Authors: Moaz H. Ali, M. N. M. Ansari

Abstract:

This paper presents a study the effect of nose radius (Rz-mm) on cutting force components and temperatures during the machining simulation in an orthogonal cutting process for titanium alloy (Ti-6Al-4V). The cutting process was performed at various nose radiuses (Rz-mm) while the depth of cut (d-mm), feed rate (fmm/ tooth) and cutting speed (vc-m/ min) were remained constant. The main cutting force (Fc), feed cutting force (Ft) and temperatures were estimated by using finite element modeling (FEM) through ABAQUS/EXPLICIT software and the simulation was developed the two-dimension via an orthogonal cutting process during machining titanium alloy (Ti-6Al-4V). The results led to the conclusion that the nose radius (Rz-mm) has affected directly on the cutting force components. However, temperature gave no indication or has no significant relation with nose radius during machining titanium alloy (Ti-6Al-4V). Hence, any increase or decrease in the nose radius (Rzmm) during machining operation led to effect on the cutting forces and thus it will be effective on surface finish, quality, and quantity of products.

Keywords: Finite element modeling (FEM), nose radius, cutting force, temperature, titanium alloy (Ti-6Al-4V).

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1100757

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2966

References:

[1] Xiaoping Yang and C. Richard Liu, Machining titanium and its alloys. Machining Science and Technology, 1999; 3 (1), pp. 107-139.
[2] S. K. Bhaumik, C. Divakar, and A. K. Singh, Machining Ti-6AI-4V Alloy with a WBN-CBN Composite Tool. Materials & Design, 1995; 16 (4), pp. 221-226.
[3] A. R. Machado and J. Wallbank, Machining of Titanium and Its Alloys: A Review. Journal of Engineering Manufacture, 1990; 204, pp. 53-60.
[4] H. E. Trucks, Machining Titanium Alloys. Machine and Tool Blue Book, 1987; 82 (I), pp. 39-41.
[5] Geoffrey Boothroyd, Winston A. Knight, Fundamentals of machining and machine tools, 3rd Ed. 2005.
[6] WU Hong-bing, Xu Chengguang, Jia Zhi-xin, Establishment of constitutive model of titanium alloy Ti6Al4V and validation of finite element. IEEE DOI 10.1109/ICMTMA.2010.555.
[7] HKS Inc., USA ABAQUS/Standard User’s Manual, Version 5.8, 1998.
[8] Donald R. Lesuer, “Experimental investigations of material for Ti-6Al- 4V titanium and 2024-T3 aluminum”. U.S. Department of Transportation Federal Aviation Administration Final Report Office of Aviation Research: Washington, DC 20591.
[9] M.S. ElTobgy, E. Ng, M.A. Elbestawi, Finite element modeling of erosive wear. International Journal of Machine Tools & Manufacture, 2005; 45, pp. 1337–1346.
[10] T. Ozel, Y. Karpat, Identification of constitutive material model parameters for high strain rate metal cutting conditions using evolutionary computational algorithms. Mater. Manuf. Process, 2007; 22 (5-6), pp. 659-667.
[11] Zhang, Y.C., et al., Chip formation in orthogonal cutting considering interface limiting shear stress and damage evolution based on fracture energy approach. Finite Elements in Analysis and Design 2011; 47 (7), pp 850-863.