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Parametric Optimization of Cutting Parameters of Laser Assisted Cutting Using Taguchi Analysis and Genetic Algorithm

Sandeep Kumar Singh*, Swati Gangwar**
* PG Scholar, MMMUT, Gorakhpur, Uttar Pradesh, India.
** Assistant Professor, MMMUT, Gorakhpur, Uttar Pradesh, India.
Periodicity:February - April'2016
DOI : https://doi.org/10.26634/jfet.11.3.5924

Abstract

Laser Beam Machining (LBM) is one of the most advanced machining processes that is used for shaping, cutting and machining the virtually whole varieties of engineering materials. In LBM, the surface roughness and kerf taper significant factors affects the product characteristics and quality of the product. During this analysis work, the impact of process parameters like cutting speed, frequency and Gas pressure surface roughness (Ra) of steel (AISI 321 stainless steel) material in laser cutting machining are studied. L9 orthogonal array was generated for fractional factorial design (Taguchi analysis) for better understanding of the interaction among the process parameters. The values of surface roughness for steel were calculated by Regression model equations, and Taguchi Analysis and Genetic Algorithm were employed to the parametric analysis of the experimental data. Taguchi analysis gives the optimum values of surface roughness and kerf taper, which are 2.2981 μm and 0.1637° respectively. Genetic algorithm was used for providing a set of optimum values for both outputs simultaneously.

Keywords

 Laser Beam Machining (LBM), Surface Roughness, Kerf Taper, Taguchi Analysis, Genetic Algorithm

How to Cite this Article?

 Singh, S. K., and Gangwar, S. (2016). Parametric Optimization of Cutting Parameters of Laser Assisted Cutting Using Taguchi Analysis and Genetic Algorithm. i-manager’s Journal on Future Engineering and Technology, 11(3), 36-42. https://doi.org/10.26634/jfet.11.3.5924

References
[2]. J. R. Duflou, E. Fallahi Sichani, J. De Keuster, and J.P. Kruth, (2009). “Development of a real time monitoring and adaptive control system for Laser Flame Cutting”. Conference Proceedings, ICALEO 2009.
[3]. John Ion, (2005). “Laser processing of engineering materials: Principles, Procedure and Industrial Application”. Elsevier Butterworth-Heinemann, pp. 347- 365.
[4]. N. Rajaram, J. Sheikh-Ahmad and S.H. Cheraghi (2003). "CO2 laser cut quality of 4130 steel”. International Journal of Machine Tools & Manufacture, Vol. 43, pp. 351- 358.
[5]. S. P. H. Narendra B. Dahotre, (2008). Laser Fabrication and Machining of Materials. Newyork: Springer, pp. 34- 38.
[6]. William Steen and Jyoti Mazumder (2008). Laser Material Processing. London: Springer-Verlag, 2008.
[7]. M. Madic, M. Radovanovic, M. Trajanovic, and M. Manic, (2015). “Multi objective optimization of laser cutting using cuckoo search algorithm”. Journal of Engineering Science and Technology, pp. 353-363.
[8]. Avanish Kumar Dubey and Vinod Yadava, (2008). “Laser beam machining - A Review”. International Journal of Machine Tools & Manufacture, pp. 609-628.
[9]. K. Venkatesan, R. Ramanujam, and P. Kuppan, (2014). “Analysis of cutting forces and temperature in laser assisted machining of Inconel 718 using Taguchi th Method”. 12 Global Congress on Manufacturing and Management (GCMM), (2014), Vol. 97, pp. 1637-1646.
[10]. M. Lakshmi Chaitanya, and A. Gopala Krishna, (2013). "Multi objective optimization of laser beam cutting process". IJRMET, Vol. 3, No. 2.
[11]. Ruben Phipon and B.B. Pradhan, (2012). “Control parameters optimization of laser beam machining using genetic algorithm” .International Journal of Computational Engineering Research, Vol. 2, No. 5.
[12]. Koji Hirano and Remy Fabbro, (2011). “Experimental observation of hydrodynamics of melt layer and striation generation during laser cutting of steel”. Physics Procedia, pp. 555-564.
[13]. R. Singh, S.N Melkote, (2011). “Characterization of a hybrid laser assisted mechanical micromachining (LAMM) process for a difficult to machine materials”. International Journal of Machine Tools & Manufacture, pp. 1139-1150.
[14]. A. K. Dubey and Vinod Yadava, (2008). “Optimization of kerf quality during pulsed laser cutting of aluminium alloy sheet”. Journal of Materials Processing Technology, pp. 412-418.
[15]. A. Sharma and Y. Vinod, (2012). “Modelling and optimization of cut quality during pulsed Nd:YAG laser cutting of thin Al-alloy sheet for straight profile”. Optics and Laser Technology, pp. 159-168.
[16]. K. Abdel Ghany and N. Newishy, (2005). “Cutting of 1.2 mm thick austenitic stainless steel sheet using pulsed and CW Nd:YAG laser”. Journal of Materials Processing Technology, pp. 438-447.
[17]. P. Di Pietro and Y. L. Yao, (1994). “An investigation into characterizing and optimizing laser cutting quality”. International Journal of Machine Tools and Manufacture, pp. 225-243.
[18]. A. F. H. Kaplan, (1995). “An analytical model of metal cutting with a laser beam”. Journal of Applied Physics, pp. 2198-2208.
[19]. B.S. Yilbas and A. Kar, (1998). “Thermal and efficiency analysis of CO2 laser cutting process”. Optics and Lasers in Engineering, pp. 17-32.
[20]. Anon, “Facts about laser cutting techniques- report”. AGA Group Ltd, pp. 3-18.
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