[1]CARVALHO S R D, MACHADO A R, SILVA M B D, et al. Analyses of Effects of Cutting Parameters on Cutting Edge Temperature Using Inverse Heat Conduction Technique [J]. Mathematical Problems in Engineering, 2014, 2014(6): 1-11.
[2]HADDAG B, NOUARI M. Tool Wear and Heat Transfer Analyses in Dry Machining Based on Multi-steps Numerical Modelling and Experimental Validation [J]. Wear, 2013, 302(1/2): 1158-1170.
[3]LIU W, REN D, USUI S, et al. A Gear Cutting Predictive Model Using the Finite Element Method [J]. Procedia CIRP, 2013, 8(1): 51-56.
[4]FAHAD M, MATIVENGA P T , SHEIKH M A. On the Contribution of Primary Deformation Zone-generated Chip Temperature to Heat Partition in Machining [J]. International Journal of Advanced Manufacturing Technology, 2013, 68(1/4): 99-110.
[5]SCHMIDT A O, ROUBIK J R. Distribution of Heat Generated in Drilling [J]. Trans. ASME, 1949, 71(3): 245-252.
[6]SATO M , TAMURA N , TANAKA H. Temperature Variation in the Cutting Tool in End Milling [J]. Journal of Manufacturing Science & Engineering, 2011, 133(2): 379-399.
[7]BENO T, HULLING U. Measurement of Cutting Edge Temperature in Drilling [J]. Procedia CIRP, 2012, 3(1): 531-536.
[8]NASKAR A, CHATTOPADHYAY A K. Investigation on Flank Wear Mechanism of CVD and PVD Hard Coatings in High Speed Dry Turning of Low and High Carbon Steel[J]. Wear, 2018, 396/397: 98-106.
[9]ZHENG L J, WANG C Y, FU L Y, et al. Wear Mechanisms of Micro-drills During Dry High Speed Drilling of PCB[J]. Journal of Materials Processing Technology, 2012, 212(10): 1989-1997.
[10]MUSFIRAH A H, GHANI J A, CHEHARON C H. Tool Wear and Surface Integrity of Inconel 718 in Dry and Cryogenic Coolant at High Cutting Speed [J]. Wear, 2017, 376/377: 125-133.
[11]李安海, 赵军, 罗汉兵, 等. 高速干铣削钛合金时涂层硬质合金刀具磨损机理研究[J]. 摩擦学学报, 2012, 32(1): 40-46.
LI Anhai, ZHAO Jun, LUO Hanbing, et al. Wear Mechanisms of Coated Carbide Tools in High-speed Dry Milling of Titanium Alloy [J]. Tribology, 2012, 32(1): 40-46.
[12]张应, 曹华军, 朱利斌, 等. 齿轮高速干切滚刀寿命预估模型与优化方法[J]. 中国机械工程, 2017, 28(21): 2614-2620.
ZHANG Ying, CAO Huajun, ZHU Libin, et al. High-speed Dry Gear Hob Life Prediction Model and Optimization Method [J]. China Mechanical Engineering, 2017, 28(21): 2614-2620.
[13]陈永鹏, 曹华军, 杨潇. 高速干切滚齿工艺滚刀切削刃载荷分布特性研究[J]. 机械工程学报, 2017, 53(15): 181-187.
CHEN Yongpeng, CAO Huajun, YANG Xiao. Research on Load Distribution Characteristic on the Cutting Edge in High Speed Gear Hobbing Process [J]. Journal of Mechanical Engineering, 2017, 53(15): 181-187.
[14]YANG X, CAO H J, CHEN Y P, et al. An Analytical Model of Chip Heat-carrying Capacity for High-speed Dry Hobbing Based on 3D Chip Geometry[J]. International Journal of Precision Engineering & Manufacturing, 2017, 18(2): 245-256.
[15]SCHEY J A. Introduction to Manufacturing Processes[M]. 3rd ed. Boston: McGraw-Hill, 2000: 552-553.
[16]张洪潮, 孔露露, 李涛, 等. 切削比能模型的建立及参数影响分析[J]. 中国机械工程, 2015, 26(8): 1098-1104.
ZHANG Hongchao, KONG Lulu, LI Tao, et al. SCE Modeling and Influencing Trend Analysis of Cutting Parameters [J]. China Mechanical Engineering, 2015, 26(8): 1098-1104.
[17]YAN S J , ZHU D H , ZHUANG K J , et al. Modeling and Analysis of Coated Tool Temperature Variation in Dry Milling of Inconel 718 Turbine Blade Considering Flank Wear Effect[J]. Journal of Materials Processing Technology, 2014, 214(12): 2985-3001.
[18]KARPUSCHEWSKI B, KNOCHE H J, HIPKE M, et al. High Performance Gear Hobbing with Powder-metallurgical High-speed-steel [J]. Procedia CIRP, 2012, 1(1): 196-201.
[19]全燕鸣, 何振威. 车削碳钢中切削热的分配[J]. 中国机械工程, 2006, 17(20): 2155-2158.
QUAN Yanming, HE Zhenwei. Cutting Heat Distribution in Turning of Carbon Steel [J]. China Mechanical Engineering, 2006, 17(20): 2155-2158. |