Abstract
The suitable thermal, chemical, and corrosion resistance properties of glass make it possible to be used in a wide variety of product manufacturing, like lenses, mirrors, mold, semiconductor, biomedical, optical, and micro-electronics. However, machining of glass like any brittle material has big challenges owing to its inherent brittleness. Ductile mode machining is known to promote the material removal from a brittle material in ductile manner rather than by brittle fracture. In high-speed machining, the thermal softening effects can enhance flexibility in ductile machining of brittle materials. In this paper, an analytical model is developed to predict the amount of temperature generated in the immediate next removable layer (INRL) of the soda-lime glass work piece per unit depth of cut \( \Delta {\overline{T}}_{\mathrm{INRL}} \) based on fundamental micro-machining principle and material physical properties. The model incorporates the effects of cutting speed, feed rate, strain rate, and thermal softening effect. The simulation and experimental results showed that at high cutting speed, glass softening can be achieved by adiabatic heating in order to facilitate ductile machining. The amount of adiabatic heating can be controlled by predicting the amount of the \( \Delta {\overline{T}}_{\mathrm{INRL}} \).
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References
Foy K et al (2009) Effect of tilt angle on cutting regime transition in glass micromilling. Int J Mach Tools Manuf 49(3):315–324
Smith, W.F. and J. Hashemi, Foundations of materials science and engineering. 2006: Mcgraw-Hill Publishing
Bifano, T.G., T.A. Dow, and R.O. Scattergood. Ductile-regime grinding of brittle materials: experimental results and the development of a model. In 32nd Annual Technical Symposium. 1989. International Society for Optics and Photonics
Arefin S et al The upper bound of tool edge radius for nanoscale ductile mode cutting of silicon wafer. Int J Adv Manuf Technol 2007, 31(7–8):655–662
Cai M, Li X, Rahman M (2007) Study of the mechanism of nanoscale ductile mode cutting of silicon using molecular dynamics simulation. Int J Mach Tools Manuf 47(1):75–80
Arif M, Rahman M, San WY (2011) Analytical model to determine the critical feed per edge for ductile–brittle transition in milling process of brittle materials. Int J Mach Tools Manuf 51(3):170–181
Zhao, Y., et al. An experimental investigation on the surface morphology in micro-end-milling of glass. In Automation and Computing (ICAC), 2014 20th International Conference on. 2014. IEEE
Moriwaki T, Shamoto E, Inoue K (1992) Ultraprecision ductile cutting of glass by applying ultrasonic vibration. CIRP Annals-Manufacturing Technol 41(1):141–144
Zhang X et al (2013) A model to predict the critical undeformed chip thickness in vibration-assisted machining of brittle materials. Int J Mach Tools Manuf 69:57–66
Lin S et al (2015) Application of ultrasonic assisted machining technique for glass-ceramic milling. World Academy Sci, Engineering Technol, Int J Mechanical, Aerospace, Industrial, Mechatronic Manufacturing Engineering 9(5):802–807
Rao DMS, Shrekanth D (2014) Abrasive jet machining-research review. Int J Advanced Engineering Technol 5:18–24
Aich U et al (2014) Abrasive water jet cutting of borosilicate glass. Procedia Materials Sci 6:775–785
Jui SK, Kamaraj AB, Sundaram MM (2013) High aspect ratio micromachining of glass by electrochemical discharge machining (ECDM). J Manuf Process 15(4):460–466
Mohammadi H et al (2015) Experimental work on micro laser-assisted diamond turning of silicon (111). J Manuf Process 19:125–128
Wlodarczyk KL et al (2016) Picosecond laser cutting and drilling of thin flex glass. Opt Lasers Eng 78:64–74
Sajjadi, M., et al. Investigation of micro scratching and machining of glass. In ASME 2009 International Manufacturing Science and Engineering Conference. 2009. American Society of Mechanical Engineers
Reddy, M.M., A. Gorin, and K. Abou-El-Hossein. Predictive surface roughness model for end milling of machinable glass ceramic. In IOP Conference Series: Materials Science and Engineering. 2011. IOP Publishing
Amin A et al (2016) An experimental approach to determine the critical depth of cut in brittle-to-ductile phase transition during end milling of soda-lime glass. Arab J Sci Eng 41(11):4553–4562
Le Bourhis E, Metayer D (2000) Indentation of glass as a function of temperature. J Non-Cryst Solids 272(1):34–38
Michel M et al (2004) High temperature microhardness of soda-lime glass. J Non-Cryst Solids 348:131–138
Rouxel T, Sanglebœuf J-C (2000) The brittle to ductile transition in a soda–lime–silica glass. J Non-Cryst Solids 271(3):224–235
Johnson, G.R. and W.H. Cook. A constitutive model and data for metals subjected to large strains, high strain rates and high temperatures. In Proceedings of the 7th International Symposium on Ballistics. 1983. The Hague, The Netherlands
Rao S, Shunmugam M (2012) Analytical modeling of micro end-milling forces with edge radius and material strengthening effects. Mach Sci Technol 16(2):205–227
Srinivasa Y, Shunmugam M (2013) Mechanistic model for prediction of cutting forces in micro end-milling and experimental comparison. Int J Mach Tools Manuf 67:18–27
Venkatachalam S et al (2015) Microstructure effects on cutting forces and flow stress in ultra-precision machining of polycrystalline brittle materials. J Manuf Sci Eng 137(2):021020
Venkatachalam S, Li X, Liang SY (2009) Predictive modeling of transition undeformed chip thickness in ductile-regime micro-machining of single crystal brittle materials. J Mater Process Technol 209(7):3306–3319
Oxley, P., The mechanics of metal cutting. An analytical approach to assessing machinability. 1989, Chichester, Elis Horwood Limited
Altintas, Y., Mechanics of metal cutting. Manufacturing automation: metal cutting mechanics, machine tool vibrations, and CNC design, Cambridge, UK. Cambridge University Press, 2000: p. 4–65
Zhou L et al (2015) Analytical modeling and experimental validation of micro end-milling cutting forces considering edge radius and material strengthening effects. Int J Mach Tools Manuf 97:29–41
Boothroyd, G. and Ey, Temperatures in orthogonal metal cutting. Proceedings Institution Mechanical Engineers, 1963. 177(1): p. 789–810
Lazoglu I, Altintas Y (2002) Prediction of tool and chip temperature in continuous and interrupted machining. Int J Mach Tools Manuf 42(9):1011–1022
Callister, W.D. and D.G. Rethwisch, Materials science and engineering. Vol. 5. 2011: John Wiley & Sons NY
Zhang X, Hao H, Ma G (2015) Dynamic material model of annealed soda-lime glass. Int J Impact Eng 77:1088–1119
Callister, W.D. and D.G. Rethwisch, Materials science and engineering: an introduction. Vol. 7. 2007: Wiley New York
Holmquist TJ, Johnson GR (2011) A computational constitutive model for glass subjected to large strains, high strain rates and high pressures. J Appl Mech 78(5):051003
Zhang X, Hao H, Ma G (2015) Dynamic material model of annealed soda-lime glass. Int J Impact Engineering 77:108–119
Nie X et al (2009) Effect of loading rate and surface conditions on the flexural strength of borosilicate glass. J Am Ceram Soc 92(6):1287–1295
Lee HU, Cho D-W, Ehmann KF (2008) A mechanistic model of cutting forces in micro-end-milling with cutting-condition-independent cutting force coefficients. J Manuf Sci Eng 130(3):031102
Funding
The authors are grateful to the Fundamental Research Grant Scheme (FRGS14-120-0361) for funding this study.
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Bagum, M.N., Konneh, M. & Nurul Amin, A.K.M. Prediction and experimental validation of temperature rise in ductile mode end milling of soda-lime glass. Int J Adv Manuf Technol 96, 3437–3447 (2018). https://doi.org/10.1007/s00170-018-1833-0
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DOI: https://doi.org/10.1007/s00170-018-1833-0