Open Access
Review
Issue
Manufacturing Rev.
Volume 4, 2017
Article Number 5
Number of page(s) 12
DOI https://doi.org/10.1051/mfreview/2017004
Published online 23 May 2017
  1. C. Yue, X. Liu, S.Y. Liang, A model for predicting chatter stability considering contact characteristic between milling cutter and workpiece, The International Journal of Advanced Manufacturing Technology 88 (2016) 2345−2354. [CrossRef]
  2. X. Lu, et al., Tool wear appearance and failure mechanism of coated carbide tools in micro-milling of Inconel 718 super alloy, Industrial Lubrication and Tribology 68 (2016) 267–277. [CrossRef]
  3. Z. Pan, et al., Analytical model for force prediction in laser-assisted milling of IN718, The International Journal of Advanced Manufacturing Technology (2016), DOI: 10.1007/s00170-016-9629-6.
  4. C.F. Cheung, W.B. Lee, A multi-spectrum analysis of surface roughness formation in ultra-precision machining, Precision Engineering 24 (2000) 77–87. [CrossRef]
  5. S. Zhang, et al., A review of surface roughness generation in ultra-precision machining, International Journal of Machine Tools and Manufacture 91 (2015) 76–95. [CrossRef]
  6. J.P. Davim, Surface integrity in machining, Springer, London, 2010, ISBN: 1848828742.
  7. C. Wu, et al., Prediction of grinding force for brittle materials considering co-existing of ductility and brittleness, The International Journal of Advanced Manufacturing Technology 87 (2016) 1967–1975. [CrossRef]
  8. D. Ulutan, T. Ozel, Machining induced surface integrity in titanium and nickel alloys: a review, International Journal of Machine Tools and Manufacture 51 (2011) 250–280. [CrossRef]
  9. E. Ezugwu, S. Tang, Surface abuse when machining cast iron (G-17) and nickel-base superalloy (Inconel 718) with ceramic tools, Journal of Materials Processing Technology 55 (1995) 63–69. [CrossRef]
  10. B. Baufeld, O. Van der Biest, R. Gault, Additive manufacturing of Ti-6Al-4V components by shaped metal deposition: microstructure and mechanical properties, Materials & Design 31 (2010) S106–S111. [CrossRef]
  11. B. Baufeld, E. Brandl, O. Van der Biest, Wire based additive layer manufacturing: comparison of microstructure and mechanical properties of Ti-6Al-4V components fabricated by laser-beam deposition and shaped metal deposition, Journal of Materials Processing Technology 211 (2011) 1146–1158. [CrossRef]
  12. L. Thijs, et al., A study of the microstructural evolution during selective laser melting of Ti-6Al-4V, Acta Materialia 58 (2010) 3303–3312. [CrossRef]
  13. Y.K. Chou, C.J. Evans, White layers and thermal modeling of hard turned surfaces, International Journal of Machine Tools and Manufacture 39 (1999) 1863–1881. [CrossRef]
  14. D. Araujo, et al., Microstructural study of CO2 laser machined heat affected zone of 2024 aluminum alloy, Applied Surface Science 208 (2003) 210–217. [CrossRef]
  15. T. El-Wardany, H. Kishawy, M. Elbestawi, Surface integrity of die material in high speed hard machining, part 1: micrographical analysis, Journal of manufacturing science and engineering 122 (2000) 620–631. [CrossRef]
  16. K.B. Popov, et al., Micromilling: material microstructure effects, Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 220 (2006) 1807–1813. [CrossRef]
  17. D. Axinte, R. Dewes, Surface integrity of hot work tool steel after high speed milling-experimental data and empirical models, Journal of Materials Processing Technology 127 (2002) 325–335. [CrossRef]
  18. S. Ghosh, V. Kain, Microstructural changes in AISI 304L stainless steel due to surface machining: effect on its susceptibility to chloride stress corrosion cracking, Journal of Nuclear Materials 403 (2010) 62–67. [CrossRef]
  19. S. Ranganath, C. Guo, P. Hegde, A finite element modeling approach to predicting white layer formation in nickel superalloys, CIRP Annals-Manufacturing Technology 58 (2009) 77–80. [CrossRef]
  20. C. Duan, et al., Modeling of white layer thickness in high speed machining of hardened steel based on phase transformation mechanism, The International Journal of Advanced Manufacturing Technology 69 (2013) 59–70. [CrossRef]
  21. A. Ramesh, S.N. Melkote, Modeling of white layer formation under thermally dominant conditions in orthogonal machining of hardened AISI 52100 steel, International Journal of Machine Tools and Manufacture 48 (2008) 402–414. [CrossRef]
  22. S. Han, et al., White layer formation due to phase transformation in orthogonal machining of AISI 1045 annealed steel, Materials Science and Engineering: A 488 (2008) 195–204. [CrossRef]
  23. Y.K. Chou, H. Song, Thermal modeling for white layer predictions in finish hard turning, International Journal of Machine Tools and Manufacture 45 (2005) 481–495. [CrossRef]
  24. D. Umbrello, et al., Modeling of white and dark layer formation in hard machining of AISI 52100 bearing steel, Machining Science and Technology 14 (2010) 128–147. [CrossRef]
  25. Z. Wan, et al., Microstructure evolution of adiabatic shear bands and mechanisms of saw-tooth chip formation in machining Ti6Al4V, Materials Science and Engineering: A 531 (2012) 155–163. [CrossRef]
  26. R. Shivpuri, et al., Microstructure-mechanics interactions in modeling chip segmentation during titanium machining, CIRP Annals-Manufacturing Technology 51 (2002) 71–74. [CrossRef]
  27. M.P. Vogler, R.E. DeVor, S.G. Kapoor, On the modeling and analysis of machining performance in micro-endmilling, part I: surface generation, Journal of Manufacturing Science and Engineering 126 (2004) 685–694. [CrossRef]
  28. Z. Pan, et al., Modeling of Ti-6Al-4V machining force considering material microstructure evolution, The International Journal of Advanced Manufacturing Technology (2017) 1–8.
  29. Z. Yuan, L. Geng, S. Dong, Ultraprecision machining of SiCw/Al composites 11 the project supported by National Natural Science Foundation of China, CIRP Annals-Manufacturing Technology 42 (1993) 107–109. [CrossRef]
  30. Y. Furukawa, N. Moronuki, Effect of material properties on ultra precise cutting processes, CIRP Annals-Manufacturing Technology 37 (1988) 113–116. [CrossRef]
  31. Y.K. Chou, Hard turning of M50 steel with different microstructures in continuous and intermittent cutting, Wear 255 (2003) 1388–1394. [CrossRef]
  32. L. Chuzhoy, R. DeVor, S. Kapoor, D. Bammann, Microstructure-level modeling of ductile iron machining, Journal of Manufacturing Science and Engineering 124 (2002) 162–169. [CrossRef]
  33. R.E. DeVor, On the modeling and analysis of machining performance in micro-endmilling, part II: cutting force prediction, Urbana 51 (2004) 61801–2906.
  34. A. Molinari, C. Musquar, G. Sutter, Adiabatic shear banding in high speed machining of Ti-6Al-4V: experiments and modeling, International Journal of Plasticity 18 (2002) 443–459. [CrossRef]
  35. R. Recht, Catastrophic thermoplastic shear, Journal of Applied Mechanics 31 (1964) 186–193. [CrossRef]
  36. Y. Xu, et al., Shear localization in dynamic deformation: microstructural evolution, Metallurgical and Materials Transactions A 39 (2008) 811. [CrossRef]
  37. M. Meyers, et al., Microstructural evolution in adiabatic shear localization in stainless steel, Acta Materialia 51 (2003) 1307–1325. [CrossRef]
  38. R. Ebrahimi, E. Shafiei, Mathematical modeling of single peak dynamic recrystallization flow stress curves in metallic alloys, in: K. Sztwiertnia (Ed.), Recrystallization, InTech, 2012, pp. 207–224.
  39. Y. Guo, Q. Wen, M. Horstemeyer, An internal state variable plasticity-based approach to determine dynamic loading history effects on material property in manufacturing processes, International Journal of Mechanical Sciences 47 (2005) 1423–1441. [CrossRef]
  40. M. Calamaz, D. Coupard, F. Girot, A new material model for 2D numerical simulation of serrated chip formation when machining titanium alloy Ti-6Al-4V, International Journal of Machine Tools and Manufacture 48 (2008) 275–288. [CrossRef]
  41. X. Zhang, R. Shivpuri, A. Srivastava, Role of phase transformation in chip segmentation during high speed machining of dual phase titanium alloys, Journal of Materials Processing Technology 214 (2014) 3048–3066. [CrossRef]
  42. S. Venkatachalam, et al., Microstructure effects on cutting forces and flow stress in ultra-precision machining of polycrystalline brittle materials, Journal of Manufacturing Science and Engineering 137 (2015) 021020. [CrossRef]
  43. Y.M. Arısoy, T. Özel, Prediction of machining induced microstructure in Ti-6Al-4V alloy using 3-D FE-based simulations: effects of tool micro-geometry, coating and cutting conditions, Journal of Materials Processing Technology 220 (2015) 1–26. [CrossRef]
  44. Z. Pan, A. Tabei, D.S. Shih, H. Garmestani, S.Y. Liang, The effects of dynamic evolution of microstructure on machining forces, Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture (2017), DOI: 10.1177/0954405417703430.
  45. W. Gourdin, D. Lassila, Flow stress of OFE copper at strain rates from 10−3 to 104s−1: grain-size effects and comparison to the mechanical threshold stress model, Acta Metallurgica et Materialia 39 (1991) 2337–2348. [CrossRef]
  46. Z. Atmani, et al., Multi-physics modelling in machining OFHC copper – coupling of microstructure-based flow stress and grain refinement models, Procedia CIRP 31 (2015) 545–550. [CrossRef]
  47. O. Fergani, S.Y. Liang, Materials-affected manufacturing, Manufacturing Letters 1 (2013) 74–77. [CrossRef]
  48. R. M’Saoubi, et al., A review of surface integrity in machining and its impact on functional performance and life of machined products, International Journal of Sustainable Manufacturing 1 (2008) 203–236. [CrossRef]
  49. A. Devillez, et al., Dry machining of Inconel 718, workpiece surface integrity, Journal of Materials Processing Technology 211 (2011) 1590–1598. [CrossRef]
  50. R. Pawade, S.S. Joshi, P. Brahmankar, Effect of machining parameters and cutting edge geometry on surface integrity of high-speed turned Inconel 718, International Journal of Machine Tools and Manufacture 48 (2008) 15–28. [CrossRef]
  51. R. Arunachalam, M. Mannan, A. Spowage, Residual stress and surface roughness when facing age hardened Inconel 718 with CBN and ceramic cutting tools, International Journal of Machine Tools and Manufacture 44 (2004) 879–887. [CrossRef]
  52. A. Sharman, J. Hughes, K. Ridgway, An analysis of the residual stresses generated in Inconel 718TM when turning, Journal of Materials Processing Technology 173 (2006) 359–367. [CrossRef]
  53. J. Outeiro, et al., Analysis of residual stresses induced by dry turning of difficult-to-machine materials, CIRP Annals-Manufacturing Technology 57 (2008) 77–80. [CrossRef]
  54. D. Thakur, B. Ramamoorthy, L. Vijayaraghavan, Study on the machinability characteristics of superalloy Inconel 718 during high speed turning, Materials & Design 30 (2009) 1718–1725. [CrossRef]
  55. R. Pawade, S.S. Joshi, Mechanism of chip formation in high-speed turning of Inconel 718, Machining Science and Technology 15 (2011) 132–152. [CrossRef]
  56. A. Ginting, M. Nouari, Surface integrity of dry machined titanium alloys, International Journal of Machine Tools and Manufacture 49 (2009) 325–332. [CrossRef]
  57. J. Sun, Y. Guo, A comprehensive experimental study on surface integrity by end milling Ti-6Al-4V, Journal of Materials Processing Technology 209 (2009) 4036–4042. [CrossRef]
  58. C. Che-Haron, A. Jawaid, The effect of machining on surface integrity of titanium alloy Ti-6% Al-4% V, Journal of Materials Processing Technology 166 (2005) 188–192. [CrossRef]
  59. A. Sharman, et al., Workpiece surface integrity considerations when finish turning gamma titanium aluminide, Wear 249 (2001) 473–481. [CrossRef]
  60. M. Mhamdi, et al., Surface integrity of titanium alloy Ti-6Al-4V in ball end milling, Physics Procedia 25 (2012) 355–362. [CrossRef]
  61. Z. Pan, et al., Prediction of machining-induced phase transformation and grain growth of Ti-6Al-4V alloy, The International Journal of Advanced Manufacturing Technology 87 (2016) 859–866. [CrossRef]
  62. T. Özel, D. Ulutan, Prediction of machining induced residual stresses in turning of titanium and nickel based alloys with experiments and finite element simulations, CIRP Annals-Manufacturing Technology 61 (2012) 547–550. [CrossRef]
  63. A. Daymi, et al., Surface integrity in high speed end milling of titanium alloy Ti-6Al-4V, Materials Science and Technology 27 (2011) 387–394. [CrossRef]
  64. B. Griffiths, White layer formations at machined surfaces and their relationship to white layer formations at worn surfaces, Journal of Tribology (Transactions of the American Society of Mechanical Engineers) 107 (1985) 165–171.
  65. A. Barbacki, M. Kawalec, Structural alterations in the surface layer during hard machining, Journal of Materials Processing Technology 64 (1997) 33–39. [CrossRef]
  66. D. Umbrello, L. Filice, Improving surface integrity in orthogonal machining of hardened AISI 52100 steel by modeling white and dark layers formation, CIRP Annals-Manufacturing Technology 58 (2009) 73–76. [CrossRef]
  67. G. Poulachon, et al., An experimental investigation of work material microstructure effects on white layer formation in PCBN hard turning, International Journal of Machine Tools and Manufacture 45 (2005) 211–218. [CrossRef]
  68. J. Barry, G. Byrne, TEM study on the surface white layer in two turned hardened steels, Materials Science and Engineering: A 325 (2002) 356–364. [CrossRef]
  69. S. Bosheh, P. Mativenga, White layer formation in hard turning of H13 tool steel at high cutting speeds using CBN tooling, International Journal of Machine Tools and Manufacture 46 (2006) 225–233. [CrossRef]
  70. J.P. Velásquez, et al., Sub-surface and surface analysis of high speed machined Ti-6Al-4V alloy, Materials Science and Engineering: A 527 (2010) 2572–2578. [CrossRef]
  71. J. Derep, Microstructure transformation induced by adiabatic shearing in armour steel, Acta Metallurgica 35 (1987) 1245–1249. [CrossRef]
  72. C. Duan, L. Zhang, Adiabatic shear banding in AISI 1045 steel during high speed machining: mechanisms of microstructural evolution, Materials Science and Engineering: A 532 (2012) 111–119. [CrossRef]
  73. A. Bayoumi, J. Xie, Some metallurgical aspects of chip formation in cutting Ti-6wt.% Al-4wt.% V alloy, Materials Science and Engineering: A 190 (1995) 173–180. [CrossRef]
  74. J.P. Velásquez, et al., Metallurgical study on chips obtained by high speed machining of a Ti-6wt.% Al-4wt.% V alloy, Materials Science and Engineering: A 452 (2007) 469–474. [CrossRef]
  75. G. Ye, et al., Modeling periodic adiabatic shear band evolution during high speed machining Ti-6Al-4V alloy, International Journal of Plasticity 40 (2013) 39–55. [CrossRef]
  76. C. Campbell, et al., Microstructural characterization of Al-7075-T651 chips and work pieces produced by high-speed machining, Materials Science and Engineering: A 430 (2006) 15–26. [CrossRef]
  77. M.R. Shankar, et al., Characteristics of aluminum 6061-T6 deformed to large plastic strains by machining, Materials Science and Engineering: A 410 (2005) 364–368. [CrossRef]
  78. U. Andrade, et al., Dynamic recrystallization in high-strain, high-strain-rate plastic deformation of copper, Acta Metallurgica et Materialia 42 (1994) 3183–3195. [CrossRef]
  79. S. Nemat-Nasser, et al., Dynamic response of conventional and hot isostatically pressed Ti-6Al-4V alloys: experiments and modeling, Mechanics of Materials 33 (2001) 425–439. [CrossRef]
  80. F.J. Zerilli, R.W. Armstrong, Dislocation-mechanics-based constitutive relations for material dynamics calculations, Journal of Applied Physics 61 (1987) 1816–1825. [CrossRef]

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