Sensor-Based Inspection of the Formation Accuracy in Ultra-Precision Grinding （UPG） of Aspheric Surface Considering the Chatter Vibration 被引量：2

Sensor-Based Inspection of the Formation Accuracy in Ultra-Precision Grinding （UPG） of Aspheric Surface Considering the Chatter Vibration

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摘要 This paper proposes an experimental approach for monitoring and inspection of the formation accuracy in ultra-precision grinding （UPG） with respect to the chatter vibration. Two factors related to the grinding progress, the grinding speed of grinding wheel and spindle, and the oil pressure of the hydrostatic bearing are taken into account to determining the accuracy. In the meantime, a mathematical model of the radius deviation caused by the micro vibration is also established and applied in the experiments. The results show that the accuracy is sensitive to the vibration and the forming accuracy is much improved with proper processing parameters. It is found that the accuracy of aspheric surface can be less than 4 μm when the grinding speed is 1400r/min and the wheel speed is 100 r/min with the oil pressure being 1.1 MPa. This paper proposes an experimental approach for monitoring and inspection of the formation accuracy in ultra-precision grinding （UPG） with respect to the chatter vibration. Two factors related to the grinding progress, the grinding speed of grinding wheel and spindle, and the oil pressure of the hydrostatic bearing are taken into account to determining the accuracy. In the meantime, a mathematical model of the radius deviation caused by the micro vibration is also established and applied in the experiments. The results show that the accuracy is sensitive to the vibration and the forming accuracy is much improved with proper processing parameters. It is found that the accuracy of aspheric surface can be less than 4 μm when the grinding speed is 1400r/min and the wheel speed is 100 r/min with the oil pressure being 1.1 MPa.

作者 Yao LEI Yue BAI Zhijun XU

机构地区 School of Mechanical Engineering and Automation Changchun Institute of Optics

出处《Photonic Sensors》 SCIE EI CAS CSCD 2018年第2期97-102,共6页 光子传感器（英文版）

关键词 Optical aspheric surface micro-vibrations ultra-precision grinding formation accuracy grindingspeed Optical aspheric surface micro-vibrations ultra-precision grinding formation accuracy grindingspeed

分类号 TP273.4 [自动化与计算机技术—检测技术与自动化装置] TB332 [自动化与计算机技术—控制科学与工程]

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1Zhengyi ZHANG,Chuntong LIU,Hongcai LI,Zhenxin HE,Xiaofeng ZHAO.Optical Fiber Grating Vibration Sensor for Vibration Monitoring of Hydraulic Pump[J].Photonic Sensors,2017,7(2):140-147. 被引量：1
2Huijuan WU,Ya QIAN,Wei ZHANG,Hanyu LI,Xin XIE.Intelligent Detection and Identification in Fiber-Optical Perimeter Intrusion Monitoring System Based on the FBG Sensor Network[J].Photonic Sensors,2015,5(4):365-375. 被引量：4
3张学忱,曹国华,聂风明,吴庆堂.光学非球面超精密磨削的微振动对成形精度影响研究[J].兵工学报,2012,33(9):1066-1069. 被引量：5
4Jinyu WANG,Long JIANG,Zengrong SUN,Binxin HU,Faxiang ZHANG,Guangdong SONG,Tongyu LIU,Junfeng QI,Longping ZHANG.Research on the Surface Subsidence Monitoring Technology Based on Fiber Bragg Grating Sensing[J].Photonic Sensors,2017,7(1):20-26. 被引量：7

二级参考文献9

1Huang H, Guo Y B. Research on aspheric machining system error compensation and experiment eliminate the error wave area [ J]. International Journal of Computer Applications Technology, 2007, 29(7) : 150 -154. 被引量：1
2Zhan Jian-ming, Yu Si-hai. Study on error compensation of machi- ning force in aspheric surfaces polishing by profile-adaptive hybrid movement-force control [ J ]. International Journal of Advanced Manufacturing Technology, 2011, 54: 879- 885. 被引量：1
3Sazedur Rahman M, Saleh T, Lim H S, et al. Development of an on-machine profile measurement system in ELID grinding for ma- chining aspheric surface with software compensation[ J ]. Interna- tional Journal of Machine Tools & Manufacture, 2008, 48 : 887 - 895. 被引量：1
4Li Y, Gracewski S M, Funkenbusch P D, et al. Analysis of chat- ter in contour grinding of optical materials[J]. International Jour- nal of Machine Tools & Manufacture, 2002,42 : 1095 - 1103. 被引量：1
5Usanov D A, Skripal A V. Quantum Electronics Measurement of micro- and nanovibrations and displacements using semiconductor laser autodynes[ J]. Quantum Electronics, 2011,41 ( 1 ) : 86 -94. 被引量：1
6吴剑锋,王文,陈子辰.激光三角法测量误差分析与精度提高研究[J].机电工程,2003,20(5):89-91. 被引量：84
7张翊,郭隐彪,庄司克雄.微小振动影响超精密非球面加工精度的研究[J].金刚石与磨料磨具工程,2003,23(3):17-20. 被引量：9
8杨福兴.大口径平面光学元件超精密加工技术的研究[J].光学技术,2004,30(1):27-29. 被引量：9
9杨小璠,郑琳,郭隐彪.超精密磨削加工微小振动模拟系统研究[J].组合机床与自动化加工技术,2004(6):1-2. 被引量：2

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1罗志会,华鹏,徐冰,汪叶梦,叶永.基于超弱光纤光栅阵列的地表位移监测方法[J].中国安全生产科学技术,2022,18(S01):18-24. 被引量：2
2李嘉全,程志峰.用于主动减振的振动信号实时高精度检测[J].电子测量与仪器学报,2013,27(12):1134-1140. 被引量：13
3郑喜贵,龚胜,尹韶辉,叶冰.磁控微粉砂轮固化工艺对砂轮磨削性能的影响[J].表面技术,2017,46(10):76-81. 被引量：1
4陈祖玎,董文博,钟红恩.电磁主动隔振电子学和控制系统设计[J].电子设计工程,2018,26(4):109-113. 被引量：1
5郭永兴,匡毅,熊丽,刘文龙,吴恒.不同封装方式的光纤光栅传感与温补特性[J].激光与光电子学进展,2018,55(11):93-100. 被引量：15
6李卢丹,白雪,胡耀升.光纤光栅传感器用于飞行试验应变测量的可行性研究[J].中国测试,2020,46(5):45-50. 被引量：11
7王蒙,孙志慧,张琳,王滨,李振强.基于FBG震动传感器的边境安防系统研究[J].光电子．激光,2020,31(7):708-712. 被引量：4
8张燕君,高海川,张龙图,刘强,付兴虎.毛细铜管封装的内嵌式镀金光纤布拉格光栅温度和应力传感器[J].光电工程,2021,48(3):56-66. 被引量：4
9彭期刚.基于Sagnac环的分布式光纤围栏智能预警安防系统[J].电力大数据,2021,24(5):86-92. 被引量：3
10李颖鑫,谢瑞欣,刘丽,徐航.基于复合式随机码雷达系统实现入侵监测[J].电子器件,2023,46(2):326-336. 被引量：1

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1李立,徐燕申,沈明,黄圣泉.M7475B型磨床工艺参数对加工稳定性影响的研究[J].磨床与磨削,1990(2):22-25. 被引量：1
2雷小宝,廖文和,张霖,戴宁,杨峰.磨牙牙冠的模型重构与CAM工艺[J].华南理工大学学报（自然科学版）,2010,38(5):116-121. 被引量：4
3董新峰,张为民,姜源.基于EMD复杂度与鉴别信息的磨削颤振预测[J].振动．测试与诊断,2012,32(4):602-607. 被引量：9
4张月星,李强.浅谈火炮身管加工工艺[J].装备制造技术,2014(2):241-242. 被引量：5
5罗彤,胡渝.自由空间光通信地面演示系统光束APT设计与实现[J].应用光学,2002,23(2):14-17. 被引量：12
6王利明,袁意林,邵毅敏,王盛军.二十辊轧机轧辊磨床砂轮动不平衡对磨削颤振的影响[J].工程科学学报,2015,37(S1):78-83. 被引量：4
7迟玉伦,李郝林.切入式外圆磨削接触刚度与固有频率研究[J].中国机械工程,2016,27(10):1294-1298. 被引量：12
8韩子瑶,胡文杰,谭建国.年轻患者磨牙残根牙冠延长术后桩核冠修复长期观察(附1例报告)[J].中国实用口腔科杂志,2018,11(10):578-582. 被引量：4
9王冬生,段有明,杨立洁,王桂梅,张华栋.新型陶瓷托辊专用磨床磨削颤振稳定性分析[J].机床与液压,2019,47(20):130-133. 被引量：3
10孙聪,姚云龙,修世超,俞志鹏.预应力条件下系统颤振对磨削工件表面形貌的影响研究[J].表面技术,2020,49(1):326-335. 被引量：3

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1Yao LEI,Xiaoming LI,Lizhong ZHANG.Experimental Study on PAT System for Long-Distance Laser Communications Between Fixed-Wing Aircrafts[J].Photonic Sensors,2019,9(2):170-178. 被引量：4
2朱子俊,朱祥龙,董志刚,康仁科,鲍岩.磨削加工颤振稳定性研究综述[J].机械工程学报,2023,59(21):15-33. 被引量：1

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1刘豪,杨祎,阴亚芳,张建磊,李思静.基于EKF的水下LD通信精对准控制算法[J].光子学报,2020,49(4):132-140. 被引量：4
2贺锋涛,韦鹏程,张建磊,杨祎,朱云周.水下无线光自动对准系统的设计与实现[J].激光杂志,2021,42(1):124-127. 被引量：3
3张敏,李勃,滕云杰,姜会林.潜望式激光通信终端的扰动抑制与动态跟踪方法[J].兵工学报,2020,41(12):2486-2494. 被引量：3
4Binbin Lv,Jun Zha,Kaichun Zeng,Hongtao Guo,Li Yu,Peng Zhang.Recent Progress on Aeroelasticity of High-Performance Morphing UAVs[J].Computer Modeling in Engineering & Sciences,2022(10):1-29.
5李干,鲍岩,王中旺,康仁科,董志刚.砂轮磨损检测技术研究:现状和展望[J].中国科学：技术科学,2024,54(7):1263-1287.

1Wang Jun.Rub of the Green[J].Beijing Review,2018,61(7):36-37.
2Xavier Beudaert,Asier Barrios,Kaan Erkorkmaz,Jokin Munoa.Limiting Factors for Active Suppression of Structural Chatter Vibrations Using Machine′s Drives[J].Transactions of Nanjing University of Aeronautics and Astronautics,2017,34(4):341-348. 被引量：1
3Zongyi Ma.Preface to the special issue： Friction stir welding and processing[J].Journal of Materials Science & Technology,2018,34(1).
4Wenlong Yan,Ningtao Quan,Yang Luo,Dunbo Yu,Zilong Wang,Guiyong Wu,Kun Zhang.Structure and hard magnetic properties of TbCu_7-type SmFe_(8.95-x)Ga_(0.26)Nb_x nitrides[J].Journal of Rare Earths,2018,36(2):165-169. 被引量：1
5林苔.爱没有理由[J].现代交际,2002,0(12):51-51.
6孟祥震.丰田驱动力控制装置的维修与保养(三)[J].汽车与驾驶维修（汽车版）,1998,0(10):34-35.
7杜青,郑加兴,吕巨智,文仁来,曾艳华,杨耀炯,王治红,张述宽,唐照磊,李石初,程伟东.利用SSR标记划分广西骨干玉米自交系的杂种优势群[J].玉米科学,2017,25(6):21-27. 被引量：9
8Zineb Squalli Houssaini,Imane Zaimi,Maroua Drissi,Mohammed Oumsis,Said El Alaoui Ouatik.Trade-off between accuracy, cost, and QoS using a beacon-on-demand strategy and Kalman filtering over a VANET[J].Digital Communications and Networks,2018,4(1):13-26.
9魏斌.寺庙的禁忌[J].现代交际,2003,0(10):9-9.
10金宝光.上海别克轮胎压力监视器故障及检修[J].汽车与驾驶维修（汽车版）,2000,0(6):63-63.

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