[1]王煜, 闫柯, 张进华. 我国高性能滚动轴承基础研究进展[J]. 中国基础科学, 2015, 17(6):10-19.
WANG Yu, YAN Ke, ZHANG Jinhua. Progress of the 973 Project-basic Research on High Performance Rolling Bearing[J]. China Basic Science, 2015, 17(6):10-19.
[2]FERREIRA J L A, BALTHAZAR J C, ARAUJO A P N. An Investigation of Rail Bearing Reliability under Real Conditions of Use[J]. Engineering Failure Analysis, 2003, 10(6):745-758.
[3]卜炎.实用轴承技术手册[M].北京:机械工业出版社, 2004.
BU Yan. Practical Bearing Technical Manual[M]. Beijing:China Machine Press, 2004.
[4]ROMANOWICZ P J, SZYBINSKI B. Fatigue Life Assessment of Rolling Bearings Made from AISI 52100 Bearing Steel[J]. Materials, 2019, 12(3):371.
[5]CHI Yulun, LI Haolin, CHEN Xun. In-process Monitoring and Analysis of Bearing Outer Race Way Grinding Based on the Power Signal[J]. Proceedings of the Institution of Mechanical Engineers, Part B:Journal of Engineering Manufacture, 2017, 231(14):2622-2635.
[6]张宏友, 吴鸣宇. 滚动轴承套圈及滚子滚道超精研发展现状[J]. 机械工程与自动化, 2015(6):220-221.
ZHANG Hongyou, WU Mingyu. Development of Super-precision Finishing Technique for Ring and Roller of Roll Bearing[J]. Mechanical Engineering & Automation, 2015(6):220-221.
[7]NOVAK M, KASUGA H, OHMORI H. Comparison of Roughness and Profile between ELID and Ground Surfaces[J]. Key Engineering Materials, 2014, 581:378-383.
[8]YIN S H, OHMORI H, DAI Y T, et al. ELID Grinding Characteristics of Glass-ceramic Materials[J]. International Journal of Machine Tools and Manufacture, 2009, 49(3/4):333-338.
[9]NEMOTO A, OHMORI H, MURATA Y, et al. Ultraprecision ELID-Grinding of Aspheric WC Lens Mold for Plastic Injection Molding[J]. Key Engineering Materials, 2010, 447:155-158.
[10]OKADA Y, ABE N, HISAMORI N, et al. Verification of Implant Surface Modification by a Novel Processing Method[J]. Acta Medica Okayama, 2017, 71(1):49-57.
[11]尹韶辉, 曾宪良, 范玉峰, 等. ELID镜面磨削加工技术研究进展[J]. 中国机械工程, 2010, 21(6):750-755.
YIN Shaohui, ZENG Xianliang, FAN Yufeng, et al. Research Progresses of ELID Mirror Grinding Technology[J]. China Mechanical Engineering, 2010, 21(6):750-755.
[12]QIAN J, OHMORI H, LIN W M. Internal Mirror Grinding with a Metal/Metal-resin Bonded Abrasive Wheel[J]. International Journal of Machine Tools and Manufacture, 2001, 41(2):193-208.
[13]杨黎健, 任成祖, 靳新民. 轴承套圈内圆在线电解修整磨削试验[J]. 中国机械工程, 2011, 22(2):212-214.
YANG Lijian, REN Chengzu, JIN Xinmin. Internal Cylindrical ELID Grinding Experiment of Bearing Rings[J]. China Mechanical Engineering, 2011, 22(2):212-214.
[14]QIAN J, LI W, OHMORI H. Cylindrical Grinding of Bearing Steel with Electrolytic In-process Dressing[J]. Precision Engineering, 2000, 24(2):153-159.
[15]WU L M, REN C Z, ZHANG K F. ELID Groove Grinding of Ball-bearing Raceway and the Accuracy Durability of the Grinding Wheel[J]. International Journal of Advanced Manufacturing Technology, 2015, 79(9/12):1721-1731.
[16]李远波, 刘国跃, 郭钟宁, 等. 电化学与磨削复合加工技术研究现状[J]. 组合机床与自动化加工技术, 2011(2):5-9.
LI Yuanbo, LIU GUOyue, GUO Zhongning, et al. Research on Electrochemical and Grinding Hybrid Process Technology[J]. Modular Machine Tool and Automatic Manufacturing Technique, 2011(2):5-9.
[17]ZHU Denglin, ZENG Yubin, XU Zhengyang, et al. Precision Machining of Small Holes by the Hybrid Process of Electrochemical Removal and Grinding[J]. CIRP Annals:Manufacturing Technology, 2011, 60(1):247-250.
[18]PURI A, BANERJEE S. Multiple-response Optimisation of Electrochemical Grinding Characteristics through Response Surface Methodology[J]. International Journal of Advanced Manufacturing Technology, 2013, 64(5/8):715-725.
[19]周锦进, 阿达依, 庞桂兵, 等. 电化学光整加工对表面微观几何形貌的影响[J]. 中国机械工程, 2006, 17(13):1346-1349.
ZHOU Jinjin, A Dayi, PANG Guibing, et al. Influence of Electrochemical Finishing Process on Micro-topography of Surfaces[J]. China Mechanical Engineering, 2006, 17(13):1346-1349.
[20]徐文骥, 魏泽飞, 孙晶, 等. 轴承滚子电化学机械光整加工表面质量预测与加工参数选择[J]. 中国机械工程, 2012, 23(5):525-530.
XU Wenji, WEI Zefei, SUN Jing, et al. Surface Quality Prediction and Processing Parameters Determination on Electrochemical Mechanical Finishing of Bearing Roller[J]. China Mechanical Engineering, 2012, 23(5):525-530.
[21]庞桂兵, 徐文骥, 周锦进. 电化学机械精准光整加工技术研究[J]. 中国机械工程, 2016, 27(19):2589-2593.
PANG Guibing, XU Wenji, ZHOU Jinjin. Study on Electrochemical Mechanical Precision Finishing Technology[J]. China Mechanical Engineering, 2016, 27(19):2589-2593.
[22]关佳亮, 胡志远, 张妤, 等. 高精度轴承套圈超精密加工技术的现状与发展[J]. 工具技术, 2018, 52(5):3-7.
GUAN Jialiang, HU Zhiyuan, ZHANG Yu, et al. Present Situation and Development of Ultra-precision Machining Technology for High Precision Bearing[J]. Tool Engineering, 2018, 52(5):3-7.
[23]孙磊,董晨晨,吕冰海,等. 基于双电解作用的表面磨削设备[P].中国,CN203495765U, 2014-03-26.
SUN Lei, DONG Chenchen, LYU Binghai, et al. A Surface Grinding Equipment Based on Dual Electrolytic[P]. China, CN203495765U, 2014-03-26.
[24]ZHANG Kaifei, REN Chengzu, YANG Lijian, et al. Precision Grinding of Bearing Steel Based on Active Control of Oxide Layer State with Electrolytic Interval Dressing[J]. International Journal of Advanced Manufacturing Technology, 2013, 65:411-419.
[25]WANG Zhiqiang, REN Chengzu, CHEN Guang, et al. A Comparative Study on State of Oxide Layer in ELID Grinding with Tool-cathode and Workpiece-cathode[J]. International Journal of Advanced Manufacturing Technology, 2018, 94:1299-1307.
[26]GLOECKNER P, EBERT F J. Micro-sliding in High-speed Aircraft Engine Ball Bearings[J]. Tribology Transactions, 2010, 53(3):369-375.
[27]AFFATATO S,RUGGIERO A, MEROLA M, et al. Advanced Biomaterials in Hip Joint Arthroplasty. A Review on Polymer and Ceramics Composites as Alternative Bearings[J]. Composites, Part B:Engineering, 2015, 83:276-283.
[28]杨帆. 双自转研磨方式下球体的运动特性及其影响因素的研究[D]. 杭州:浙江工业大学, 2010.
YANG Fan. The Research of Kinematic Characteristics of Balls and Their Influence Factors on the Rotated Dual-plates Lapping Platform[D]. Hangzhou:Zhejiang University of Technology, 2010.
[29]KANG J, HADFIELD M. The Polishing Process of Advanced Ceramic Balls Using a Novel Eccentric Lapping Machine[J]. Proceedings of the Institution of Mechanical Engineers, Part B:Journal of Engineering Manufacture, 2005, 219(7):493-503.
[30]LEE R T, HWANG Y C, CHIOU Y C. Lapping of Ultra-precision Ball Surfaces. Part I. Concentric V-groove Lapping System[J]. International Journal of Machine Tools and Manufacture, 2006, 46(10):1146-1156.
[31]YUAN Julong, CHEN Lineng, ZHAO Ping, et al. Study on Sphere Shaping Mechanism of Ceramic Ball for Lapping Process[J]. Key Engineering Materials, 2004, 259/260:195-200.
[32]郁炜, 吕冰海, 李兴林, 等. 双自转研磨沟槽结构参数对球体研磨均匀性的影响分析[J]. 轴承, 2013(4):19-21.
YU Wei, LYU Binghai, LI Xinglin, et al. Analysis on Influence of Structural Parameters for Rotated Dual-plates Lapping Groove on Lapping Uniformity of Sphere[J]. Bearing, 2013(4):19-21.
[33]郁炜, 吕冰海, 姚蔚峰, 等. 基于ADAMS的球体双自转研磨方式下研磨盘转速优化研究[J]. 中国机械工程, 2013, 24(7):866-872.
YU Wei, LYU Binghai, YAO Weifeng, et al. Speed Optimization for Lapping Plates in RDP Lapping Mode Based on ADAMS[J]. China Mechanical Engineering, 2013, 24(7):866-872.
[34]ZHOU Fenfen, YUAN Julong, LYU Binghai, et al. Kinematics and Trajectory in Processing Precision Balls with Eccentric Plate and Variable-radius V-groove[J]. International Journal of Advanced Manufacturing Technology, 2016, 84:2167-2178.
[35]ZHOU L B, SHIINA T, QIU Z J, et al. Research on Chemo-mechanical Grinding of Large Size Quartz Glass Substrate[J]. Precision Engineering, 2009, 33(4):499-504.
[36]WU K, ZHOU L B, SHIMIZU J, et al. Study on the Potential of Chemo-mechanical-grinding (CMG) Process of Sapphire Wafer[J]. International Journal of Advanced Manufacturing Technology, 2017, 91(5/8):1539-1546.
[37]HASHIMOTO F, GALLEGO I, OLIVEIRA J F G, et al. Advances in Centerless Grinding Technology [J]. CIRP Annals:Manufacturing Technology, 2012, 61(2):747-770.
[38]蔡智杰. 双盘直槽滚子圆柱面研磨循环系统设计[D]. 天津:天津大学, 2017.
CAI Zhijie. Design of Circulatory System for Roller Cylindrical Surface Processing with Double-disc Straight Groove Lapping Process[D]. Tianjin:Tianjin University, 2017.
[39]YAO Weifeng, YUAN Julong, ZHOU Fengfeng, et al. Trajectory Analysis and Experiments of Both-sides Cylindrical Lapping in Eccentric Rotation[J]. International Journal of Advanced Manufacturing Technology, 2017, 88(9/12):2849-2859.
[40]李敏, 吕冰海, 袁巨龙, 等. 剪切增稠抛光的材料去除数学模型[J]. 机械工程学报, 2016, 52(7):142-151.
LI Min, LYU Binghai, YUAN Julong, et al. Material Removal Mathematics Model of Shear Thickening Polishing[J]. Journal of Mechanical Engineering, 2016, 52(7):142-151.
[41]LI Min, LYU Binghai, YUAN Julong, et al. Evolution and Equivalent Control Law of Surface Roughness in Shear-thickening Polishing[J]. International Journal of Machine Tools and Manufacture, 2016, 108:113-126.
[42]李敏, 袁巨龙, 吕冰海, 等. Si3N4陶瓷的剪切增稠抛光[J]. 机械工程学报, 2017, 53(9):193-200.
LI Min, YUAN Julong, LYU Binghai, et al. Shear-thickening Polishing of Si3N4 Ceramics[J]. Journal of Mechanical Engineering, 2017, 53(9):193-200. |