International Journal of Mechanical Dynamics & Analysis

In this work, finite element simulation of drilling process is performed to study the behavior of twist drill using DEFORM-3D. The purpose of this analysis is to determine the temperature distribution in the drill bit, workpiece and generated chip. A modified Normalized Johnson cook model is considered in this analysis with Northam-Cockroft failure criteria. The workpiece material chosen is AISI 1045 steel. With this analysis using FEM, the drilling process can be well studied without the need for any expensive real-time experimental work.

Cite this Article: M. Anbarasan, N. Senthilkumar, T. Tamizharasan. Modelling and Simulation of Conventional Drilling Process using Deform 3D. International Journal of Mechanical Dynamics & Analysis. 2019; 5(2): 9–16p.

Gardner JD, Dornfeld D. Finite Element Modeling of Drilling Using DEFORM. UC Berkeley: Laboratory for Manufacturing and Sustainability. 2006.

Marusich T, Ortiz M. Finite element study of chip formation in high-speed machining. International Journal for Numerical Methods in Engineering. 1995; 38: 3675–3694.

Huang J, Black J. An evaluation of chip separation criteria for the FEM simulation of machining. ASME Transactions. Journal of Manufacturing Science and Engineering. 1996; 118(4): pp. 545–554.

Klamecki B. Incipient chip formation in metal cutting – a three dimensional element analysis. Ph.D. [Thesis], University of Illinois, Urbana-Champaign. 1973; pp. 1–10.

Guo YB, Dornfeld DA. Finite element modeling of burr formation in drilling 304 stainless steel. ASME Transactions. Journal of Manufacturing Science and Engineering. 2000; 122(4): 612–619.

Klocke F Raedt, H Hoppe S. 2D FEM simulation of the orthogonal

high speed cutting process. ASME Transactions, Machining Science and Technology. 2001; 5(3): 323–340.

Liu G. Liu M. Smoothed Particle Dynamics. Toh Tuc Link, Singapore: World Scientific; 2003.

N Senthilkumar, T Tamizharasan. Effect of tool geometry in turning AISI 1045 steel: experimental investigation and FEM analysis. Arabian Journal for Science and Engineering. 2014; 39(6): 4963–4975.

T Tamizharasan, N Senthil kumar. Numerical simulation of effects of machining parameters and tool geometry using DEFORM-3D: optimization and experimental validation. World Journal of Modelling and Simulation. 2014; 10(1): 49–59.

T Tamizharasan, N Senthilkumar. Optimization of cutting insert geometry using DEFORM-3D: numerical simulation and experimental validation. International Journal of Simulation Modelling. 2012; 11(2): 65–76.

G Hariharan, N Shenbaga Vinayaga Moorthi, N Senthilkumar. A numerical simulation study on drill bit point angle and helix angle during drilling AISI 1045 steel. Proceedings of ICAME-2015. UCEV, Villupuram, Tamil Nadu. 2015, October 15–16. pp. 837–844.

N Senthilkumar, P Gopinathan, B Deepanraj. Parametric optimization of drilling hybrid metal matrix composite using Taguchi-grey relational analysis (ISME-M-113). Proceedings of the 17th ISME Conference. IIT Delhi, New Delhi. 2015, October 3–4.

Strenkowski J, Carroll JA. Finite element model of machining. Journal of Engineering of Industry. 1985; 107: 349–354.

Vijayaraghavan A. Drilling of fiber-reinforced plastics-tool deflection and defect prediction. Master’s Report. University of California, Berkeley. 2005.

N Senthilkumar, Azhagiri Pon, T Tamizharasan. A finite element simulation study on effects of variation in machining and geometrical parameters in turning. Applied Mechanics and Materials. 2014; 592–594: 3–7.