool Manuf. 2010.

Patil RM, Umasankar Ravat. Experimental Study of Effect of Cutting Parameter on Cutting Force in Dry Turning of SS 316L using Taguchi Method. IIJRE. 2011; 2349–2163p.

Davies MA, Cooke AL, Larsen ER. High Bandwidth Thermal Microscopy of machining AISI 1045 Steel. CIRPAnn Manuf Technol. 2005; 54(1): 63–66p.

Mabrouki T, Rigal J-F. A Contribution to a Qualitative Understanding of Thermo-Mechanical Effects during Chip Formation in Hard Turning. J Mater Process Technol. 2006; 176: 214–221p.

Klocke F, Raedt H-W, Hoppe S. 2D-FEM Simulation of the Orthogonal High Speed Cutting Process. Mach Sci Technol. 2001; 5(3): 323–340p.

Duan C, Cai Y, Li Y. Finite Element Simulation of Cutting Temperature Field during High Speed Machining Hardened Steel Based on ABAQUS. Second International Conference on Intelligent Computational Technology and Automation. 2009.