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2020 | OriginalPaper | Chapter

12. Thermally Assisted Ductile Mode Cutting

Authors : Kui Liu, Hao Wang, Xinquan Zhang

Published in: Ductile Mode Cutting of Brittle Materials

Publisher: Springer Singapore

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Abstract

The growing necessity for advanced manufacturing technologies brings forth initiatives to incorporate thermal effects in micromachining of difficult-to-machine brittle material. While conventional heating methods exist in the macroform and are infeasible for micro-cutting applications, the fundamental concepts of heating are miniaturized to enable ductile mode micro-cutting of brittle single crystals. In general, ductile–brittle transition of these hard materials undergoes a significant improvement with thermal assistance, but the fundamental cause is material specific and could be attributed to the thermal softening effect, phase transition, and slip system activation. In addition, several aspects of the most promising technological advancements in thermally assisted machining, micro-laser assisted machining, are discussed in relation to machining conditions and tool wear. Temperature measurement techniques are also covered with the emphasis on its importance in ensuring proper thermal control of the machining system.

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Ezugwu EO (2005) Key improvements in the machining of difficult-to-cut aerospace superalloys. Int J Mach Tools Manuf 45:1353–1367CrossRef

Sun S, Brandt M, Dargusch MS (2010) Thermally enhanced machining of hard-to machine materials—a review. Int J Mach Tools Manuf 50:663–680CrossRef

Pramanik A (2014) Problems and solutions in machining of titanium alloys. Int J Adv Manuf Technol 70:919–928CrossRef

Ding H, Ibrahim R, Cheng K, Chen SJ (2010) Experimental study on machinability improvement of hardened tool steel using two dimensional vibration-assisted micro-end-milling. Int J Mach Tools Manuf 50:1115–1118CrossRef

Babitsky VI, Kalashnikov AN, Meadows A, Wijesundara AAH (2003) Ultrasonically assisted turning of aviation materials. J Mater Process Technol 132:157–167CrossRef

Kitagawa T, Kubo A, Maekawa K (1997) Temperature and wear of cutting tools in high-speed machining of Inconel 718 and Ti6Al6V2Sn. Wear 202:142–148CrossRef

Palanisamy S, McDonald SD, Dargusch MS (2009) Effects of coolant pressure on chip formation while turning Ti6Al4V alloy. Int J Mach Tools Manuf 49:739–743CrossRef

Nandy AK, Gowrishankar MC, Paul S (2009) Some studies on high-pressure cooling in turning of Ti-6Al-4V. Int J Mach Tools Manuf 49:182–198CrossRef

Tsutsumi C, Okano K, Suto T (1993) High quality machining of ceramics. J Mater Process Technol 37:639–654CrossRef

10.

Antwi EK, Liu K, Wang H (2018) A review on ductile mode cutting of brittle materials. Front Mech Eng 13:251–263CrossRef

11.

Ngoi BKA, Sreejith PS (2000) Ductile regime finish machining—a review. Int J Adv Manuf Technol 16:547–550CrossRef

12.

Spur G, Holl S-E (1996) Ultrasonic assisted grinding of ceramics. J Mater Process Technol 62:287–293CrossRef

13.

Amini S, Soleimanimehr H, Nategh MJ, Abudollah A, Sadeghi MH (2008) FEM analysis of ultrasonic-vibration-assisted turning and the vibratory tool. J Mater Process Technol 201:43–47CrossRef

14.

Yanyan Y, Bo Z, Junli L (2009) Ultraprecision surface finishing of nano-ZrO₂ ceramics using two-dimensional ultrasonic assisted grinding. Int J Adv Manuf Technol 43:462CrossRef

15.

Tian Y, Shin YC (2005) Thermal modeling for laser-assisted machining of silicon nitride ceramics with complex features. J Manuf Sci Eng 128:425–434CrossRef

16.

Tian Y, Wu B, Anderson M, Shin YC (2008) Laser-assisted milling of silicon nitride ceramics and Inconel 718. J Manuf Sci Eng 130:031013CrossRef

17.

Shams OA, Pramanik A, Chandratilleke TT (2017) Thermal-assisted machining of titanium alloys. In: Gupta K (ed) Advanced manufacturing technologies. Springer, pp 49–76

18.

Chang CW, Kuo CP (2007) An investigation of laser-assisted machining of Al₂O₃ ceramics planing. Int J Mach Tools Manuf 47:452–461CrossRef

19.

Tosun N, Ozler L (2004) Optimisation for hot turning operations with multiple performance characteristics. Int J Adv Manuf Technol 23:777–782CrossRef

20.

López de Lacalle LN, Sánchez JA, Lamikiz A, Celaya A (2004) Plasma assisted milling of heat-resistant superalloys. J Manuf Sci Eng 126:274CrossRef

21.

Özler L, İnan A, Özel C (2001) Theoretical and experimental determination of tool life in hot machining of austenitic manganese steel. Int J Mach Tools Manuf 41:163–172CrossRef

22.

Jeon Y, Lee CM (2012) Current research trend on laser assisted machining. Int J Precis Eng Manuf 13:311–317CrossRef

23.

Novak JW, Shin YC, Incropera FP (1997) Assessment of plasma enhanced machining for improved machinability of Inconel 718. J Manuf Sci Eng 119:125–129CrossRef

24.

Leshock CE, Kim JN, Shin YC (2001) Plasma enhanced machining of Inconel 718: modeling of workpiece temperature with plasma heating and experimental results. Int J Mach Tools Manuf 41:877–897

25.

Madhavulu G, Ahmed B (1994) Hot machining process for improved metal removal rates in turning operations. J Mater Process Technol 44:199–206CrossRef

26.

Chen SH, Tsai KT (2017) The study of plasma-assisted machining to Inconel-718. Adv Mech Eng 9:1–7. https://doi.org/10.1177/1687814017735789CrossRef

27.

Kttagawa T, Maekawa K (1990) Plasma got machining for new engineering materials. Wear 139:251–267CrossRef

28.

Lee YJ (2019) Thermal expansion control in heat assisted machining of calcium fluoride single crystals. In: 19th international conference of the European Society for Precision Engineering and Nanotechnology (euspen)

29.

Lee YJ, Chaudhari A, Zhang J, Wang H (2019) Thermally assisted microcutting of calcium fluoride single crystals. In: Simulation and experiments of material-oriented ultra-precision machining. Springer, Singapore, pp 77–127

30.

Wang H, Senthil Kumar A, Riemer O (2018) On the theoretical foundation for the microcutting of calcium fluoride single crystals at elevated temperatures. Proc Inst Mech Eng Part B J Eng Manuf 232:1123–1129CrossRef

31.

Lei S, Shin YC, Incropera FP (2001) Experimental investigation of thermo-mechanical characteristics in laser-assisted machining of silicon nitride ceramics. J Manuf Sci Eng 123:639CrossRef

32.

Anderson M, Patwa R, Shin YC (2006) Laser-assisted machining of Inconel 718 with an economic analysis. Int J Mach Tools Manuf 46:1879–1891CrossRef

33.

Shayan AR, Poyraz HB, Ravindra D, Patten JA (2009) Pressure and temperature effects in micro-laser assisted machining (μ-LAM) of silicon carbide. Trans North Am Manuf Res Inst SME 37:75–80

34.

Shayan AR, Poyraz HB, Ravindra D, Ghantasala M, Patten JA (2009) Force analysis, mechanical energy and laser heating evaluation of scratch tests on silicon carbide (4H-SiC) in micro-laser assisted machining (µ-LAM) process. In: ASME 2009 international manufacturing science and engineering conference. American Society of Mechanical Engineers, pp 827–832

35.

Cline HE, Anthony TR (1977) Heat treating and melting material with a scanning laser or electron beam. J Appl Phys 48:3895–3900CrossRef

36.

Spalding IJ (1974) Lasers—their applications and operational requirements. Opt Laser Technol 6:263–272CrossRef

37.

Chryssolouris G, Anifantis N, Karagiannis S (1997) Laser assisted machining: an overview. Trans ASME 119:766–769

38.

Tomizawa H, Fischer TE (1987) Friction and wear of silicon nitride and silicon carbide in water: hydrodynamic lubrication at low sliding speed obtained by tribochemical wear. A S L E Trans 30:41–46CrossRef

39.

Hibi Y, Enomoto Y, Kikuchi K, Shikata N, Ogiso H (1995) Excimer laser assisted chemical machining of SiC ceramic. Appl Phys Lett 66:817–818CrossRef

40.

Chavoshi SZ, Xu S (2018) Temperature-dependent nanoindentation response of materials. MRS Commun 8:15–28CrossRef

41.

Yan J, Asami T, Harada H, Kuriyagawa T (2009) Fundamental investigation of subsurface damage in single crystalline silicon caused by diamond machining. Precis Eng 33:378–386CrossRef

42.

Domnich V, Aratyn Y, Kriven WM, Gogotsi Y (2008) Temperature dependence of silicon hardness: experimental evidence of phase transformations. Rev Adv Mater Sci 17:33–41

43.

Khayyat MMO, Hasko DG, Chaudhri MM (2007) Effect of sample temperature on the indentation-induced phase transitions in crystalline silicon. J Appl Phys 101:83515CrossRef

44.

Khayyat MM, Banini GK, Hasko DG, Chaudhri MM (2003) Raman microscopy investigations of structural phase transformations in crystalline and amorphous silicon due to indentation with a Vickers diamond at room temperature and at 77 K. J Phys D Appl Phys 36:1300–1307CrossRef

45.

Ravindra D, Ghantasala MK, Patten J (2012) Ductile mode material removal and high-pressure phase transformation in silicon during micro-laser assisted machining. Precis Eng 36:364–367CrossRef

46.

Yan J, Maekawa K, Tamaki J, Kuriyagawa T (2005) Micro grooving on single-crystal germanium for infrared Fresnel lenses. J Micromech Microeng 15:1925–1931CrossRef

47.

Clarke DR, Kroll MC, Kirchner PD, Cook RF, Hockey BJ (1988) Amorphization and conductivity of silicon and germanium induced by indentation. Phys Rev Lett 60:2156–2159CrossRef

48.

Patten JA, Jacob J (2008) Comparison between numerical simulations and experiments for single-point diamond turning of single-crystal silicon carbide. J Manuf Process 10:28–33CrossRef

49.

Patten J, Fesperman R, Kumar S, McSpadden S, Qu J, Lance M, Nemanich R, Huening J (2003) High-pressure phase transformation of silicon nitride. Appl Phys Lett 83:4740–4742CrossRef

50.

Wang H, Riemer O, Rickens K, Brinksmeier E (2016) On the mechanism of asymmetric ductile–brittle transition in microcutting of (111) CaF₂ single crystals. Scr Mater 114:21–26CrossRef

51.

Mizumoto Y, Kangawa H, Itobe H, Tanabe T, Kakinuma Y (2017) Influence of crystal anisotropy on subsurface damage in ultra-precision cylindrical turning of CaF₂. Precis Eng 49:104–114CrossRef

52.

Muñoz A, Domínguez-Rodríguez A, Castaing J (1994) Slip systems and plastic anisotropy in CaF₂. J Mater Sci 29:6207–6211CrossRef

53.

Chaudhari A, Lee YJ, Wang H, Kumar AS (2017) Thermal effect on brittle–ductile transition in CaF₂ single crystals. In: 17th international conference of the European Society for Precision Engineering and Nanotechnology (euspen)

54.

Shahinian H, Navare J, Zaytsev D, Kode S, Azimi F (2018) Effect of laser-assisted diamond turning (Micro-LAM) on form and finish of selected IR crystals. In: 33rd annual meeting of American Society for Precision Engineering, Las Vegas, Nevada, pp 1–5

55.

Shahinian H, Navare J, Zaytsev D, Ravindra D (2019) Microlaser assisted diamond turning of precision silicon optics. Opt Eng 58:1–8

56.

Mohammadi H, Ravindra D, Kode SK, Patten JA (2015) Experimental work on micro laser-assisted diamond turning of silicon (111). J Manuf Process 19:125–128CrossRef

57.

Ravindra D, Kode SK, Stroshine C, Morrison D, Mitchell M (2017) Micro-laser assisted machining: the future of manufacturing silicon optics. In: Proceedings of the SPIE

58.

Suthar K, Patten JA, Dong L, Abdel-aal H (2008) Estimation of temperature distribution in silicon during micro laser assisted machining. In: ASME 2008 international manufacturing science and engineering conference collocated with the 3rd JSME/ASME international conference on materials and processing, Evanston, Illinois, USA

59.

Patten J, Ghantasala M, Shayan AR, Bogac Poyraz H, Ravindra D (2009) Micro-laser assisted machining (µ-LAM): scratch tests on 4H-SiC. In: Proceedings of 2009 NSF engineering research and innovation conference, Honolulu, Hawaii

60.

Leung TP, Lee WB, Lu XM (1998) Diamond turning of silicon substrates in ductile-regime. J Mater Process Technol 73:42–48CrossRef

61.

Yan J, Yoshino M, Kuriagawa T, Shirakashi T, Syoji K, Komanduri R (2001) On the ductile machining of silicon for micro electro-mechanical systems (MEMS), opto-electronic and optical applications. Mater Sci Eng A 297:230–234CrossRef

62.

Ravindra D, Poyraz HB, Patten J (2010) The effect of laser heating on the ductile to brittle transition of silicon. In: The 5th international conference in micromanufacturing (ICOMM/4M), Wisconsin, USA

63.

Ravindra D, Poyraz HB, Patten J (2010) The effect of laser heating on the ductile to brittle transition of silicon carbide. Manufacturing Research Center, Western Michigan University

64.

Yan J, Tamaki J, Syoji K, Kuriyagawa T (2004) Single-point diamond turning of CaF₂ for nanometric surface. Int J Adv Manuf Technol 24:640–646CrossRef

65.

Ravindra D, Ponthapalli SC, Patten J (2013) Micro-laser assisted single point diamond turning feasibility tests of single crystal silicon. In: American Society for Precision Engineering (ASPE) 28th annual meeting, St. Paul, Minnesota

66.

Mohammadi H, Patten JA (2016) Laser augmented diamond drilling: a new technique to drill hard and brittle materials. Procedia Manuf 5:1337–1347CrossRef

67.

Shimada S, Tanaka H, Higuchi M, Yamaguchi T, Honda S, Obata K (2004) Thermo-chemical wear mechanism of diamond tool in machining of ferrous metals. CIRP Ann Manuf Technol 53:57–60CrossRef

68.

Schuelke T, Grotjohn TA (2013) Diamond polishing. Diam Relat Mater 32:17–26CrossRef

69.

Fedoseev DV, Vnukov SP, Bukhovets VL, Anikin BA (1986) Surface graphitization of diamond at high temperatures. Surf Coatings Technol 28:207–214CrossRef

70.

Yan J, Syoji K, Kuriyagawa T (2000) Ductile–brittle transition at large negative tool rake angles. J Jpn Soc Precis Eng 66:1130–1134CrossRef

71.

Patten JA, Shayan AR, Poyraz HB, Ravindra D, Ghantasala M (2009) Scratch tests on 4H-SiC using micro laser assisted machining (μ-LAM) system. In: Advance laser applications conference and exposition, San Jose, California, USA

72.

Douglas-Hamilton DH, Hoag ED, Seitz JRM (1974) Diamond as a high-power-laser window. J Opt Soc Am 64:36–38CrossRef

73.

Zaitsev AM (2001) Optical properties of diamond. Springer, Berlin, HeidelbergCrossRef

74.

Collins AT (1993) Intrinsic and extrinsic absorption and luminescence in diamond. Phys B Condens Matter 185:284–296CrossRef

75.

Mizumoto Y, Amano H, Kangawa H, Harano K, Sumiya H, Kakinuma Y (2018) On the improvement of subsurface quality of CaF₂ single crystal machined by boron-doped nano-polycrystalline diamond tools. Precis Eng 52:73–83CrossRef

76.

Fontanella J, Johnston RL, Colwell JH, Andeen C (1977) Temperature and pressure variation of the refractive index of diamond. Appl Opt 16:2949–2951CrossRef

77.

Chaudhari A, Soh ZY, Wang H, Kumar AS (2018) Rehbinder effect in ultraprecision machining of ductile materials. Int J Mach Tools Manuf 133:47–60CrossRef

78.

Chaudhari A, Wang H (2019) Effect of surface-active media on chip formation in micromachining. J Mater Process Technol 271:325–335CrossRef

79.

Rozzi JC, Pfefferkorn FE, Shin YC, Incropera FP (2000) Experimental evaluation of the laser assisted machining of silicon nitride ceramics. Trans ASME 122:666–670MATH

80.

Pfefferkorn FE (1997) Laser pyrometry: non-intrusive temperature measurement for laser-assisted machining of ceramics. Purdue University

81.

Dinc C, Lazoglu I, Serpenguzel A (2008) Analysis of thermal fields in orthogonal machining with infrared imaging. J Mater Process Technol 198:147–154CrossRef

82.

Davies MA, Yoon H, Schmitz TL, Burns TJ, Kennedy MD (2003) Calibrated thermal microscopy of the tool-chip interface in machining. Mach Sci Technol 7:167–190CrossRef

83.

Xiong HP, Kawasaki A, Kang YS, Watanabe R (2005) Experimental study on heat insulation performance of functionally graded metal/ceramic coatings and their fracture behavior at high surface temperatures. Surf Coatings Technol 194:203–214CrossRef

84.

Gavrunov A, Ravindra D (2013) Custom cooling stage to eliminate thermal expansion of spindle during micro-laser assisted machining. In: Advance laser applications conference and exposition, Chicago, Illinois, USA

85.

Chaudhari A, Antwi EK, Wang H, Liu K, Kumar AS, Tu J, Zhang X (2017) Tool design and implementation for thermally assisted ultraprecision diamond turning. In: The 7th international conference of Asian Society for Precision Engineering and Nanotechnology, Seoul, Korea

Title: Thermally Assisted Ductile Mode Cutting
Authors: Kui Liu
Hao Wang
Xinquan Zhang
Publisher: Springer Singapore
Book: Ductile Mode Cutting of Brittle Materials
Print ISBN: 978-981-329-835-4

Electronic ISBN: 978-981-329-836-1

Copyright Year: 2020
DOI: https://doi.org/10.1007/978-981-32-9836-1_12

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