Cutting force and chip formation in end milling operation when machining nickelbased superalloy, Hastelloy C-2000

Authors

  • N.H. Razak Faculty of Mechanical Engineering, Universiti Malaysia Pahang 26600 Pekan, Pahang, Malaysia
  • M.M. Rahman Faculty of Mechanical Engineering, Universiti Malaysia Pahang 26600 Pekan, Pahang, Malaysia
  • K. Kadirgama Faculty of Mechanical Engineering, Universiti Malaysia Pahang 26600 Pekan, Pahang, Malaysia

DOI:

https://doi.org/10.15282/jmes.11.1.2017.12.0233

Keywords:

Cutting force; chip formation; Hastlelloy C-2000; coated carbide; uncoated carbide.

Abstract

This paper presents an experimental study of the cutting force and chip formation in the end milling of the nickel-based superalloy, Hastelloy C-2000. The experiment was conducted using two different cutting inserts under wet conditions – namely physical vapor deposition coated with TiAlN, and uncoated carbide. The assessment of machining performance is based on a design of experiment. New insight into the influence of the cutting process on the cutting force and chip formation are key measures of machining performance. The effect of the machining parameters on chip formation was examined through scanning electron microscope micrographs and energy dispersive x-ray tests. The cutting forces and chip formation analysis for different sets of experiments were examined and compared in order to establish the most suitable cutting conditions, through highlighting the drawbacks and by suggesting proper measures to be undertaken during machining performance, which might overcome the barriers of machining Hastelloy C2000.

References

Razak NH, Rahman MM, Kadirgama K. Experimental study on surface integrity in end milling of hastelloy c-2000 superalloy. International Journal of Automotive and Mechanical Engineering. 2014;9:1578-87.

Sahaya Anand TJ. Nickel as an alternative automotive body materials. Journal of Mechanical Engineering and Sciences. 2012;2:187-97.

Kadirgama K, Rahman MM, Ismail AR, Bakar RA. Finite element analysis of hastelloy c-22hs in end milling. Journal of Mechanical Engineering and Sciences. 2011;1:37-46.

M'Saoubi R, Outeiro JC, Chandrasekaran H, Dillon Jr OW, Jawahir IS. A review of surface integrity in machining and its impact on functional performance and life of machined products. International Journal of Sustainable Manufacturing. 2008;1:203-36.

Guo YB, Yen DW. A fem study on mechanisms of discontinuous chip formation in hard machining. Journal of Materials Processing Technology. 2004;155:1350-6.

Razak N, Rahman M, Kadirgama K. Experimental study on surface integrity in end milling of hastelloy c-2000 superalloy. International Journal of Automotive and Mechanical Engineering. 2014;9:1578-87.

Razak NH, Rahman MM, Kadirgama K. Investigation of machined surface in end-milling operation of hastelloy c-2000 using uncoated-carbide insert. Advanced Science Letters. 2012;13:300-5.

Razak NH, Rahman MM, Kadirgama K. Response surface design model to predict surface roughness when machining hastelloy c-2000 using uncoated carbide insert. IOP Conference Series: Materials Science and Engineering2012. p. 012022.

Isik Y. Investigating the machinability of tool steels in turning operations. Materials & Design. 2007;28:1417-24.

Najiha M, Rahman M, Kadirgama K. Performance of water-based tio2 nanofluid during the minimum quantity lubrication machining of aluminium alloy, aa6061-t6. Journal of Cleaner Production. 2016;In press.

Yusoff AR, Mohamed Suffian MRZ, Taib MY. Literature review of optimization technique for chatter suppression in machining. Journal of Mechanical Engineering and Sciences. 2011;1:47-61.

Khan MAR, Rahman MM, Kadirgama K, Maleque MA, Ishak M. Prediction of surface roughness of ti-6al-4v in electrical discharge machining: A regression model. Journal of Mechanical Engineering and Sciences. 2011;1:16-24.

Najiha MS, Rahman MM, Kadirgama K. Minimum quantity lubrication: Quantifying non-deterministic component of sustainability index for machining operations. International Journal of Automotive and Mechanical Engineering. 2016;13:3190-200.

Mohanty S, Routara BC. A review on machining of metal matrix composites using nanoparticle mixed dielectric in electro-discharge machining. International Journal of Automotive and Mechanical Engineering. 2016;13:3518-39.

Najiha MS, Rahman MM, Kadirgama K. Machining performance of aluminum alloy 6061-t6 on surface finish using minimum quantity lubrication. International Journal of Automotive and Mechanical Engineering. 2015;11:2699-712.

Rahman MM, Kadirgama K, Noor MM, Ramasamy D. Optimization of abrasive machining of ductile cast iron using tio2 nanoparticles: A multilayer perceptron approach. ARPN Journal of Engineering and Applied Sciences. 2016;11:2529-34.

Muthusamy Y, Kadirgama K, Rahman MM, Ramasamy D, Sharma KV. Wear analysis when machining aisi 304 with ethylene glycol/tio2 nanoparticle-based coolant. International Journal of Advanced Manufacturing Technology. 2016;82:327-40.

Najiha MS, Rahman MM, Kadirgama K. Experimental investigation and optimization of minimum quantity lubrication for machining of aa6061-t6. International Journal of Automotive and Mechanical Engineering. 2015;11:2722-37.

Fang N, Wu Q. A comparative study of the cutting forces in high speed machining of ti–6al–4v and inconel 718 with a round cutting edge tool. Journal of Materials Processing Technology. 2009;209:4385-9.

Li HZ, Zeng H, Chen XQ. An experimental study of tool wear and cutting force variation in the end milling of inconel 718 with coated carbide inserts. Journal of Materials Processing Technology. 2006;180:296-304.

Krain HR, Sharman ARC, Ridgway K. Optimisation of tool life and productivity when end milling inconel 718tm. Journal of Materials Processing Technology. 2007;189:153-61.

Zhang S, Li JF, Wang YW. Tool life and cutting forces in end milling inconel 718 under dry and minimum quantity cooling lubrication cutting conditions. Journal of Cleaner Production. 2012;32:81-7.

Astakhov VP. Tribology of metal cutting. Mechanical Tribology, New York: Marcel Dekker. 2004:307-46.

Cristino VAM, Rosa PARC, Martins PAF. Tribology in metal cutting. Tribology for scientists and engineers: Springer; 2013. p. 677-728.

Shih AJ, Luo J, Lewis MA, Strenkowski JS. Chip morphology and forces in end milling of elastomers. Journal of Manufacturing Science and Engineering. 2004;126:124-30.

Nakayama K, Arai M. Comprehensive chip form classification based on the cutting mechanism. CIRP Annals-Manufacturing Technology. 1992;41:71-4.

Outeiro JC, Pina JC, M'saoubi R, Pusavec F, Jawahir IS. Analysis of residual stresses induced by dry turning of difficult-to-machine materials. CIRP Annals-Manufacturing Technology. 2008;57:77-80.

Devillez A, Le Coz G, Dominiak S, Dudzinski D. Dry machining of inconel 718, workpiece surface integrity. Journal of Materials Processing Technology. 2011;211:1590-8.

Pusavec F, Hamdi H, Kopac J, Jawahir IS. Surface integrity in cryogenic machining of nickel based alloy—inconel 718. Journal of Materials Processing Technology. 2011;211:773-83.

M’saoubi R, Outeiro JC, Changeux B, Lebrun JL, Dias AM. Residual stress analysis in orthogonal machining of standard and resulfurized aisi 316l steels. Journal of Materials Processing Technology. 1999;96:225-33.

Ezugwu EO, Wang ZM, Okeke CI. Tool life and surface integrity when machining inconel 718 with pvd-and cvd-coated tools. Tribology Transactions. 1999;42:353-60.

Jindal PC, Santhanam AT, Schleinkofer U, Shuster AF. Performance of pvd tin, ticn, and tialn coated cemented carbide tools in turning. International Journal of Refractory Metals and Hard Materials. 1999;17:163-70.

Hynes International. Http://www.Haynesintl.Com/. Retrived on 16 June 2017.

Astakhov VP. Tribology of metal cutting: Elsevier; 2006.

Aykut Ş, Bagci E, Kentli A, Yazıcıoğlu O. Experimental observation of tool wear, cutting forces and chip morphology in face milling of cobalt based super-alloy with physical vapour deposition coated and uncoated tool. Materials & Design. 2007;28:1880-8.

Kishawy HA, Elbestawi MA. Effects of process parameters on material side flow during hard turning. International Journal of Machine Tools and Manufacture. 1999;39:1017-30.

Sreejith PS, Ngoi BKA. Dry machining: Machining of the future. Journal of Materials Processing Technology. 2000;101:287-91.

Vyas A, Shaw MC. Mechanics of saw-tooth chip formation in metal cutting. Journal of Manufacturing Science and Engineering. 1999;121:163-72.

Morehead MD, Huang Y, Luo J. Chip morphology characterization and modeling in machining hardened 52100 steels. Machining Science and Technology. 2007;11:335-54.

Thakur DG, Ramamoorthy B, Vijayaraghavan L. Study on the machinability characteristics of superalloy inconel 718 during high speed turning. Materials & Design. 2009;30:1718-25.

Razak et al. / Journal of Mechanical Engineering and Sciences 11(1) 2017 2439 -2451

Thakur DG, Ramamoorthy B, Vijayaraghavan L. Machinability investigation of inconel 718 in high-speed turning. The International Journal of Advanced Manufacturing Technology. 2009;45:421-9.

Davies MA, Burns TJ, Evans CJ. On the dynamics of chip formation in machining hard metals. CIRP Annals-Manufacturing Technology. 1997;46:25-30.

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Published

2017-03-31

How to Cite

[1]
N.H. Razak, M.M. Rahman, and K. Kadirgama, “Cutting force and chip formation in end milling operation when machining nickelbased superalloy, Hastelloy C-2000”, J. Mech. Eng. Sci., vol. 11, no. 1, pp. 2539–2551, Mar. 2017.