International Journal of Extreme Manufacturing, Volume. 5, Issue 1, 12002(2023)

Friction behaviors in the metal cutting process: state of the art and future perspectives

[in Chinese]1...2,3, [in Chinese]1,2,*, [in Chinese]1,2, [in Chinese]3 and [in Chinese]3 |Show fewer author(s)
Author Affiliations
  • 1Key Laboratory of High Efficiency and Clean Mechanical Manufacture of MOE, School of Mechanical Engineering, Shandong University, Jinan 250061, People’s Republic of China
  • 2Key National Demonstration Center for Experimental Mechanical Engineering Education, Shandong University, Jinan 250061, People’s Republic of China
  • 3State Key Laboratory of Ultra-Precision Machining Technology, Department of Industrial and Systems Engineering, The Hong Kong Polytechnic University, Kowloon, Hong Kong, People’s Republic of China
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    References(245)

    [1] [1] Klocke F 2011 Manufacturing Processes (Berlin: Springer) (https://doi.org/10.1016/j.jmapro.2011.11.001)

    [2] [2] Jawahir I S, Brinksmeier E, M’saoubi R, Aspinwall D K, Outeiro J C, Meyer D, Umbrello D and Jayal A D 2011 Surface integrity in material removal processes: recent advances CIRP Ann. 60 603–26

    [3] [3] M’Saoubi R, Axinte D, Soo S L, Nobel C, Attia H, Kappmeyer G, Engin S and Sim W M 2015 High performance cutting of advanced aerospace alloys and composite materials CIRP Ann. 64 557–80

    [4] [4] Kumar S, Tong Z and Jiang X 2022 Advances in the design and manufacturing of novel freeform optics Int. J. Extreme Manuf. 4 032004

    [5] [5] Melkote S N, Grzesik W, Outeiro J, Rech J, Schulze V, Attia H, Arrazola P J, M’saoubi R and Saldana C 2017 Advances in material and friction data for modelling of metal machining CIRP Ann. 66 731–54

    [6] [6] Zhang Y B et al 2022 Nano-enhanced biolubricant in sustainable manufacturing: from processability to mechanisms Friction 10 803–41

    [7] [7] Jawahir I S, Kaynak Y and Lu T 2014 The impact of novel material processing methods on component quality, life and performance Proc. CIRP 22 33–44

    [8] [8] Cakir E, Ozlu E, Bakkal M and Budak E 2018 Investigation of temperature distribution in orthogonal cutting through dual-zone contact model on the rake face Int. J. Adv. Manuf. Technol. 96 81–89

    [9] [9] Arrazola P J, Arriola I, Davies M A, Cooke A L and Dutterer B S 2008 The effect of machinability on thermal fields in orthogonal cutting of AISI 4140 steel CIRP Ann. 57 65–68

    [10] [10] Vandana A S and Sundaram N K 2018 Simulation of sinuous flow in metal cutting Tribol. Lett. 66 94

    [11] [11] Mahato A, Yeung H, Guo Y, Viswanathan K, Sundaram N K, Udupa A, Mann J B and Chandrasekar S 2017 Sinuous flow and folding in metals: implications for delamination wear and surface phenomena in sliding and cutting Wear 376–377 1534–41

    [12] [12] .zel T 2006 The influence of friction models on finite element simulations of machining Int. J. Mach. Tool. Manuf. 46 518–30

    [13] [13] Davim J P 2013 Tribology in Manufacturing Technology (Berlin: Springer)

    [14] [14] WangB,LiuZQ,CaiYK,LuoXC,MaHF, SongQHand Xiong Z H 2021 Advancements in material removal mechanism and surface integrity of high speed metal cutting: a review Int. J. Mach. Tools Manuf. 166 103744

    [15] [15] LiangXL,LiuZQ,ChenLX,HaoGC,WangB,CaiYK and Song Q H 2020 Tool wear induced modifications of plastic flow and deformed material depth in new generated surfaces during turning Ti-6Al-4V J. Mater. Res. Technol. 9 10782–95

    [16] [16] Sagapuram D, Yeung H, Guo Y, Mahato A, M’Saoubi R, Compton W D, Trumble K P and Chandrasekar S 2015 On control of flow instabilities in cutting of metals CIRP Ann. 64 49–52

    [17] [17] Yang X, Zhang Q, Zheng Y, Liu X, Politis D, Fakir O E and Wang L 2021 Investigation of the friction coefficient evolution and lubricant breakdown behaviour of AA7075 aluminium alloy forming processes at elevated temperatures Int. J. Extreme Manuf. 3 025002

    [18] [18] Fu X L, Pan Y A, Wang Y and Qiao Y 2016 Experimental and simulation study on friction condition of the tool-chip interface during cutting process Key Eng. Mater. 693 747–54

    [19] [19] Ulutan D and .zel T 2012 Methodology to determine friction in orthogonal cutting with application to machining titanium and nickel based alloys Proc. ASME 2012 Int. Manufacturing Science and Engineering Conf. (Notre Dame: ASME) pp 327–34

    [20] [20] Arrazola P J, .zel T, Umbrello D, Davies M and Jawahir I S 2013 Recent advances in modelling of metal machining processes CIRP Ann. 62 695–718

    [21] [21] Lotfi M, Amini S and Ashrafi H 2019 Theoretical and numerical modeling of tool-chip friction in ultrasonic-assisted turning Proc. Inst. Mech. Eng. E 233 824–38

    [22] [22] Smolenicki D, Boos J, Kuster F, Roelofs H and Wyen C F 2014 In-process measurement of friction coefficient in orthogonal cutting CIRP Ann. 63 97–100

    [23] [23] Polvorosa R, Suárez A, De Lacalle L N L, Cerrillo I, Wretland A and Veiga F 2017 Tool wear on nickel alloys with different coolant pressures: comparison of alloy 718 and Waspaloy J. Manuf. Process. 26 44–56

    [24] [24] Pang M H, Liu X J and Liu K 2019 Effect of conical micro-grooved texture on tool-chip friction property and cutting performance of WC-TiC/Co cemented carbide tools Proc. Inst. Mech. Eng. J 233 791–804

    [25] [25] Cai F, Gao Y, Zhang S H, Zhang L and Wang Q M 2019 Gradient architecture of Si containing layer and improved cutting performance of AlCrSiN coated tools Wear 424–425 193–202

    [26] [26] He G H, Liu X L and Yan F G 2012 Research on the dynamic mechanical characteristics and turning tool life under the conditions of excessively heavy-duty turning Front. Mech. Eng. 7 329–34

    [27] [27] Liang X L, Liu Z Q and Wang B 2019 State-of-the-art of surface integrity induced by tool wear effects in machining process of titanium and nickel alloys: a review Measurement 132 150–81

    [28] [28] Liang X L, Liu Z Q, Wang B and Hou X 2018 Modeling of plastic deformation induced by thermo-mechanical stresses considering tool flank wear in high-speed machining Ti-6Al-4V Int. J. Mech. Sci. 140 1–12

    [29] [29] Liu S Q, Zhang H J, Zhao L, Li G, Zhang C Y, Zhang J J and Sun T 2021 Coupled thermo-mechanical sticking-sliding friction model along tool-chip interface in diamond cutting of copper J. Manuf. Process. 70 578–92

    [30] [30] Mane S, Joshi S S, Karagadde S and Kapoor S G 2020 Modeling of variable friction and heat partition ratio at the chip-tool interface during orthogonal cutting of Ti-6Al-4V J. Manuf. Process. 55 254–67

    [31] [31] Enomoto T and Sugihara T 2010 Improving anti-adhesive properties of cutting tool surfaces by Nano-/micro-textures CIRP Ann. 59 597–600

    [32] [32] Dang J Q, Zhang H, Ming W W, An Q L and Chen M 2020 New observations on wear characteristics of solid Al2O3/Si3N4 ceramic tool in high speed milling of additive manufactured Ti6Al4V Ceram. Int. 46 5876–86

    [33] [33] Dargusch M S, Sun S J, Kim J W, Li T, Trimby P and Cairney J 2018 Effect of tool wear evolution on chip formation during dry machining of Ti-6Al-4V alloy Int. J. Mach. Tools Manuf. 126 13–17

    [34] [34] Chen F Y, Wang D Z and Wu S J 2021 Influence of ultrasonic vibration-assisted cutting on ploughing effect in cutting Ti6Al4V Arch. Civ. Mech. Eng. 21 42

    [35] [35] Yan L, Yang W Y and Jin H P 2010 A new experimental approach for determination the effect of tool flank wear length on cutting temperature distributions Adv. Mater. Res. 156–157 64–67

    [36] [36] Atlati S, Haddag B, Nouari M and Moufki A 2015 Effect of the local friction and contact nature on the built-up edge formation process in machining ductile metals Tribol. Int. 90 217–27

    [37] [37] Fan YH,HaoZP, LinJQandYu ZX2015New observations on tool wear mechanism in machining Inconel 718 under water vapor + air cooling lubrication cutting conditions J. Clean. Prod. 90 381–7

    [38] [38] ZhangHD,MeiFS,Yu Y, LinXLandGaoJX2021 Improvement on the mechanical, tribological properties and cutting performance of AlTiN-based coatings by compositional and structural design Surf. Coat. Technol. 422 127503

    [39] [39] Barry J, Byrne G and Lennon D 2001 Observations on chip formation and acoustic emission in machining Ti-6Al-4V alloy Int. J. Mach. Tools Manuf. 41 1055–70

    [40] [40] Hou X, Li J Y, Li Y Z and Tian Y 2022 Intermolecular and surface forces in atomic-scale manufacturing Int. J. Extreme Manuf. 4 022002

    [41] [41] Abukhshim N A, Mativenga P T and Sheikh M A 2006 Heat generation and temperature prediction in metal cutting: a review and implications for high speed machining Int. J. Mach. Tools Manuf. 46 782–800

    [42] [42] LiTX,ShiTL,TangZR,LiaoGL,HanJHandDuanJ 2020 Temperature monitoring of the tool-chip interface for PCBN tools using built-in thin-film thermocouples in turning of titanium alloy J. Mater. Process. Technol. 275 116376

    [43] [43] Ramalingam S and Lehn L L 1971 A photoelastic study of stress distribution during orthogonal cutting-part 1: workpiece stress distribution J. Manuf. Sci. Eng. 93 527–37

    [44] [44] Dang J Q, Zhang H, An Q L, Ming W W and Chen M 2021 On the microstructural evolution pattern of 300 M steel subjected to surface cryogenic grinding treatment J. Manuf. Process. 68 169–85

    [45] [45] Zhang D, Zhang X M, Nie G C, Yang Z Y and Ding H 2021 In situ imaging based thermo-mechanical analysis of built-up edge in cutting process J. Manuf. Process. 71 450–60

    [46] [46] Ackroyd B, Chandrasekar S and Compton W D 2003 A model for the contact conditions at the chip-tool interface in machining J. Tribol. 125 649–60

    [47] [47] Segebade E, Schneider J and Schulze V 2018 Tribological effects in and by metal cutting Key Eng. Mater. 767 3–24

    [48] [48] Schultheiss F, Fallqvist M, M’Saoubi R, Olsson M and St.hl J E 2013 Influence of the tool surface micro topography on the tribological characteristics in metal cutting—Part II. Theoretical calculations of contact conditions Wear 298–299 23–31

    [49] [49] Gajrani K K, Ram D and Sankar M R 2017 Biodegradation and hard machining performance comparison of eco-friendly cutting fluid and mineral oil using flood cooling and minimum quantity cutting fluid techniques J. Clean. Prod. 165 1420–35

    [50] [50] Hwang J and Chandrasekar S 2011 Contact conditions at the chip-tool interface in machining Int. J. Precis. Eng. Manuf. 12 183–93

    [51] [51] Woon K S, Rahman M, Neo K S and Liu K 2008 The effect of tool edge radius on the contact phenomenon of tool-based micromachining Int. J. Mach. Tools Manuf. 48 1395–407

    [52] [52] Ulutan D and .zel T 2013 Determination of tool friction in presence of flank wear and stress distribution based validation using finite element simulations in machining of titanium and nickel based alloys J. Mater. Process. Technol. 213 2217–37

    [53] [53] Dargusch M S, Sivarupan T, Bermingham M, Rashid R A R, Palanisamy S and Sun S 2020 Challenges in laser-assisted milling of titanium alloys Int. J. Extreme Manuf. 3 015001

    [54] [54] Sato Y and Yan J 2022 Tool path generation and optimization for freeform surface diamond turning based on an independently controlled fast tool servo Int. J. Extreme Manuf. 4 025102

    [55] [55] Wang B, Liu Z Q, Hou X and Zhao J F 2018 Influences of cutting speed and material mechanical properties on chip deformation and fracture during high-speed cutting of Inconel 718 Materials 11 461

    [56] [56] Wang J J, Wang Y K, Zhang J F, Yang Y and Guo P 2021 Structural coloration of non-metallic surfaces using ductile-regime vibration-assisted ultraprecision texturing Light Adv. Manuf. 2 434–45

    [57] [57] LaiXM,LiHT, LiCF, LinZQandNiJ2008Modelling and analysis of micro scale milling considering size effect, micro cutter edge radius and minimum chip thickness Int. J. Mach. Tools Manuf. 48 1–14

    [58] [58] Kim C J, Mayor R and Ni J 2012 Molecular dynamics simulations of plastic material deformation in machining with a round cutting edge Int. J. Precis. Eng. Manuf. 13 1303–9

    [59] [59] Liu H, Guo Y B, Li D and Wang J Q 2021 Material removal mechanism of FCC single-crystalline materials at nano-scales: chip removal & ploughing J. Mater. Process. Technol. 294 117106

    [60] [60] Xie W K and Fang F Z 2020 Mechanism of atomic and close-to-atomic scale cutting of monocrystalline copper Appl. Surf. Sci. 503 144239

    [61] [61] Gao J, Luo X, Fang F and Sun J 2022 Fundamentals of atomic and close-to-atomic scale manufacturing: a review Int. J. Extreme Manuf. 4 012001

    [62] [62] Zhang T, Jiang F, Huang H, Lu J, Wu Y, Jiang Z and Xu X 2021 Towards understanding the brittle–ductile transition in the extreme manufacturing Int. J. Extreme Manuf. 3 022001

    [63] [63] Merchant M E 1945 Mechanics of the metal cutting process. II. Plasticity conditions in orthogonal cutting J. Appl. Phys. 16 318–24

    [64] [64] Albrecht P 1960 New developments in the theory of the metal-cutting process: part I. The ploughing process in metal cutting J. Manuf. Sci. Eng. 82 348–57

    [65] [65] Maekawa K, Kitagawa T and Childs T H C 1997 Friction characteristics at tool-chip interface in steel machining Tribol. Ser. 32 559–67

    [66] [66] Du M H, Cheng Z and Wang S S 2019 Finite element modeling of friction at the tool-chip-workpiece interface in high speed machining of Ti6Al4V Int. J. Mech. Sci. 163 105100

    [67] [67] Grzesik W 2008 Advanced Machining Processes of Metallic Materials (Amsterdam: Elsevier)

    [68] [68] Kopalinsky E M and Oxley P L B 1995 Explaining the mechanics of metallic sliding friction and wear in terms of slipline field models of asperity deformation Wear 190 145–54

    [69] [69] Filice L, Micari F, Rizzuti S and Umbrello D 2007 A critical analysis on the friction modelling in orthogonal machining Int. J. Mach. Tools Manuf. 47 709–14

    [70] [70] Grzesik W 1999 Experimental investigation of the influence of adhesion on the frictional conditions in the cutting process Tribol. Int. 32 15–23

    [71] [71] Bowden F P and Tabor D 2001 The Friction and Lubrication of Solids (Oxford: Oxford University Press)

    [72] [72] Ozlu E, Budak E and Molinari A 2009 Analytical and experimental investigation of rake contact and friction behavior in metal cutting Int. J. Mach. Tools Manuf. 49 865–75

    [73] [73] Zorev N N 1963 Inter-relationship between shear processes occurring along tool face and shear plane in metal cutting Proc. Int. Research in Production Engineering Conf. (New York: ASME) pp 42–49

    [74] [74] Calamaz M, Coupard D and Girot F 2008 A new material model for 2D numerical simulation of serrated chip formation when machining titanium alloy Ti-6Al-4V Int. J. Mach. Tools Manuf. 48 275–88

    [75] [75] Shirakashi T and Usui E 1973 Friction characteristics on tool face in metal machining J. Japan Soc. Precis. Eng. 39 966–72

    [76] [76] Childs T H C 2006 Friction modelling in metal cutting Wear 260 310–8

    [77] [77] Bahi S, Moufki A, Nouari M, El Mansori M and Molinari A 2009 Analysis of tribological parameters during machining Int. J. Mater. Form. 2 221–4

    [78] [78] Zhang C Y, Lu J P, Zhang F P and Butt S I 2017 Identification of a new friction model at tool-chip interface in dry orthogonal cutting Int. J. Adv. Manuf. Technol. 89 921–32

    [79] [79] Zhou F J 2014 A new analytical tool-chip friction model in dry cutting Int. J. Adv. Manuf. Technol. 70 309–19

    [80] [80] Moufki A and Molinari A 2005 A new thermomechanical model of cutting applied to turning operations. Part II. Parametric study Int. J. Mach. Tools Manuf. 45 181–93

    [81] [81] Klocke F, D.bbeler B, Peng B and Schneider S A M 2018 Tool-based inverse determination of material model of direct aged alloy 718 for FEM cutting simulation Proc. CIRP 77 54–57

    [82] [82] Zemzemi F, Rech J, Ben Salem W, Dogui A and Kapsa P 2009 Identification of a friction model at tool/chip/ workpiece interfaces in dry machining of AISI4142 treated steels J. Mater. Process. Technol. 209 3978–90

    [83] [83] Outeiro J C, Campocasso S, Denguir L A, Fromentin G, Vignal V and Poulachon G 2015 Experimental and numerical assessment of subsurface plastic deformation induced by OFHC copper machining CIRP Ann. 64 53–56

    [84] [84] Abouridouane M, Bergs T, Schraknepper D and Wirtz G 2021 Friction behavior in metal cutting: modeling and simulation Proc. CIRP 102 405–10

    [85] [85] Chen L, El-Wardany T I and Harris W C 2004 Modelling the effects of flank wear land and chip formation on residual stresses CIRP Ann. 53 95–98

    [86] [86] Behera B C, Ghosh S and Rao P V 2018 Modeling of cutting force in MQL machining environment considering chip tool contact friction Tribol. Int. 117 283–95

    [87] [87] Banerjee N and Sharma A 2016 Development of a friction model and its application in finite element analysis of minimum quantity lubrication machining of Ti-6Al-4 V J. Mater. Process. Technol. 238 181–94

    [88] [88] Hao M H, Xu D C, Wei F Q and Li Q Q 2018 Quantitative analysis of frictional behavior of cupronickel B10 at the tool-chip interface during dry cutting Tribol. Int. 118 163–9

    [89] [89] Peng B X, Bergs T, Schraknepper D, Smigielski T and Klocke F 2020 Development and validation of a new friction model for cutting processes Int. J. Adv. Manuf. Technol. 107 4357–69

    [90] [90] Wan L and Wang D Z 2015 Numerical analysis of the formation of the dead metal zone with different tools in orthogonal cutting Simul. Model. Pract. Theory 56 1–15

    [91] [91] Duan C Z, Sun W, Fu C and Zhang F Y 2018 Modeling and simulation of tool-chip interface friction in cutting Al/SiCp composites based on a three-phase friction model Int. J. Mech. Sci. 142–143 384–96

    [92] [92] Menezes P L 2017 Influence of cutter velocity, friction coefficient and rake angle on the formation of discontinuous rock fragments during rock cutting process Int. J. Adv. Manuf. Technol. 90 3811–27

    [93] [93] Leopold J and Wohlgemuth R 2010 Modeling and simulation of burr formation: state-of-the-art and future trends Proc. CIRP Int. Conf. Burrs-Analysis, Control and Removal (Kaiserslautern: Springer) pp 79–86

    [94] [94] Shi G Q, Deng X M and Shet C 2002 A finite element study of the effect of friction in orthogonal metal cutting Finite Elem. Anal. Des. 38 863–83

    [95] [95] Arrazola P J, Ugarte D and Domínguez X 2008 A new approach for the friction identification during machining through the use of finite element modeling Int. J. Mach. Tools Manuf. 48 173–83

    [96] [96] Oliaei S N B and Karpat Y 2017 Investigating the influence of friction conditions on finite element simulation of microscale machining with the presence of built-up edge Int. J. Adv. Manuf. Technol. 90 819–29

    [97] [97] Arrazola P J and .zel T 2010 Investigations on the effects of friction modeling in finite element simulation of machining Int. J. Mech. Sci. 52 31–42

    [98] [98] Lorentzon J and J.rvstr.t N 2008 Modelling tool wear in cemented-carbide machining alloy 718 Int. J. Mach. Tools Manuf. 48 1072–80

    [99] [99] Denguir L A, Outeiro J C, Rech J, Fromentin G, Vignal V and Besnard R 2017 Friction model for tool/work material contact applied to surface integrity prediction in orthogonal cutting simulation Proc. CIRP 58 578–83

    [100] [100] Schulze V, Michna J, Zanger F, Faltin C, Maas U and Schneider J 2013 Influence of cutting parameters, tool coatings and friction on the process heat in cutting processes and phase transformations in workpiece surface layers HTM J. Heat Treat. Mater. 68 22–31

    [101] [101] Zanger F, Bollig P and Schulze V 2017 Simulative investigations on different friction coefficient models Proc. CIRP 58 140–5

    [102] [102] Malakizadi A, Hosseinkhani K, Mariano E, Ng E, Del Prete A and Nyborg L 2017 Influence of friction models on FE simulation results of orthogonal cutting process Int. J. Adv. Manuf. Technol. 88 3217–32

    [103] [103] Rech J, Arrazola P J, Claudin C, Courbon C, Pusavec F and Kopac J 2013 Characterisation of friction and heat partition coefficients at the tool-work material interface in cutting CIRP Ann. 62 79–82

    [104] [104] Puls H, Klocke F and Lung D 2014 Experimental investigation on friction under metal cutting conditions Wear 310 63–71

    [105] [105] Chowdhury M A, Das S and Debnath U K 2018 Estimation of the friction coefficient in turning process of metals through model experiment Proc. Inst. Mech. Eng. J 232 685–92

    [106] [106] Faverjon P, Rech J and Leroy R 2013 Influence of minimum quantity lubrication on friction coefficient and work-material adhesion during machining of cast aluminum with various cutting tool substrates made of polycrystalline diamond, high speed steel, and carbides J. Tribol. 135 041602

    [107] [107] Chardon G, Klinkova O, Rech J, Drapier S and Bergheau J M 2015 Characterization of friction properties at the work material/cutting tool interface during the machining of randomly structured carbon fibers reinforced polymer with Poly Crystalline Diamond tool under dry conditions Tribol. Int. 81 300–8

    [108] [108] Da Silva L R R, Ruzzi R S, Teles V C, Sales W F, Guesser W L and Machado A R 2019 Analysis of the coefficient of friction at the workpiece-tool interface in milling of high strength compacted graphite cast irons Wear 426–427 1646–57

    [109] [109] Nouari M and Makich H 2013 Experimental investigation on the effect of the material microstructure on tool wear when machining hard titanium alloys: ti-6Al-4 V and Ti-555 Int. J. Refract. Met. Hard Mater. 41 259–69

    [110] [110] Hassouna A, Mzali S, Zemzemi F and Mezlini S 2022 Effect of geometrical parameters and tool pattern of multi-tooth sawing on cutting of sheet molding compound composite: FE study Mach. Sci. Technol. 26 95–119

    [111] [111] Ding Y C, Shi G F, Zhang H, Shi G Q and Han D D 2020 Analysis of critical negative rake angle and friction characteristics in orthogonal cutting of AL1060 and T2 Sci. Prog. 103 1–18

    [112] [112] Sutter G and Molinari A 2005 Analysis of the cutting force components and friction in high speed machining J. Manuf. Sci. Eng. 127 245–50

    [113] [113] Denkena B, Kr.del A and Beblein S 2021 A novel approach to determine the velocity dependency of the friction behavior during machining by means of digital particle image velocimetry (DPIV) CIRP J. Manuf. Sci. Tech. 32 81–90

    [114] [114] Grzesik W, Rech J and ˙Zak K 2014 Determination of friction in metal cutting with tool wear and flank face effects Wear 317 8–16

    [115] [115] Abouridouane M, Klocke F, Lung D and Veselovac D 2015 The mechanics of cutting: in-situ measurement and modelling Proc. CIRP 31 246–51

    [116] [116] Grzesik W, Denkena B, ˙Zak K, Grove T and Bergmann B 2016 Correlation between friction and wear of Cubic Borone Nitride cutting tools in precision hard machining J. Manuf. Sci. Eng. 138 031010

    [117] [117] Grzesik W, Nies.ony P, Habrat W, Sieniawski J and Laskowski P 2018 Investigation of tool wear in the turning of Inconel 718 superalloy in terms of process performance and productivity enhancement Tribol. Int. 118 337–46

    [118] [118] Ma G J, Wang L L, Gao H X, Zhang J and Reddyhoff T 2015 The friction coefficient evolution of a TiN coated contact during sliding wear Appl. Surf. Sci. 345 109–15

    [119] [119] Grzesik W and ˙Zak K 2013 Friction quantification in the oblique cutting with CBN chamfered tools Wear 304 36–42

    [120] [120] Sen B, Mia M, Krolczyk G M, Mandal U K and Mondal S P 2021 Eco-friendly cutting fluids in minimum quantity lubrication assisted machining: a review on the perception of sustainable manufacturing Int. J. Precis. Eng. Manuf. Green Technol. 8 249–80

    [121] [121] Liu W T and Liu Z Q 2018 High-pressure coolant effect on the surface integrity of machining titanium alloy Ti-6Al-4 V: a review Mater. Res. Express 5 032001

    [122] [122] Braham-Bouchnak T, Germain G, Morel A and Furet B 2015 Influence of high-pressure coolant assistance on the machinability of the titanium alloy Ti555–3 Mach. Sci. Technol. 19 134–51

    [123] [123] Gajrani K K, Suvin P S, Kailas S V and Sankar M R 2019 Hard machining performance of indigenously developed green cutting fluid using flood cooling and minimum quantity cutting fluid J. Clean Prod. 206 108–23

    [124] [124] Banerjee N and Sharma A 2014 Identification of a friction model for minimum quantity lubrication machining J. Clean Prod. 83 437–43

    [125] [125] Liu Z Q, Chen M and An Q L 2015 Investigation of friction in end-milling of Ti-6Al-4 V under different green cutting conditions Int. J. Adv. Manuf. Technol. 78 1181–92

    [126] [126] Maruda R W, Krolczyk G M, Nieslony P, Wojciechowski S, Michalski M and Legutko S 2016 The influence of the cooling conditions on the cutting tool wear and the chip formation mechanism J. Manuf. Process. 24 107–15

    [127] [127] Cabanettes F, Rolland J, Dumont F, Rech J and Dimkovski Z 2016 Influence of minimum quantity lubrication on friction characterizing tool-aluminum alloy contact J. Tribol. 138 021107

    [128] [128] Yin Q G, Li C H, Dong L, Bai X F, Zhang Y B, Yang M, JiaDZ, Li R ZandLiuZ Q 2021 Effects of physicochemical properties of different base oils on friction coefficient and surface roughness in MQL milling AISI 1045 Int. J. Precis. Eng. Manuf. Green Technol. 8 1629–47

    [129] [129] Sharma A K, Katiyar J K, Bhaumik S and Roy S 2019 Influence of alumina/MWCNT hybrid nanoparticle additives on tribological properties of lubricants in turning operations Friction 7 153–68

    [130] [130] Pal A, Chatha S S and Sidhu H S 2020 Experimental investigation on the performance of MQL drilling of AISI 321 stainless steel using nano-graphene enhanced vegetable-oil-based cutting fluid Tribol. Int. 151 106508

    [131] [131] Gajrani K K, Suvin P S, Kailas S V and Mamilla R S 2019 Thermal, rheological, wettability and hard machining performance of MoS2 and CaF2 based minimum quantity hybrid nano-green cutting fluids J. Mater. Process. Technol. 266 125–39

    [132] [132] Faizal M, Saidur R, Mekhilef S and Faizal M 2014 Potential of size reduction of flat-plate solar collectors when applying Al2O3 nanofluid Adv. Mater. Res. 832 149–53

    [133] [133] LvT, HuangSQ,LiuET, MaYLandXuXF2018 Tribological and machining characteristics of an electrostatic minimum quantity lubrication (EMQL) technology using graphene nano-lubricants as cutting fluids J. Manuf. Process. 34 225–37

    [134] [134] Hong S Y, Ding Y C and Jeong W C 2001 Friction and cutting forces in cryogenic machining of Ti-6Al-4 V Int. J. Mach. Tools Manuf. 41 2271–85

    [135] [135] Courbon C, Pusavec F, Dumont F, Rech J and Kopac J 2013 Tribological behaviour of Ti6Al4V and Inconel 718 under dry and cryogenic conditions—Application to the context of machining with carbide tools Tribol. Int. 66 72–82

    [136] [136] Bruschi S, Bertolini R, Bordin A, Medea F and Ghiotti A 2016 Influence of the machining parameters and cooling strategies on the wear behavior of wrought and additive manufactured Ti6Al4V for biomedical applications Tribol. Int. 102 133–42

    [137] [137] Bermingham M J, Kirsch J, Sun S, Palanisamy S and Dargusch M S 2011 New observations on tool life, cutting forces and chip morphology in cryogenic machining Ti-6Al-4 V Int. J. Mach. Tools Manuf. 51 500–11

    [138] [138] Liu J Y, Han R D and Sun Y F 2005 Research on experiments and action mechanism with water vapor as coolant and lubricant in Green cutting Int. J. Mach. Tool. Manuf. 45 687–94

    [139] [139] XuCW, XuY, LiHY, ShiZC,JingHBandLiuMD2017 Friction, wear, and cutting tests on 022Cr17Ni12Mo2 stainless steel under minimum quantity lubrication conditions Int. J. Adv. Manuf. Technol. 90 677–89

    [140] [140] Deng J X, Song W L, Zhang H, Yan P and Liu A H 2011 Friction and wear behaviors of the carbide tools embedded with solid lubricants in sliding wear tests and in dry cutting processes Wear 270 666–74

    [141] [141] ZhangS,XiaoGC,ChenZQ,XuCH,YiMD,LiQand Zhang J J 2020 Influence of CaF2@Al2O3 on cutting performance and wear mechanism of Al2O3/Ti(C,N)/ CaF2@Al2O3 self-lubricating ceramic tools in turning Materials 13 2922

    [142] [142] Deng J X, Cao T K and Liu L L 2005 Self-lubricating behaviors of Al2O3/TiB2 ceramic tools in dry high-speed machining of hardened steel J. Eur. Ceram. Soc. 25 1073–9

    [143] [143] Cao T K, Liu Y J and Xu Y T 2020 Cutting performance of tool with continuous lubrication at tool-chip interface Int. J. Precis. Eng. Manuf. Green Technol. 7 347–59

    [144] [144] Yi M D, Wang J P, Xiao G C, Chen Z Q, Zhang J J, Chen H, Wang L and Xu C H 2022 Effect of gradient design on the mechanical property and friction performance of nano self-lubricating ceramic cutting tool material Ceram. Int. 48 7045–55

    [145] [145] TangSW, WangR,LiuPF, NiuQL,YangGQ,LiuWH and Liu D S 2020 Preparation of WC-TiC-Ni3Al-CaF2 functionally graded self-lubricating tool material by microwave sintering and its cutting performance High Temp. Mater. Process. 39 45–53

    [146] [146] Rosenkranz A, Costa H L, Baykara M Z and Martini A 2021 Synergetic effects of surface texturing and solid lubricants to tailor friction and wear–a review Tribol. Int. 155 106792

    [147] [147] Fatima A and Mativenga P T 2015 A comparative study on cutting performance of rake-flank face structured cutting tool in orthogonal cutting of AISI/SAE 4140 Int. J. Adv. Manuf. Technol. 78 2097–106

    [148] [148] Chang W L, Sun J N, Luo X C, Ritchie J M and Mack C 2011 Investigation of microstructured milling tool for deferring tool wear Wear 271 2433–7

    [149] [149] Niketh S and Samuel G L 2017 Surface texturing for tribology enhancement and its application on drill tool for the sustainable machining of titanium alloy J. Clean. Prod. 167 253–70

    [150] [150] WangQW, YangY, Yao P, ZhangZY, Yu SM,ZhuHTand Huang C Z 2021 Friction and cutting characteristics of micro-textured diamond tools fabricated with femtosecond laser Tribol. Int. 154 106720

    [151] [151] Pang M H, Nie Y F and Ma L J 2018 Effect of symmetrical conical micro-grooved texture on tool-chip friction property of WC-TiC/Co cemented carbide tools Int. J. Adv. Manuf. Technol. 99 737–46

    [152] [152] Xing Y Q, Deng J X, Wu Z, Liu L, Huang P and Jiao A Q 2018 Analysis of tool-chip interface characteristics of self-lubricating tools with nanotextures and WS2/Zr coatings in dry cutting Int. J. Adv. Manuf. Technol. 97 1637–47

    [153] [153] JiangK,Wu XY, LeiJG,XuB,ZhuLK,CaoYX,LiKS, Guo D J and Zhao Y H 2020 Cutting force and tool wear in cutting Ti-6Al-4 V using microstructure-based PCD turning tools Proc. CIRP 95 572–7

    [154] [154] ZhengKR,YangFZ,Pan MZ,ZhaoGDandBianDC 2021 Effect of surface line/regular hexagonal texture on tribological performance of cemented carbide tool for machining Ti-6Al-4 V alloys Int. J. Adv. Manuf. Technol. 116 3149–62

    [155] [155] Enomoto T, Watanabe T, Aoki Y and Ohtake N 2007 Development of a cutting tool with micro structured surface Trans. Japan Soc. Mech. Eng. Ser. C 73 1560–5

    [156] [156] Gajrani K K, Suresh S and Sankar M R 2018 Environmental friendly hard machining performance of uncoated and MoS2 coated mechanical micro-textured tungsten carbide cutting tools Tribol. Int. 125 141–55

    [157] [157] Mishra S K, Ghosh S and Aravindan S 2018 3D finite element investigations on textured tools with different geometrical shapes for dry machining of titanium alloys Int. J. Mech. Sci. 141 424–49

    [158] [158] Shimizu J, Nakayama T, Watanabe K, Yamamoto T, Onuki T, Ojima H and Zhou L B 2020 Friction characteristics of mechanically microtextured metal surface in dry sliding Tribol. Int. 149 105634

    [159] [159] Koshy P and Tovey J 2011 Performance of electrical discharge textured cutting tools CIRP Ann. 60 153–6

    [160] [160] Kawasegi N, Sugimori H, Morimoto H, Morita N and Hori I 2009 Development of cutting tools with microscale and nanoscale textures to improve frictional behavior Precis. Eng. 33 248–54

    [161] [161] Kim D M, Bajpai V, Kim B H and Park H W 2015 Finite element modeling of hard turning process via a micro-textured tool Int. J. Adv. Manuf. Technol. 78 1393–405

    [162] [162] Sun J L, Zhou Y H, Deng J X and Zhao J 2016 Effect of hybrid texture combining micro-pits and micro-grooves on cutting performance of WC/Co-based tools Int. J. Adv. Manuf. Technol. 86 3383–94

    [163] [163] Siju A S, Gajrani K K and Joshi S S 2021 Dual textured carbide tools for dry machining of titanium alloys Int. J. Refract. Met. Hard Mater. 94 105403

    [164] [164] Sivaiah P, Ajay Kumar G V, Singh M M and Kumar H 2020 Effect of novel hybrid texture tool on turning process performance in MQL machining of Inconel 718 superalloy Mater. Manuf. Process. 35 61–71

    [165] [165] Hao X Q, Chen X W, Xiao S N, Li L and He N 2018 Cutting performance of carbide tools with hybrid texture Int. J. Adv. Manuf. Technol. 97 3547–56

    [166] [166] Gajrani K K, Suvin P S, Kailas S V, Rajurkar K P and Sankar M R 2021 Machining of hard materials using textured tool with minimum quantity nano-green cutting fluid CIRP J. Manuf. Sci. Technol. 35 410–21

    [167] [167] ZhangKD,DengJX,XingYQ,LiSPandGaoHH2015 Effect of microscale texture on cutting performance of WC/Co-based TiAlN coated tools under different lubrication conditions Appl. Surf. Sci. 26 107–18

    [168] [168] Liao Z R, Xu D D, Axinte D, M’Saoubi R, Thelin J and Wretland A 2020 Novel cutting inserts with multi-channel irrigation at the chip-tool interface: modelling, design and experiments CIRP Ann. 69 65–68

    [169] [169] HaoXQ,CuiW, LiL,LiHL,KhanAMandHeN2018 Cutting performance of textured polycrystalline diamond tools with composite lyophilic/lyophobic wettabilities J. Mater. Process. Technol. 260 1–8

    [170] [170] Sharma V and Pandey P M 2016 Comparative study of turning of 4340 hardened steel with hybrid textured self-lubricating cutting inserts Mater. Manuf. Process. 31 1904–16

    [171] [171] XingYQ,DengJX,LiSP, Yue HZ,MengRandGao P 2014 Cutting performance and wear characteristics of Al2O3/TiC ceramic cutting tools with WS2/Zr soft-coatings and Nano-textures in dry cutting Wear 318 12–26

    [172] [172] Hao G C and Liu Z Q 2020 The heat partition into cutting tool at tool-chip contact interface during cutting process: a review Int. J. Adv. Manuf. Technol. 108 393–411

    [173] [173] Grzesik W 2000 The influence of thin hard coatings on frictional behaviour in the orthogonal cutting process Tribol. Int. 33 131–40

    [174] [174] Talib R J, Zaharah A M, Selamat M A, Mahaidin A A and Fazira M F 2013 Friction and wear characteristics of WC and TiCN-coated insert in turning carbon steel workpiece Proc. Eng. 68 716–22

    [175] [175] Kumar C S, Zeman P and Polcar T 2020 A 2D finite element approach for predicting the machining performance of nanolayered TiAlCrN coating on WC-Co cutting tool during dry turning of AISI 1045 steel Ceram. Int. 46 25073–88

    [176] [176] Bar-Hen M and Etsion I 2017 Experimental study of the effect of coating thickness and substrate roughness on tool wear during turning Tribol. Int. 110 341–7

    [177] [177] Fallqvist M, Schultheiss F, M’Saoubi R, Olsson M and St.hl J E 2013 Influence of the tool surface micro topography on the tribological characteristics in metal cutting: part I experimental observations of contact conditions Wear 298–299 87–98

    [178] [178] Chang K S, Dong Y J, Zheng G M, Jiang X L, Yang X H, Cheng X, Liu H B and Zhao G X 2022 Friction and wear properties of TiAlN coated tools with different levels of surface integrity Ceram. Int. 48 4433–43

    [179] [179] Mo J L and Zhu M H 2009 Tribological oxidation behaviour of PVD hard coatings Tribol. Int. 42 1758–64

    [180] [180] MeiFS,ChenY, ZhangHD,LinXL,GaoJX,Yuan TC and Cao X X 2021 Greater improvement of carbon and boron co-doping on the mechanical properties, wear resistance and cutting performance of AlTiN coating than that of doping alone Surf. Coat. Technol. 406 126738

    [181] [181] Aihua L, Jianxin D, Haibing C, Yangyang C and Jun Z 2012 Friction and wear properties of TiN, TiAlN, AlTiN and CrAlN PVD nitride coatings Int. J. Refract. Met. Hard Mater. 31 82–88

    [182] [182] Mishra S K, Ghosh S and Aravindan S 2020 Investigations into friction and wear behavior of AlTiN and AlCrN coatings deposited on laser textured WC/Co using novel open tribometer tests Surf. Coat. Technol. 387 125513

    [183] [183] Grzesik W, Zalisz Z and Nieslony P 2002 Friction and wear testing of multilayer coatings on carbide substrates for dry machining applications Surf. Coat. Technol. 155 37–45

    [184] [184] Wang H, Song X, Wang X C and Sun F H 2021 Fabrication, tribological properties and cutting performances of high-quality multilayer graded MCD/NCD/UNCD coated PCB end mills Diam. Relat. Mater. 118 108505

    [185] [185] Vereschaka A, Grigoriev S, Tabakov V, Migranov M, Sitnikov N, Milovich F and Andreev N 2020 Influence of the nanostructure of Ti-TiN-(Ti,Al,Cr) N multilayer composite coating on tribological properties and cutting tool life Tribol. Int. 150 106388

    [186] [186] LianYS,LongYY, ZhaoGL,MuCL,LiXM,DengJX and Xie C P 2020 Performance of CrCN-WS2 hard/soft composite coated tools in dry cutting of titanium alloys J. Manuf. Process. 54 201–9

    [187] [187] LiGJ,ZLW, LiuSY, LiC,ZhouYandWangQ2021 Multilayer-growth of TiAlN/WS self-lubricating composite coatings with high adhesion and their cutting performance on titanium alloy Composites B 211 108620

    [188] [188] Ayed Y, Germain G, Ammar A and Furet B 2013 Degradation modes and tool wear mechanisms in finish and rough machining of Ti17 Titanium alloy under high-pressure water jet assistance Wear 305 228–37

    [189] [189] DangJQ,CaiXJ,Yu DD,AnQL,MingWWandChenM 2020 Effect of material microstructure on tool wear behavior during machining additively manufactured Ti6Al4V Arch. Civ. Mech. Eng. 20 4

    [190] [190] Ayed Y, Germain G, Melsio A P, Kowalewski P and Locufier D 2017 Impact of supply conditions of liquid nitrogen on tool wear and surface integrity when machining the Ti-6Al-4 V titanium alloy Int. J. Adv. Manuf. Technol. 93 1199–206

    [191] [191] Liang X L, Liu Z Q and Wang B 2020 Multi-pattern failure modes and wear mechanisms of WC-Co tools in dry turning Ti-6Al-4 V Ceram. Int. 46 24512–25

    [192] [192] Odelros S, Kaplan B, Kritikos M, Johansson M and Norgren S 2017 Experimental and theoretical study of the microscopic crater wear mechanism in titanium machining Wear 376–377 115–24

    [193] [193] Rahman Rashid R A, Palanisamy S, Sun S and Dargusch M S 2016 Tool wear mechanisms involved in crater formation on uncoated carbide tool when machining Ti6Al4V alloy Int. J. Adv. Manuf. Technol. 83 1457–65

    [194] [194] Grigoriev S, Vereschaka A, Milovich F, Migranov M, Andreev N, Bublikov J, Sitnikov N and Oganyan G 2021 Investigation of the tribological properties of Ti-TiN-(Ti, Al, Nb, Zr) N composite coating and its efficiency in increasing wear resistance of metal cutting tools Tribol. Int. 164 107236

    [195] [195] Koseki S, Inoue K, Morito S, Ohba T and Usuki H 2015 Comparison of TiN-coated tools using CVD and PVD processes during continuous cutting of Ni-based superalloys Surf. Coat. Technol. 283 353–63

    [196] [196] Fox-Rabinovich G S, Yamamoto K, Beake B D, Gershman I S, Kovalev A I, Veldhuis S C, Aguirre M H, Dosbaeva G and Endrino J L 2012 Hierarchical adaptive nanostructured PVD coatings for extreme tribological applications: the quest for nonequilibrium states and emergent behavior Sci. Technol. Adv. Mater. 13 043001

    [197] [197] Sugihara T and Enomoto T 2013 Crater and flank wear resistance of cutting tools having micro textured surfaces Precis. Eng. 37 888–96

    [198] [198] Grzesik W, Kiszka P, Kowalczyk D, Rech J and Claudin C 2012 Machining of nodular cast iron (PF-NCI) using CBN tools Proc. CIRP 1 483–7

    [199] [199] Yuan J F, Fox-Rabinovich G S and Veldhuis S C 2018 Control of tribofilm formation in dry machining of hardened AISI D2 steel by tuning the cutting speed Wear 402–403 30–37

    [200] [200] Shokrani A, Dhokia V and Newman S T 2016 Comparative investigation on using cryogenic machining in CNC milling of Ti-6Al-4V titanium alloy Mach. Sci. Tech. 20 475–94

    [201] [201] Naves V T G, Da Silva M B and Da Silva F J 2013 Evaluation of the effect of application of cutting fluid at high pressure on tool wear during turning operation of AISI 316 austenitic stainless steel Wear 302 1201–8

    [202] [202] Kaynak Y, Karaca H E, Noebe R D and Jawahir I S 2013 Tool-wear analysis in cryogenic machining of NiTi shape memory alloys: a comparison of tool-wear performance with dry and MQL machining Wear 306 51–63

    [203] [203] Maruda R W, Krolczyk G M, Feldshtein E, Nieslony P, Tyliszczak B and Pusavec F 2017 Tool wear characterizations in finish turning of AISI 1045 carbon steel for MQCL conditions Wear 372–373 54–67

    [204] [204] Günay M, Korkmaz M E and Yas.ar N 2020 Performance analysis of coated carbide tool in turning of Nimonic 80A superalloy under different cutting environments J. Manuf. Process. 56 678–87

    [205] [205] Said Z, Gupta M, Hegab H, Arora N, Khan A M, Jamil M and Bellos E 2019 A comprehensive review on minimum quantity lubrication (MQL) in machining processes using nano-cutting fluids Int. J. Adv. Manuf. Technol. 105 2057–86

    [206] [206] Bermingham M J, Palanisamy S, Kent D and Dargusch M S 2012 A comparison of cryogenic and high pressure emulsion cooling technologies on tool life and chip morphology in Ti-6Al-4 V cutting J. Mater. Process. Technol. 212 752–65

    [207] [207] Seid Ahmed Y, Paiva J M, Covelli D and Veldhuis S C 2017 Investigation of coated cutting tool performance during machining of super duplex stainless steels through 3D wear evaluations Coatings 7 127

    [208] [208] LüWZ,LiGJ,ZhouYY, LiuSY, WangKandWangQ 2020 Effect of high hardness and adhesion of gradient TiAlSiN coating on cutting performance of titanium alloy J. Alloys Compd. 820 153137

    [209] [209] Wang C C, Wang X C and Sun F H 2018 Tribological behavior and cutting performance of monolayer, bilayer and multilayer diamond coated milling tools in machining of zirconia ceramics Surf. Coat. Technol. 353 49–57

    [210] [210] Fox-Rabinovich G S, Gershman I, Hakim M A E, Shalaby M A, Krzanowski J E and Veldhuis S C 2014 Tribofilm formation as a result of complex interaction at the tool/chip interface during cutting Lubricants 2 113–23

    [211] [211] HaoTM,DuJ,SuGS,ZhangPR,SunYJandZhangJJ 2020 Mechanical and cutting performance of cemented carbide tools with Cr/x/DLC composite coatings Int. J. Adv. Manuf. Technol. 106 5241–54

    [212] [212] Sadik M I and Isakson S 2017 The role of PVD coating and coolant nature in wear development and tool performance in cryogenic and wet milling of Ti-6Al-4 V Wear 386–387 204–10

    [213] [213] LiuZQ,AnQL,XuJY, ChenMandHanS2013Wear performance of (nc-AlTiN)/(a-Si3N4) coating and (nc-AlCrN)/(a-Si3N4) coating in high-speed machining of titanium alloys under dry and minimum quantity lubrication (MQL) conditions Wear 305 249–59

    [214] [214] Musavi S H, Davoodi B and Nankali M 2021 Assessment of tool wear and surface integrity in ductile cutting using a developed tool Arab. J. Sci. Eng. 46 7773–87

    [215] [215] Wu Z, Deng J X, Chen Y, Xing Y Q and Zhao J 2012 Performance of the self-lubricating textured tools in dry cutting of Ti-6Al-4 V Int. J. Adv. Manuf. Technol. 62 943–51

    [216] [216] DangJQ,LiuGY, ChenYF, AnQL,MingWWand Chen M 2019 Experimental investigation on machinability of DMLS Ti6Al4V under dry drilling process Mater. Manuf. Process. 34 749–58

    [217] [217] Sun S J, Brandt M and Dargusch M S 2017 Effect of tool wear on chip formation during dry machining of Ti-6Al-4 V alloy, part 1: effect of gradual tool wear evolution Proc. Inst. Mech Eng. B 231 1559–74

    [218] [218] Wang Q, Lu C, Ye G G and Dai L H 2015 Modelling the tuned criticality in stick-slip friction during metal cutting Model. Simul. Mater. Sci. Eng. 23 055013

    [219] [219] Ming W W, Dang J Q, An Q L and Chen M 2020 Chip formation and hole quality in dry drilling additive manufactured Ti6Al4V Mater. Manuf. Process. 35 43–51

    [220] [220] Pu C L, Zhu G, Yang S B, Yue E B and Subramanian S V 2016 Effect of dynamic recrystallization at tool-chip interface on accelerating tool wear during high-speed cutting of AISI1045 steel Int. J. Mach. Tools Manuf. 100 72–80

    [221] [221] Mabrouki T, Courbon C, Zhang Y C, Rech J, Nélias D, Asad M, Hamdi H, Belhadi S and Salvatore F 2016 Some insights on the modelling of chip formation and its morphology during metal cutting operations C. R. Mécanique 344 335–54

    [222] [222] He Q, Paiva J M, Kohlscheen J, Beake B D and Veldhuis S C 2020 An integrative approach to coating/carbide substrate design of CVD and PVD coated cutting tools during the machining of austenitic stainless steel Ceram. Int. 46 5149–58

    [223] [223] LiangXL,LiuZQ,WangB,SongQH,CaiYKandWan Y 2021 Prediction of residual stress with multi-physics model for orthogonal cutting Ti-6Al-4 V under various tool wear morphologies J. Mater. Process. Technol. 288 116908

    [224] [224] M’Saoubi R, Larsson T, Outeiro J, Guo Y, Suslov S, Saldana C and Chandrasekar S 2012 Surface integrity analysis of machined Inconel 718 over multiple length scales CIRP Ann. 61 99–102

    [225] [225] Che-Haron C H and Jawaid A 2005 The effect of machining on surface integrity of titanium alloy Ti–6% Al–4% V J. Mater. Process. Technol. 166 188–92

    [226] [226] Sharman A R C, Hughes J I and Ridgway K 2008 Surface integrity and tool life when turning Inconel 718 using ultra-high pressure and flood coolant systems Proc. Inst. Mech. Eng. B 222 653–64

    [227] [227] Arrazola P J, Garay A, Fernandez E and Ostolaza K 2014 Correlation between tool flank wear, force signals and surface integrity when turning bars of Inconel 718 in finishing conditions Int. J. Mach. Machinabil. Mater. 15 84–100

    [228] [228] Shunmugavel M, Polishetty A, Goldberg M, Singh R P and Littlefair G 2016 Tool wear and surface integrity analysis of machined heat treated selective laser melted Ti-6Al-4V Int. J. Mater. Form. Mach. Process. 3 50–63

    [229] [229] Hughes J I, Sharman A R C and Ridgway K 2006 The effect of cutting tool material and edge geometry on tool life and workpiece surface integrity Proc. Inst. Mech. Eng. B 220 93–107

    [230] [230] Liang X L and Liu Z Q 2017 Experimental investigations on effects of tool flank wear on surface integrity during orthogonal dry cutting of Ti-6Al-4 V Int. J. Adv. Manuf. Technol. 93 1617–26

    [231] [231] Dang J Q, Zang H, An Q L, Ming W W and Chen M 2022 Feasibility study of creep feed grinding of 300M steel with zirconium corundum wheel Chin. J. Aeronaut 35 565–78

    [232] [232] Dang J Q, Zhang H, An Q L, Ming W W and Chen M 2021 Surface modification of ultrahigh strength 300M steel under supercritical carbon dioxide (scCO2)-assisted grinding process J. Manuf. Process. 61 1–14

    [233] [233] Kwong J, Axinte D A, Withers P J and Hardy M C 2009 Minor cutting edge-workpiece interactions in drilling of an advanced nickel-based superalloy Int. J. Mach. Tools Manuf. 49 645–58

    [234] [234] Miao Q, Ding W, Xu J, Cao L, Wang H, Yin Z, Dai C and Kuang W 2021 Creep feed grinding induced gradient microstructures in the superficial layer of turbine blade root of single crystal nickel-based superalloy Int. J. Extreme Manuf. 3 045102

    [235] [235] Xu W, Li C H, Zhang Y, Ali H M, Sharma S, Li R, Yang M, Gao T, Liu M and Wang X 2022 Electrostatic atomization minimum quantity lubrication machining: from mechanism to application Int. J. Extreme Manuf. 4 042003

    [236] [236] Xu X, Zhang J, Liu H G, He Y and Zhao W H 2019 Grain refinement mechanism under high strain-rate deformation in machined surface during high speed machining Ti6Al4V Mater. Sci. Eng. A 752 167–79

    [237] [237] DangJQ,ZhangH,AnQL,LianGH,LiYG,WangHW and Chen M 2021 Surface integrity and wear behavior of 300M steel subjected to ultrasonic surface rolling process Surf. Coat. Technol. 421 127380

    [238] [238] Axinte D A, Andrews P, Li W, Gindy N, Withers P J and Childs T H C 2006 Turning of advanced Ni based alloys obtained via powder metallurgy route CIRP Ann. 55 117–20

    [239] [239] Herbert C R J, Axinte D A, Hardy M C and Brown P D 2011 Investigation into the characteristics of white layers produced in a nickel-based superalloy from drilling operations Proc. Eng. 19 138–43

    [240] [240] .sterle W and Li P X 1997 Mechanical and thermal response of a nickel-base superalloy upon grinding with high removal rates Mater. Sci. Eng. A 238 357–66

    [241] [241] Liang X L, Liu Z Q, Ren X P and Wang B 2021 Tool wear induced the gradient distribution of surface integrity with process-microstructure-property characteristics after turning Ti-6Al-4 V J. Manuf. Process. 70 570–7

    [242] [242] Hood R, Soo S L, Aspinwall D K and Mantle A L 2018 Tool life and workpiece surface integrity when turning an RR1000 nickel-based superalloy Int. J. Adv. Manuf. Technol. 98 2461–8

    [243] [243] Fernández-Valdivielso A, López De Lacalle L N, Urbikain G and Rodriguez A 2016 Detecting the key geometrical features and grades of carbide inserts for the turning of nickel-based alloys concerning surface integrity Proc. Inst. Mech. Eng. C 230 3725–42

    [244] [244] Ginting A and Nouari M 2009 Surface integrity of dry machined titanium alloys Int. J. Mach. Tools Manuf. 49 325–32

    [245] [245] Mantle A L and Aspinwall D K 2001 Surface integrity of a high speed milled gamma titanium aluminide J. Mater. Process. Technol. 118 143–50

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    [in Chinese], [in Chinese], [in Chinese], [in Chinese], [in Chinese]. Friction behaviors in the metal cutting process: state of the art and future perspectives[J]. International Journal of Extreme Manufacturing, 2023, 5(1): 12002

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    Paper Information

    Category: Topical Review

    Received: May. 8, 2022

    Accepted: --

    Published Online: Jul. 26, 2024

    The Author Email: (melius@sdu.edu.cn)

    DOI:10.1088/2631-7990/ac9e27

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