[1]任敬心, 康仁科, 王西彬. 难加工材料磨削技术[M]. 北京:电子工业出版社, 2011.
REN Jingxin, KANG Renke, WANG Xibin. Grinding Technology for Difficult-to-process Materials[M]. Beijing:Publishing House of Electronics Industry, 2011.
[2]BIFANO T G, DOW T A, SCATTERGOOD R O. Ductile-regime Grinding:a New Technology for Machining Brittle Materials[J]. Journal of Engineering for Industry, 1991, 113(2):184-189.
[3]OBIKAWA T, USUI E. Computational Machining of Titanium Alloy—Finite Element Modeling and a Few Results[J]. Journal of Manufacturing Science and Engineering, 1996, 118(2):208-215.
[4]HARZALLAH M, POTTIER T, GILBLAS R, et al. Thermo-mechanical Coupling Investigation in Ti-6Al-4V Orthogonal Cutting:Experimental and Numerical Confrontation[J]. International Journal of Mechanical Sciences, 2020, 169:105322.
[5]ZHANG Xiaodong, LUO Ming, ZHANG Dinghua. High Performance Cutting of Titanium Alloy Based on the Thermo-mechanical Coupling Effect[J]. Procedia CIRP, 2018, 77:126-129.
[6]同晓芳. 磨削区温度场有限元分析及仿真[D]. 武汉:武汉理工大学, 2007.
TONG Xiaofang. Finite Element Analysis and Simulation of Temperature Field in Grinding Zone[D]. Wuhan:Wuhan University of Technology, 2007.
[7]冯垚垚. TC4钛合金微观磨粒磨削加工仿真技术研究[D]. 西安:西安理工大学, 2020.
FENG Yaoyao. Research on Simulation Technology of Micro-abrasive Grinding of TC4 Titanium Alloy[D]. Xian:Xian University of Technology, 2020.
[8]田梦. 三维螺线超声振动磨削硬脆材料的热力耦合作用机理SPH仿真研究[D]. 北京:北京理工大学, 2015.
TIAN Meng. SPH Simulation Study on Thermal-mechanical Coupling Mechanism of Three-dimensional Spiral Ultrasonic Vibration Grinding of Hard and Brittle Materials[D]. Beijing:Beijing Institute of Technology, 2015.
[9]吴书安, 祝锡晶, 郭策. 基于热力耦合的单磨粒临界磨削仿真分析[J]. 表面技术, 2016, 45(8):144-149.
WU Shuan, ZHU Xijing, GUO Ce. Simulation Analysis of Single-grain Critical Grinding Based on Thermal-mechanical Coupling[J]. Surface Technology, 2016, 45(8):144-149.
[10]YAN Yanyan, ZHANG Zhaoqing, ZHAO Bo, et al. Study on Prediction of Three-dimensional Surface Roughness of Nano-ZrO2 Ceramics under Two-dimensional Ultrasonic-assisted Grinding[J]. The International Journal of Advanced Manufacturing Technology, 2021, 112:2623-2638.
[11]MALKIN S, GUO C S. Grinding Technology:Theory and Applications of Machining with Abrasives[M]. New York:Industrial Press, 2008.
[12]DABROWSKI L, MARCINIAK L. Investigation into the Phenomenological Aspects of the Grinding Process[J]. Proceedings of the Institution of Mechanical Engineers, Part B:Journal of Engineering Manufacture, 2004, 218(5):495-502.
[13]WANG Sheng, LI Changhe, ZHANG Dongkun, et al. Modeling the Operation of a Common Grinding Wheel with Nanoparticle Jet Flow Minimal Quantity Lubrication[J]. The International Journal of Advanced Manufacturing Technology, 2014, 74(5/8):835-850.
[14]HOU Z B, KOMANDURI R. On the Mechanics of the Grinding Process—Part I. Stochastic Nature of the Grinding Process[J]. International Journal of Machine Tools and Manufacture, 2003, 43(15):1579-1593.
[15]XIE Y, WILLIAMS J A. The Prediction of Friction and Wear When a Soft Surface Slides against a Harder Rough Surface[J]. Wear, 1996, 196(1):21-34.
[16]ABDOLHAMID A, MEHRDAD M. Modeling and Analysis of Grinding Forces Based on the Single Grit Scratch[J]. The International Journal of Advanced Manufacturing Technology, 2015, 78(5/8):1223-1231.
[17]WILLIAMS J A, XIE Y. The Generation of Wear Surfaces by the Interaction of Parallel Grooves[J]. Elsevier, 1992, 155(2):363-379.
[18]李伯民, 赵波. 现代磨削技术[M]. 北京:机械工业出版社, 2003.
LI Bomin, ZHAO Bo. Modern Grinding Technology[M]. Beijing:China Machinery Industry Press, 2003.
[19]ZHANG Dongkun, LI Changhe, ZHANG Yanbin, et al. Experimental Research on the Energy Ratio Coefficient and Specific Grinding Energy in Nanoparticle Jet MQL Grinding[J]. The International Journal of Advanced Manufacturing Technology, 2015, 78(5/8):1275-1288.
[20]ZHANG Lei, BRIAN R W. Study of Convective Heat Transfer in Grinding Applied to Tool Carbide[J]. Journal of Manufacturing Science and Engineering, 2020, 142(2):021001-021008.
[21]ISMAIL L, YUSUF A. Prediction of Tool and Chip Temperature in Continuous and Interrupted Machining[J]. International Journal of Machine Tools and Manufacture, 2002, 42(9):1011-1022.
[22]JOHNSON G C, BAMMANN D J. A Discussion of Stress Rates in Finite Deformation Problems[J]. International Journal of Solids and Structures, 1984, 20(8):725-737.
[23]惠旭龙, 牟让科, 白春玉, 等. TC4钛合金动态力学性能及本构模型研究[J]. 振动与冲击, 2016, 35(22):161-168.
HUI Xulong, MU Rangke, BAI Chunyu, et al. Research on Dynamic Mechanical Properties and Constitutive Model of TC4 Titanium Alloy[J]. Vibration and Shock, 2016, 35(22):161-168.
[24]KAY G. Failure Modeling of Titanium6Al4V and 2024 T3 Aluminum with the Johnson Cook Material Model[R]. Springfield, Virginia:Nation Technical Information Service(NTIS), 2003.