数控机床高性能传动部件控制技术的研究进展

摘要/Abstract

摘要：

介绍了高档数控机床工作台、刀具伺服等关键传动部件控制技术的研究进展，主要包括滚珠丝杠的工作行为建模与控制方法、电机直接驱动关键技术、宏微结合驱动与传动新技术以及智能刀具伺服技术等内容。针对以上典型传动控制技术，分别回顾了其发展历程，总结了近年来的主要研究成果，归纳出各自的基本设计思想，讨论了四种传动控制技术的发展趋势以及研究中尚待解决的问题。

关键词:

数控机床, 精密, 传动控制, 研究现状

Abstract:

Numerical control work tables and tool servos are the key transmission components of advanced NC machines. Current status of research on the modeling and control of NC work tables and tool servos were reviewed herein, which included dynamic behavior analysis method and control design method of ball-screw driven servomechanism, advanced controller design techniques for direct drive, novel techniques in coarse/fine dual stage drive and transmission design and intelligent tool servos design. For each field, the development history was reviewed, main contributions were surveyed, basic design principles were summarized, and the problems which required further investigation were discussed, respectively. 

Key words: numerical control(NC) machine; precision, transmission control;current status

中图分类号:

TG659

范大鹏, 范世珣, 鲁亚飞, 张连超.

数控机床高性能传动部件控制技术的研究进展

[J]. 中国机械工程, 2011, 22(11): 1378-1385.

FAN Da-Feng, FAN Shi-Xun, LU E-Fei, ZHANG Lian-Chao.

Current Status of Control Research on NC Machine Transmission Components

[J]. China Mechanical Engineering, 2011, 22(11): 1378-1385.

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链接本文: http://www.cmemo.org.cn/CN/

http://www.cmemo.org.cn/CN/Y2011/V22/I11/1378

参考文献

[1]Chen J S, Huang Y K, Cheng C C. Mechanical Model and Contouring Analysis of High- speed Ball-screw Drive Systems with Compliance Effect[J]. International Journal of Advanced Manufac- turing Technology, 2004, 24:241-250.
[2]Kim M S, Chung S C. Integrated Design Methodol- ogy of Ball- screw Driven Servomechanisms with Discrete Controllers, Part I: Modelling and Per- formance Analysis[J].Mechatronics, 2006, 16: 491-502.
[3]Poignet P, Gautier M, Khalil W, et al. Modeling, Simulation and Control of High Speed Machine Tools Using Robotics Formalism[J].Mechatronies, 2002, 12:461-487.
[4]Yang Tachong, Lin C S. Identifying the Stiffness and Damping Parameters of a Linear Servomecha- nism[J]. Mechanics Based Design of Structures and Machines, 2004, 32:283-304.
[5]van Brussel H, Sas P, Nemeth I, et al. Towards a Mechatronic Compiler[J].IEEE-ASME Transac- tions on Mechatronics, 2001, 6 : 90-105.
[6]Schafers E, Denk J, Hamann J. Mechatronic Modeling and Analysis of Machine Tools[C]//Proceedings of the 2nd International Conference on High Performance Cutting. Vancouver: CIRP-HPC, 2006:456-461.
[7]Pislaru C, Ford D G, Holroyd G. Hybrid Modelling and Simulation of a Computer Numerical Control Machine Tool Feed Drive[J].Journal of Systems and Control Engineering, 2004, 218: 111- 120.
[8]Varanasi K K, Nayfeh S A. The Dynamics of Lead-screw Drives: Low-order Modeling and Experiments [J].Journal of Dynamic Systems Measurement and Control- Transactions of the ASME, 2004, 126:388-396.
[9]Whalley R, Ebrahimi M, Abdul-Ameer A A. Machine Tool Axis Dynamics[J]. Journal of Mechanical Engineering Science, 2006, 220:403-419.
[10]Allotta B, Angioli F, Rinchi M. Constraints Identification for Vibration Control of Time-varying Boundary Conditions Systems[C]//Proceedings of the International Conference on Advanced Intelli- gent Meehatronics. Como, Italy:IEEE/ASME, 2001: 606-611.
[11]Erkorkmaz K, Kamalzadeh A. High Bandwidth Control of Ball Screw Drives[J]. CIRP Annals- Manufacturing Technology, 2006, 55:393-398.
[12]Holroyd G, Pislaru C, Ford D G. Modelling the Dynamic Behaviour of a Ball-screw System Tak- ing into Account the Changing Position of the Ball-screw Nut[C]//Proceedings of 6th Interna- tional Conference LAMDAMAP. Huddersfield, UK, 2003:337-348.
[13]Zaeh M F, Oertli T. Finite Element Modelling of Ball Screw Feed Drive Systems[J]. CIRP Annals-Manu- faeturing Technology, 2004, 53:289-292.
[14]Pritschow G. A Comparison of Linear and Con- ventional Electromechanical Drives[J]. Annals of the CIRP, 1998, 47:541-547.
[15]Jones S D, Ulsoy A G. An Approach to Control Input Shaping with Application to Coordinate Measuring Machines[J]. Journal of Dynamic Sys- tems Measurement and Control-Transactions of the ASME, 1999, 121:242-247.
[16]Zhou Yong, Peng Fangyu, Chen Jihong. Torsion Vibration Analysis of Lead- screw Feed Dreves with Changeable Table Position and Work-piece Mass[C]//Proceedings of IEEE International Con- ference on Mechatronics and Automation. Harbin, 2007:2194-2199.
[17]Smith A D. Wide Bandwidty Control of High- Speed Milling Machine Feed Drives[D], Oeala: Univ. of Florida, 1999.
[18]Kamalzadeh A, Erkorkmaz K. Compensation of Axial Vibrations in Ball Screw Drives[J].CIRP Annals- Manufacturing Technology, 2007, 56:373-378.
[19]Zhou Yong, Peng Fangyu, Chen Jihong. Adaptive Notch Filter Control for the Torsion Vibration in Lead-screw Feed Dreves System Based on Neural Network[C]//Proceedings of International Confer- ence on Intelligent Robotics and Applications. Wuhan, 2008:803-812.
[20]Kamalzadeh A, Erkorkmaz K. Accurate Tracking Controller Design for High-speed Drives[J]. International Journal of Machine Tools & Manufac- ture, 2007, 47:1393-1400.
[21]Chen Y, Tlusty J. Effect of Low- Friction Guid- ways and Lead-screw Flexibility on Dynamics of High-speed Machines[J].Annals of the CIRP, 1995, 44:353-356.
[22]Lira H, Seo J W, Choi C H. Torsional Displacement Compensation in Position Control for Machining Centers[J].Control Engineering Practice, 2001, 9:79- 87.
[23]Lim H, Seo J W, Choi C H. Position Control of XY Table in CNC Machining Center with an Iner- tia Identification using ROELO[C]//IEE Proceed- ings on Electric Power Applications. Chicago,2000, 151:116-120.
[24]Erkorkmaz K. Optimal Trajectory Generation and Precision Tracking Control for Multiaxis Machines[D]. Vancouver: Univ. of British Columbia, 2003.
[25]Symens W, van Brussel H, Sewvers J. Gain- sched uling Control of Machine Tools with Varying Struc rural Dynamics[J]. Annals of the CIRP, 2004, 53: 321-324.
[26]van BrusseI H,van den Braembussche P. Robust Control of Feed Drives with Linear Motor[J].Annals of the CIRP, 1998, 47:325-328.
[27]Alter D M, Tsao T C. Dynamic Stiffness Enhance ment of Direct Linear Motor Feed Drives for Machi ning[C]//Proceedings of the American Control Con ference. Baltimore, MD, 1994:3303-3307.
[28]Shieh N C, Tung P C. Robust Position Control of a Transportation Carriage Directly Driven by a Linear Brushless DC Motor[J]. Journal of Systems and Con trol Engineering, 2001, 215:611-624.
[29]Ahintas Y, Okwudire C E. Dynamic Stiffness Enhancement of Direct- driven Machine Tools Using Sliding Mode Control with Disturbance Recovery[J]. CIRP Annals - Manufacturing Technology, 2009, 58:335-338.
[30]van den Braembussche P, Swevers J, van Brussel H, et al. Design and Experimental Validation of Robust Controllers for Machine Tool Drives with Linear Motor[J].Mechatronics, 2001, 11:545-562.
[31]Shieh N C, Tung P C. Robust Position Regulation Control of a Transportation Carriage Directly Driven by Linear Brushless DC Motor [J]. Electric Power Components and Systems, 2002, 30 : 661-677.
[32]Choi C T, Tsao T C. Control of Linear Motor Machine Tool Feed Drives for End Milling: Robust MI- MO Approach[J]. Mechatronics, 2005, 15: 1207- 1224.
[33]Egami T, Tsuchiya T. Disturbance Suppression Control with Preview Action of Linear DC Brushless Motor[J]. IEEE Transactions on Industrial Electronics,1995, 42:494-500.
[34]Alter D M, Tsao T C. Control of Linear Motors for Machine Tool Feed Drives: Design and Implementation of H- infinity Optimal Feedback Control[J]. Journal of Dynamic Systems Measurement and Control-Transactions of the ASME, 1996, 118:649- 656.
[35]Choi C, Tsao T C, Matsubara A. Control of Linear Motor Machine Tool Feed Drives for End Milling: Robust MIMO Approach [ J ]. KSME International Journal, 1999, 13:727-737.
[36]Chung S K,Lee J H,Cho J S,et al. Robust Speed Control of Brushless Direct- drive Motor Using Integral Variable-structure Control[J].IEE Proceedings- Electric Power Applications, 1995, 142 : 361-370.
[37]Wang Jian, van Brussel H. Robust Perfect Tracking Control with Discrete Sliding Mode Controller[J]. Journal of Dynamic Systems Measurement and Control-Transaetions of the ASME, 2003, 125:27-32.
[38]Jamaludin Z, van Brussel H, Pipeleersa G, et al. Accurate Motion Control of xy High- speed Linear Drives Using Friction Model Feedforward and Cutting Forces Estimation[J]. CIRP Annals -Manufacturing Technology, 2008, 57:403-406.
[39]Denkenaa B, Toumlnshoffa H K, Lib X, et at. Anal- ysis and Control/Monitoring of the Direct Linear Drive in End Milling[J].International Journal of Pro- duction Research, 2004, 42 : 5149-5166.
[40]Yao Bin, Xu Li. Adaptive Robust Motion Control of Linear Motors for Precision Manufacturing [J]. Mechatronics, 2002, 12:595-616.
[41]Hollis J M. A Six- degree- of- freedom Test System for the Study of Joint Mechanics and Ligament Forces [J]. Journal of Biomechanical Engineering - Transactions of the ASME, 1995, 117 : 383-389.
[42]Xu Li, Yao Bin. Adaptive Robust Precision Motion Control of Linear Motors with Negligible Electrical Dynamics : Theory and Experiments [J]. IEEE - ASME Transactions on Mecbatronics, 2001, 6:444- 452.
[43]Xu Li, Yao Bin. Output Feedback Adaptive Robust Precision Motion Control of Linear Motors[J]. Automatica, 2001, 37 :1029-1039.
[44]Sharon A, Hogan N, Hardt D E. High Bandwidth Force Regulation and Inertia Reduction Using a Macro/Micro Manipulator System [C]//Proceedings of 1988 IEEE Int. Conf. on Robot. and Auto: Philadelphia, PA, USA, 1988:129-132.
[45]Sharon A, Hogana N, Hardt D E. The Macro Micro Manipulator- an Improved Architecture for Robot Control[J]. Robotics and Computer - integrated Manufacturing, 1993, 10:209-222.
[46]Khatib O. Inertial Properties in Robotic Manipulation-an Object- level Framework[J].International Journal of Robotics Research, 1995, 14 : 19-36.
[47]Saleudean S, An C. On the Control of Redundant Coarse- fine Manipulators[C]//Proceedings of 1989 IEEE Int. Conf. on Robot. and Auto: Scottsdale, USA, 1989 : 1834-1840.
[48]Lee C W, Kim S W. An Utraprecision Stage for Alignment of Wafers in Advanced Microlithography[J]. Precision Engineering, 1997, 21 : 113-122.
[49]Kwon S J, Chung W K, Youm Y. On the Coarse/ Fine Dual Stage Manipulators with Robust Perturbation Compensator[C]//Proc. of 2000 IEEE Int. Conf. on Robot. and Auto.. Seoul:ICRA, 2001: 121-126.
[50]Kwon S J, Chung W K, Youm Y. Robust and Time-optimal Control Strategy for Coarse/Fine Dual Stage Manipulators[C]//Proc. of 2000 IEEE Int. Conf. on Robot. and Auto.. San Francisco: ICRA, 2000 : 4051-4056.
[51]Yoshikawa T, Harada K, Matsumoto A. Hybrid Position/Force Control of Flexible-macro/Rigid- micro Manipulator Systems [J]. IEEE Transactions on Robotics and Automation, 1996, 12:633-640.
[52]Li Y, Horowitz R. Track Following Controller Design of MEMS Based Dualstage Servos in Magnetic Hard Disk Drives[C]//Proc. of 2000 IEEE Int. Conf. on Robot. and Auto.. San Francisco: ICRA, 2000:953-938.
[53]Hernandez D, Park S S, Horowitz R, et al. Dual Stage Track Following Servo Design for Hard Disk Drives[C]//Proc. of 1999 American Contr. Conf.. San Diego, USA, 1999: 4116-4121.
[54]Fan Longsheng, Ottesen H H, Reiley T C, et al. Magnetic Recording Head Positioning at Very High Track Densities Using a Microactuator-Based, 2- Stage Servo System[J]. IEEE Transactions on Indus- trial Electronics, 1995, 42 : 222-233.
[55]Staroselsky S, Stelson K A. Two- stage Actuation for Improved Accuracy of Contouring[C]//Proc. of 1988 American Contr. Conf.. Atlanta, USA, 1988: 127-132.
[56]Patterson S R, Magrab E B, Design and Testing of a Fast Tool Servo for Diamond Turning [J].Precision Engineering -Journal o[ the American Society for Precision Engineering, 1985, 7 :123-128.
[57]Kwon S, Cbeong J. Robust Minimum-time Control with Coarse/Fine Dual- stage Mechanism[J].Journal of Mechanical Science and Technology, 2006, 20 : 1834-1847.
[58]Yen Y J. Track- following Controller-design for a Compound Disk Drive Actuator[J]. Journal of Dy- namic Systems Measurement and Control- Transactions of the ASME, 1990, 112:391-402.
[59]Schroeck S J, Messner W C. On Controller Desing for Linear Time Invariant Dual Input Single Output Sytems[C]//Proc. of 1999 American Contr. Conf.. San Diego, USA, 1999:4121-4126.
[60]Kim E J. Ultra- precision Machining Using Fast Tool Servo and On-machine Form Measurement of Large Aspheric Mirrors[J].Journal of Korean Society of Precision Engineering Applications of Artificial Intelligence, 2000, 17:129-134.
[61]Kim H S. Diamond Turning of Large Off-axis As- pheric Mirrors Using a Fast Tool Servo with On- machine Measurement[J].Journal of Materials Processing Technology, 2004, 146:349-355.
[62]Dow T A. Application of a Fast Tool Servo for Diamond Turning of Nonrotationally Symmetrical Surfaces[J]. Precision Engineering-Journal of the American Society for Precision Engineering, 1991, 13: 243-250.
[63]Kim H S, Kim E J. Feed-forward Control of Fast Tool Servo for Real-time Correction of Spindle Error in Diamond Turning of Flat Surfaces[J]. International Journal of Machine Tools & Manufacture, 2003, 43: 1177-1183.
[64]Zimmergren R. Acticut Award Winning Technology Changing the World of Metal Cutting[R/DK]. Falkenberg, Sweden: Acticut International, 2008.
[65]Zhu W H. A Fast Tool Servo Design for Precision Turning of Shafts on Conventional CNC Lathes[J]. International Journal of Machine Tools & Manufacture, 2001, 41:953-965.
[66]Rakuff S, Cuttino J F. Design and Testing of a Long-range, Precision Fast Tool Servo System for Diamond Turning [J]. Precision Engineering- Journal of the International Societies for Precision Engineering and Nanotechnology, 2009, 33 : 18-25.
[67]Lu Xiaodong, Trumper D L. Ultra Fast Tool Servos for Diamond Turning [J].Annals of CIRP, 2005, 54 : 383-388.
[68]Lu Xiaodong, Trumper D L. Spindle Rotary Position Estimation for Fast Tool Servo Trajectory Generation [J].International Journal of Machine Tools & Manufacture, 2007, 47:1362-1367.