i-manager Publications

Taguchi Multiple Performance Characteristics Optimization In Machining Of AISI 4340 Steel Using Utility Function

Munish Kumar Gupta*, Pardeep Kumar Sood**, Gauravdeep Singh***

*Research Scholar, Department of Mechanical Engineering, National Institute of Technology, Hamirpur, India.

** Workshop Superintendent, Department of Mechanical Engineering, National Institute of Technology, Hamirpur, India.

*** Research Scholar, G.N.D.E.C. Ludhiana, India.

Periodicity:November - January'2015
DOI : https://doi.org/10.26634/jme.5.1.3070

Abstract

This paper aims the development of multi response optimization technique using utility method to predict and select the optimal setting of machining parameters while machining AISI 4340 steel. The experimental studies in machining were carried out under varying conditions of process parameters, such as cutting speed (v), feed rate (f) and different cooling conditions (i.e. dry, wet and cryogenic in which liquid nitrogen used as a coolant) by using uncoated tungsten carbide insert tool. Experiments were carried out as per Taguchi's L9 orthogonal array with the utility concept and multi response optimization were performed for minimization of tool wear (Vc) and specific cutting force (Ks). Next, statistical analysis of variation (ANOVA) and analysis of mean (ANOM) were led to determine the effect of process parameters on responses Vc and Ks based on their P-value and F-value at 95% confidence level. The optimization results proved that, cutting speed 57 m/min, feed rate 0.248 mm/min and cryogenic cooling is required for minimize tool wear and specific cutting force.

Keywords

ANOVA (Analysis of Variation), ANOM (Analysis of Mean), Cutting Speed, Feed Rate, Taguchi, Tool Wear, Cryogenic Cooling

How to Cite this Article?

Gupta, M. K., Sood,P. K., and Singh, G. (2015). Taguchi Multiple Performance Characteristics Optimization in Machining of AISI 4340 Steel Using Utility Function. i-manager’s Journal on Mechanical Engineering, 5(1), 37-43. https://doi.org/10.26634/jme.5.1.3070

References

[1]. Singh J. (2008). “Experimental investigation for tool life enhancement of single point cutting tool with cryogenic treatment”. M.Tech. Thesis, P.T.U. Jalandhar, pp.12-47.

[2]. Aujla H.S., Singh R. (2008). “Applications of cryogenic treatment for enhancing the machining properties of titanium alloy (Ti-6Al-4V)”, Manufacturing Technology Today, Vol. 7, pp.22-26.

[3]. Singh K. (2009). “Study of the effect of cryogenic treatment on various tools for machining cost reduction: A case study” M.Tech. Thesis, P.T.U. Jalandhar, pp. 10-32.

[4]. Armarego EJA, Brown RH. (1969). “ The machining of metals”, New Jersey: Prentice-Hall.

[5]. Boothroyd G. (1965). “Fundamentals of metal machining”, Washington: Edward Arnold.

[6]. Baradie MA EI. (1996). “Cutting Fluids: Part I. Characterisation”. J. Mater. Process. Technol. Vol.56, pp. 789-797

[7]. Gaitondea V.N., Karnik S.R., Davim Paulo J. (2008). “Selection of optimal MQL and cutting conditions for enhancing machinability in turning of brass”. Journal of materials processing technology, Vol.204, pp.459–464

[8]. Hong S. Y. and Ding Y. (2001). “Cooling approaches and cutting temperatures in cryogenic machining of Ti-6Al- 4V”. International Journal of Machine Tools and Manufacture, Vol.41 (10), pp.1417-1437

[9]. Werthem, R. and Rotberg, J. “Influence of high pressure flushing through the rake face of the tool”. Annals CIRP, Vol. 41 (1), 101-106.

[10]. Bartley EW. Machinery (E) 1953:83.

[11]. Hollis WS. “The application of controlled atmosphere in machining of metals”. Int J Mach Tool Des, Vol.1, pp.59–78.

[12]. Uhera K, Kumagai S. (1968). “Chip formation, surface roughness, cutting forces and tool wear in cryogenic machining”. Annals CIRP, Vol.17, No.1, pp.93-98.

[13]. Chattopadhyay AB, Roy TK, Bhattacharyya A. (1972). “Application of cryogenics in metal cutting”. J Inst Eng (India).

[14]. Paul S, Dhar NR, Chattopadhyay AB. “Beneficial effects of cryogenic cooling over dry and wet machining on tool wear and surface finish in turning AISI 1060 steel”. J Mater Process Technol , Vol. 116, pp.44–8.

[15]. Hong SY, Markus I, Jeong W. (2001). “New cooling approach and tool life improvement in cryogenic machining of titanium alloy Ti–6Al–4V”. Int J Mach Tools Manuf , Vol. 41, pp.2245–60.

[16]. Çakir O, Kiyak M, Altan E. (2004). “Comparison of gases applications to wet and dry cuttings in turning”. J Mater Process Technol, Vol.153–154, pp.35–41.

[17]. Liu J, Han R, Sun Y. (2005). “Research on experiments and action mechanism with water vapor as coolant and lubricant in Green cutting”. Int J Mach Tools Manuf, Vol. 45, pp.687–94.

[18]. Dhar N.R., Kamruzzaman, M. (2007). “Cutting temperature, tool wear, surface roughness and dimensional deviation in turning of AISI 4037 steel under cryogenic condition”. International Journal of machine tools and manufacture, Vol. 47, pp.754-759.

[19]. Kumar, P., Barua, P.B., Gaindhar, J.L. (2000). “Quality optimization (multi-characteristic) through Taguchi's technique and utility concept”. Qual. Reliab. Eng. Int. Vol. 16, pp.475–485.

[20]. Phadke, M.S. (1989). “Quality Engineering Using Robust Design”. Prentice Hall, Englewood Cliffs, NJ.

[21]. Ross, P.J. Taguchi, (1996). “Techniques for Quality Engineering”. McGraw-Hill, New York .

Taguchi Multiple Performance Characteristics Optimization In Machining Of AISI 4340 Steel Using Utility Function

Abstract

Keywords

How to Cite this Article?

References

If you have access to this article please login to view the article or kindly login to purchase the article

Purchase Instant Access

Options for accessing this content:

	North Americas,UK, Middle East,Europe		India	Rest of world
	USD	EUR	INR	USD-ROW
Pdf	35	35	200	20
Online	35	35	200	15
Pdf & Online	35	35	400	25