Klocke F, Soo S L, Karpuschewski B, Webster J A, Novovic D, Elfizy A, Axinte D A and Tönissen S 2015 Abrasive machining of advanced aerospace alloys and composites CIRP Ann.-Manuf. Technol. 64581–604 |
Sun J Y, Yang S and Yuan H 2021 Assessment of thermo-mechanical fatigue in a nickel-based single-crystal superalloy CMSX-4 accounting for temperature gradient effects Mater. Sci. Eng. A 809140918 |
Miao Q, Ding W F, Kuang W J and Yang C Y 2021 Grinding force and surface quality in creep feed profile grinding of turbine blade root of nickel-based superalloy with microcrystalline alumina abrasive wheels Chin. J. Aeronaut. 34576–85 |
Chen J J, Fu Y C, Qian N, Jiang H F, Ching C Y, Ewing D and Dai C W 2021 Investigation on cooling behavior of axially rotating heat pipe in profile grinding of turbine blade slots Appl. Therm. Eng. 182116031 |
Aspinwall D K, Soo S L, Curtis D T and Mantle A L 2007 Profiled superabrasive grinding wheels for the machining of a nickel based superalloy CIRP Ann.-Manuf. Technol. 56335–8 |
Li H N, Zhao Y J, Cao S Y, Chen H, Wu C Q, Qi H, Sun X, Wang H X, Li C H and Liu G Y 2021 Controllable generation of 3D textured abrasive tools via multiple-pass laser ablation J. Mater. Process. Technol. 295117149 |
Fan Z H, Tian Y B, Zhou Q and Shi C 2020 A magnetic shear thickening media in magnetic field–assisted surface finishing Proc. Inst. Mech. Eng. B 2341069–72 |
Chen J J, Fu Y C, Qian N, Ching C Y, Ewing D and He Q S 2021 A study on thermal performance of revolving heat pipe grinding wheel Appl. Therm. Eng. 182116065 |
Tian Y B, Li L G, Han J G, Fan Z H and Liu K 2021 Development of novel high-shear and low-pressure grinding tool with flexible composite Mater. Manuf. Process. 36479–87 |
Tian Y B, Li L G, Liu B, Han J G and Fan Z H 2020 Experimental investigation on high-shear and low-pressure grinding process for Inconel718 superalloy Int. J. Adv. Manuf. Technol. 1073425–35 |
Liao Z R, la Monaca A, Murray J, Speidel A, Ushmaev D, Clare A, Axinte D and M’Saoubi R 2021 Surface integrity in metal machining—part I: fundamentals of surface characteristics and formation mechanisms Int. J. Mach. Tools Manuf. 162103687 |
Xu Y C, Gong Y D, Wang Z X, Wen X L, Yin G Q, Zhang H and Qi Y 2021 Experimental study of Ni-based single-crystal superalloy: microstructure evolution and work hardening of ground subsurface Arch. Civ. Mech. Eng. 2143 |
Wang Y S, Xiu S C and Zhang S N 2021 Microstructure evolution and crystallographic slip modes during grind hardening in TC21 titanium alloy Surf. Coat. Technol. 417127211 |
Thakur A and Gangopadhyay S 2016 State-of-the-art in surface integrity in machining of nickel-based super alloys Int. J. Mach. Tools Manuf. 10025–54 |
Wenfeng D, Jiuhua X, Zhenzhen C, Honghua S and Yucan Y C 2010 Grindability and surface integrity of cast nickel-based superalloy in creep feed grinding with brazed CBN abrasive wheels Chin. J. Aeronaut. 23501–10 |
Curtis D T, Soo S L, Aspinwall D K and Mantle A L 2016 Evaluation of workpiece surface integrity following point grinding of advanced titanium and nickel based alloys Proc. CIRP 4547–50 |
Liao Z R, Polyakov M, Diaz O G, Axinte D, Mohanty G, Maeder X, Michler J and Hardy M 2019 Grain refinement mechanism of nickel-based superalloy by severe plastic deformation—mechanical machining case Acta Mater. 1802–14 |
Ding J, Li Q, Li J, Xue S, Fan Z, Wang H and Zhang X 2018 Mechanical behavior of structurally gradient nickel alloy Acta Mater. 14957–67 |
Liu X C, Zhang H W and Lu K 2013 Strain-induced ultrahard and ultrastable nanolaminated structure in nickel Science 342337–40 |
Liu X C, Zhang H W and Lu K 2015 Formation of nano-laminated structure in nickel by means of surface mechanical grinding treatment Acta Mater. 9624–36 |
Reed R C 2006 The Superalloys: Fundamentals and Applications (Cambridge: Cambridge University Press) |
Jichun X, Jiarong L and Shizhong L 2010 Surface recrystallization in nickel base single crystal superalloy DD6 Chin. J. Aeronaut. 23478–85 |
Swaminathan S et al 2005 Large strain deformation and ultra-fine grained materials by machining Mater. Sci. Eng. A 410–1358–63 |
Xiong X H, Quan D M, Dai P D, Wang Z P, Zhang Q X and Yue Z F 2015 Tensile behavior of nickel-base single-crystal superalloy DD6 Mater. Sci. Eng. A 636608–12 |
Miao Q, Li H N and Ding W F 2020 On the temperature field in the creep feed grinding of turbine blade root: simulation and experiments Int. J. Heat Mass Transfer 147118957 |
Miao Q, Ding W F, Kuang W J and Xu J H 2020 Tool wear behavior of vitrified microcrystalline alumina wheels in creep feed profile grinding of turbine blade root of single crystal nickel-based superalloy Tribol. Int. 145106144 |
Chen Y X, Yang Y Q, Feng Z Q, Huang B and Luo X 2017 Surface gradient nanostructures in high speed machined 7055 aluminum alloy J. Alloys Compd. 726367–77 |
Wu C J, Guo W C, Li R, Zhao Y D and Zhou Q Z 2020 Thermal effect on oxidation layer evolution and phase transformation in grinding of Fe-Ni super alloy Mater. Lett. 275128072 |
Cheng Z, Zhou H F, Lu Q H, Gao H J and Lu L 2018 Extra strengthening and work hardening in gradient nanotwinned metals Science 362 eaau1925 |
Lu K 2016 Stabilizing nanostructures in metals using grain and twin boundary architectures Nat. Rev. 116019 |
Sun L G, Wu G, Wang Q and Lu J 2020 Nanostructural metallic materials: structures and mechanical properties Mater. Today 38114–35 |
Wang M, Jiang Y B, Li Z, Xiao Z, Gong S, Qiu W T and Lei Q 2021 Microstructure evolution and deformation behaviour of Cu-10 wt%Fe alloy during cold rolling Mater. Sci. Eng. A 801140379 |
Liu X M, Nakatani M, Gao H L, Sharma B, Pan H J, Fu Z R, Li X F, Ameyama K and Zhu X K 2021 Effect of staking fault energy on deformation mechanisms in Cu and Cu-30% Zn alloy with gradient structure obtained by SMAT J. Alloys Compd. 865158863 |
Li C, Cui W F and Zhang Y S 2017 Surface self-nanocrystallization of α +β titanium alloy by surface mechanical grinding treatment Met. Mater. Int. 23512–8 |
Lu K 2014 Making strong nanomaterials ductile with gradients Science 3451455–6 |
Merchant M E 1945 Mechanics of the metal cutting process Ⅱ. Plasticity conditions in orthogonal cutting J. Appl. Phys. 16318–24 |
Oxley P L B 1989 The Mechanics of Machining: An Analytical Approach to Assessing Machinability (Chichester: Ellis Horwood Limited) |
Malkin S and Guo C S 2008 Grinding Technology: Theory and Applications of Machining with Abrasives 2nd edn (New York: Industrial Press) |
Yan L, Li X K, Jiang F, Zhou Z X and Rong Y M 2009 Research on microscopic grain-workpiece interaction in grinding through micro-cutting simulation, part 2: factorial study Adv. Mater. Res. 76–7815–20 |
Ohbuchi Y and Obikawa T 2003 Finite element modeling of chip formation in the domain of negative rake angle cutting J. Eng. Mater. Technol. 125324–32 |
Jin T 1999 Fundamental Research on High Efficiency Deep Grinding Technology (Shenyang: Northeastern University) |
Bay B, Hansen N, Hughes D A and Kuhlmann-Wilsdorf D 1992 Overview no. 96 evolution of f.c.c. deformation structures in polyslip Acta Metall. Mater. 40205–19 |
Hughes D A and Hansen N 1997 High angle boundaries formed by grain subdivision mechanisms Acta Mater. 453871–86 |
Zhang B and Shim V P W 2010 Effect of strain rate on microstructure of polycrystalline oxygen-free high conductivity copper severely deformed at liquid nitrogen temperature Acta Mater. 586810–27 |
Yang M X, Pan Y, Yuan F P, Zhu Y T and Wu X L 2016 Back stress strengthening and strain hardening in gradient structure Mater. Res. Lett. 4145–51 |
Li W L, Tao N R and Lu K 2008 Fabrication of a gradient nano-micro-structured surface layer on bulk copper by means of a surface mechanical grinding treatment Scr. Mater. 59546–9 |
Rowe W 2017 Temperatures in grinding—a review J. Manuf. Sci. Eng. 139121001 |
Lu K, Lu L and Suresh S 2009 Strengthening materials by engineering coherent internal boundaries at the nanoscale Science 324349–52 |
Lu L 2004 Ultrahigh strength and high electrical conductivity in copper Science 304422–6 |
Laplanche G, Wieczorek N, Fox F, Berglund S, Pfetzing-Micklich J, Kishida K, Inui H and Eggeler G 2018 On the influence of crystallography and dendritic microstructure on micro shear behavior of single crystal Ni-based superalloys Acta Mater. 160173–84 |
Luo J T, Yu W L, Xi C Y, Zhang C X and Ma C H 2019 Preparation of ultrafine-grained GH4169 superalloy by high-pressure torsion and analysis of grain refinement mechanism J. Alloys Compd. 777157–64 |
Wu X L, Jiang P, Chen L, Zhang J F, Yuan F P and Zhu Y T 2014 Synergetic strengthening by gradient structure Mater. Res. Lett. 2185–91 |
Fang T H, Li W L, Tao N R and Lu K 2011 Revealing extraordinary intrinsic tensile plasticity in gradient nano-grained copper Science 3311587–90 |