[1] ZHOU T, FALESKOG J, BABU R P, et al. Exploring the relationship between the microstructure and strength of fresh and tempered martensite in a maraging stainless steel Fe-15Cr-5Ni[J]. Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing, 2019, 745:420-428. [2] ZHU D H, FENG X Z, XU X H, et al. Robotic grinding of complex components:A step towards efficient and intelligent machining-challenges, solutions, and applications[J]. Robotics and Computer-Integrated Manufacturing, 2020, 65:101908. [3] LIU Shuang, LI Min, DING Wenfeng, et al. Study on creep-feed deep grinding of K444 nickel-based superalloy with corundum grinding wheel[J]. Diamond & Abrasives Engineering, 2021, 41, 244(4):72-81. 刘爽, 李敏, 丁文锋, 等. 刚玉砂轮缓进深切磨削K444镍基高温合金研究[J]. 金刚石与磨料磨具工程, 2021, 41, 244(4):72-81. [4] DING Wenfeng, MIAO Qing, LI Benkai, et al. Review on grinding technology of nickel-based superalloys used for aero-engine[J]. Journal of Mechanical Engineering, 2019, 55(1):189-215. 丁文锋, 苗情, 李本凯, 等. 面向航空发动机的镍基合金磨削技术研究进展[J]. 机械工程学报, 2019, 55(1):189-215. [5] DING Z S, LI B Z, LIANG S Y. Phase transformation and residual stress of Maraging C250 steel during grinding[J]. Materials Letters, 2015, 154:37-39. [6] DAI Qifeng, SONG Renbo, GUAN Xiaoxia, et al. Effects of ferrite grain size on dynamic deformation behavior of ferrite-martensite dual phase steel DP980[J]. Journal of Mechanical Engineering, 2012, 48(6):44-50. 代启锋, 宋仁伯, 关小霞, 等. 铁素体晶粒尺寸对铁素体-马氏体双相钢DP980动态变形行为影响[J]. 机械工程学报, 2012, 48(6):44-50. [7] YAO Y, ZHU H T, HUANG C Z, et al. On the relations between the specific cutting energy and surface generation in micro-milling of maraging steel[J]. International Journal of Advanced Manufacturing Technology, 2019, 104 (1-4):585-598. [8] ZHOU Wenwen, WANG Jianqing, ZHAO Jing, et al. Experimental research on single abrasive grain scratch SiCf/SiC ceramic matrix composite[J]. Diamond & Abrasives Engineering, 2021, 41(1):51-57. 周雯雯, 王建青, 赵晶, 等. 单颗磨粒划擦SiC_f/SiC陶瓷基复合材料的试验研究[J]. 金刚石与磨料磨具工程, 2021, 41 (1):51-57. [9] HAN Yu, CHEN Xuedong, LIU Quankun, et al. Study on technique and properties of cold stretching for austenitic stainless steels[J]. Journal of Mechanical Engineering, 2012, 48(2):87-92. 韩豫, 陈学东, 刘全坤, 等. 奥氏体不锈钢应变强化工艺及性能研究[J]. 机械工程学报, 2012, 48(2):87-92. [10] JERMOLAJEV S, EPP J, HEINZEL C, et al. Material modifications caused by thermal and mechanical load during grinding[J]. Procedia CIRP, 2016, 45:43-46. [11] DING Z S, LI B Z, LIANG S Y. Maraging steel phase transformation in high strain rate grinding[J]. International Journal of Advanced Manufacturing Technology, 2015, 80 (1-4):711-718. [12] WU C J, PANG J Z, LI B Z, et al. High-speed grinding of HIP-SiC ceramics on transformation of microscopic features[J]. International Journal of Advanced Manufacturing Technology, 2019, 102 (5-8):1913-1921. [13] PERLA S, KULKARNI S, BALACHANDRAN G, et al. Influence of section size and grain size on the microstructure evolution and mechanical properties in steel grade AISI 5160[J]. Transactions of the Indian Institute of Metals, 2017, 70 (9):2449-2458. [14] RODRIGUES D G, De ALCANTARA C M, De OLIUEIRA T R, et al. The effect of grain size and initial texture on microstructure, texture, and formability of Nb stabilized ferritic stainless steel manufactured by two-step cold rolling[J]. Journal of Materials Research and Technology-JMR & T, 2019, 8 (5):4151-4162. [15] SIMM T, SUN L, MCADAM S, et al. The Influence of lath, block and prior austenite grain (PAG) size on the tensile, creep and fatigue properties of novel maraging steel[J]. Materials, 2017, 10 (7):730. [16] Da SILVA M J G, CARDOSO J L, CARVALHO D S, et al. The effect of prior austenite grain size on hydrogen embrittlement of Co-containing 18Ni 300 maraging steel[J]. International Journal of Hydrogen Energy, 2019, 44 (33):18606-18615. [17] ZHAO Xuechuan. Research on nonhomogeneous dislocation nucleation and interaction between dislocation and grain boundary[D]. Beijing:Tsinghua University, 2011. 赵雪川. 位错非均匀形核及与晶界作用研究[D]. 北京:清华大学, 2011. [18] YEDDU H K. Phase-field modeling of austenite grain size effect on martensitic transformation in stainless steels[J]. Computational Materials Science, 2018, 154:75-83. [19] WANG M M, TASAN C C, PONGE D, et al. Smaller is less stable:Size effects on twinning vs. transformation of reverted austenite in TRIP-maraging steels[J]. Acta Materialia, 2014, 79:268-281. [20] LI X C, XIA D X, WANG X L, et al. Effect of austenite grain size and accelerated cooling start temperature on the transformation behaviors of multi-phase steel[J]. Science China-Technological Sciences, 2013, 56(1):66-70. [21] RYKLINA E P, POLYAKOVA K A, TABACHKOVA N Y, et al. Effect of B2 austenite grain size and aging time on microstructure and transformation behavior of thermomechanically treated titanium nickelide[J]. Journal of Alloys and Compounds, 2018, 764:626-638. [22] AVRAMI M. Kinetics of phase change. I General theory[J]. The Journal of Chemical Physics, 1939, 7(12):1103-1112. [23] KOSISTINEN, D P, MARBURGER R E. A general equation prescribing extent of austenite-martensite transition in pure Fe-C alloys and plain carbon steel[J]. Acta. Metall., 1959, 7:50-60. [24] DING Z S, LI B Z, SHAO Y M, et al. Phase transition at high heating rate and strain rate during maraging steel C250 grinding[J]. Materials and Manufacturing Processes, 2016, 31 (13):1763-1769. |