Journal of Guangdong University of Technology ›› 2023, Vol. 40 ›› Issue (06): 52-61.doi: 10.12052/gdutxb.230147

• Precision Manufacturing Technology and Equipment • Previous Articles     Next Articles

Design and Control of Constant Force Control Components Based on Disturbance Conversion Compensation

Jiang Chuan-xing, Yang Zhi-jun, Chen Xin, Bai You-dun   

  1. State Key Laboratory for Precision Electronics Manufacturing Technology and Equipment, Guangdong University of Technology, Guangzhou 510006, China
  • Received:2023-09-19 Online:2023-11-25 Published:2023-11-08

HTML

PDF (PC)

555

Abstract: Constant force control is significant for robot griding or polishing. Due to the influence of guide rail friction, the existing high precision force control employs air bearing and pneumatic control. Aiming at the problem that the precision of mechanical guideway force control system is affected by nonlinear friction, a design method is proposed that converts friction disturbance into elastic disturbance, which solves the problems of friction dead zone and static friction compensation. Specifically, the force control actuator is designed as a frame and working platform connected by a flexible hinge group. When the driving force is less than the friction force, the displacement is completely generated by the elastic deformation of the flexure hinge, eliminating the friction dead zone. The nonlinear friction disturbance is converted into the elastic deformation disturbance of the flexure hinge. Through the deformation amount and deformation rate of the flexure hinge, the elastic force and damping force are calculated for real-time compensation, which solves the problem of friction compensation. The experiment shows that the friction disturbance conversion design reduces the influence of friction, finally improves the force control accuracy to 0.08 N through measurement and compensation, which is 20~50 N times higher than the original, more than 10 times higher than the general air flotation accuracy, and maintains the advantages of fast response and low cost of the electronic control system.

Key words: disturbance transformation, constant force control, compensation, mechanism design

CLC Number: 

  • TH122
[1] MOHAMMAD A E K, HONG J, WANG D, et al. Synergistic integrated design of an electrochemical mechanical polishing end-effector for robotic polishing applications [J]. Robotics and Computer-Integrated Manufacturing, 2019, 55: 65-75.
[2] HONG J, MOHAMMAD A E K, WANG D. Improved design of the end-effector for macro-mini robotic polishing systems[C]// Proceedings of the 3rd International Conference on Mechatronics and Robotics Engineering. Paris: ACM, 2017: 36-41.
[3] MOHAMMAD A E K, HONG J, WANG D. Design of a force-controlled end-effector with low-inertia effect for robotic polishing using macro-mini robot approach [J]. Robotics and Computer-Integrated Manufacturing, 2018, 49: 54-65.
[4] LI J, GUAN Y, CHEN H, et al. A high-bandwidth end-effector with active force control for robotic polishing [J]. IEEE Access, 2020, 8: 169122-169135.
[5] CHEN F, ZHAO H, LI D, et al. Contact force control and vibration suppression in robotic polishing with a smart end effector [J]. Robotics and Computer-Integrated Manufacturing, 2019, 57: 391-403.
[6] MA Z, HONG G S, ANG M H, et al. Design and control of an end-effector module for industrial finishing applications[C]//2016 IEEE International Conference on Advanced Intelligent Mechatronics (AIM). Banff, AB: IEEE, 2016: 339-344.
[7] MA Z, SEE H H, HONG G S, et al. Control and modeling of an end-effector in a macro-mini manipulator system for industrial applications[C]//2017 IEEE International Conference on Advanced Intelligent Mechatronics (AIM). Munich: IEEE, 2017: 676-681.
[8] WEI Y, XU Q. Design of a new robot end-effector based on compliant constant-force mechanism[C]//2021 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). Prague, Czech Republic: IEEE, 2021: 7601-7606.
[9] WEI Y, XU Q. Design of a new passive end-effector based on constant-force mechanism for robotic polishing [J]. Robotics and Computer-Integrated Manufacturing, 2022, 74: 102278.
[10] ZHU R, YANG G, FANG Z, et al. Kinematic design of a 3-DOF force-controlled end-effector with flexure joints for robotic finishing applications[C]//2019 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM). Hong Kong: IEEE, 2019: 1473-1478.
[11] YANG G, ZHU R, FANG Z, et al. Kinematic design of a 2R1T robotic end-effector with flexure joints [J]. IEEE Access, 2020, 8: 57204-57213.
[12] ZHANG J, ZHAO L, LI L, et al. Design of passive constant-force end-effector for robotic polishing of optical reflective mirrors [J]. Chinese Journal of Mechanical Engineering, 2022, 35(1): 141.
[13] CHEN Y H, LAN C C. An adjustable constant-force mechanism for adaptive end-effector operations [J]. Journal of Mechanical Design, 2012, 134(3): 031005.
[14] ZHANG X, FU Z, WANG G. Design and development of a novel 3-DOF parallel robotic polishing end-effector[C]//2021 6th IEEE International Conference on Advanced Robotics and Mechatronics (ICARM). Chongqing: IEEE, 2021: 352-357.
[15] 赵亚平, 杨桂林, 杨巍, 等. 气电混合式机器人力控末端执行器研究[J]. 组合机床与自动化加工技术, 2016(12): 103-106.
ZHAO Y P, YANG G L, YANG W, et al. Research on a pneumoelectric robotic end-effector with force control [J]. Modular Machine Tool & Automatic Manufacturing Technique, 2016(12): 103-106.
[16] 刘立涛, 杨桂林, 柳丽, 等. 气电混合式力控末端执行器接触力控制研究[J]. 机械设计与研究, 2020, 36(5): 33-37.
LIU L T, YANG G L, LIU L, et al. Research on the contact force control of pneumatic-electric hybrid force-controlled end-effector[J], Machine Design and Research, 2020, 36(5): 33-37.
[17] WHITNEY D E. Historical perspective and state of the art in robot force control [J]. The International Journal of Robotics Research, 1987, 6(1): 3-14.
[18] 李正义. 机器人与环境间力/位置控制技术研究与应用[D]. 武汉: 华中科技大学, 2011.
[19] SCHUMACHER M, WOJTUSCH J, BECKERLE P, et al. An introductory review of active compliant control [J]. Robotics and Autonomous Systems, 2019, 119: 185-200.
[20] 葛吉民, 邓朝晖, 李尉, 等. 机器人磨抛力柔顺控制研究进展[J]. 中国机械工程, 2021, 32(18): 2217-2230.
GE J M, DENG Z H, LI W, el al. Research progresses of robot grinding and polishing force compliance controls [J]. China Mechanical Engineering, 2021, 32(18): 2217-2230.
[21] 甘亚辉, 段晋军, 戴先中. 非结构环境下的机器人自适应变阻抗力跟踪控制方法[J]. 控制与决策, 2019, 34(10): 2134-2142.
GAN Y H, DUAN J J, DAI X Z. Adaptive variable impedance control for robot force tracking in unstructured environment [J]. Control and Decision, 2019, 34(10): 2134-2142.
[22] LOPES A, ALMEIDA F. A force-impedance controlled industrial robot using an active robotic auxiliarydevice [J]. Robotics and Computer-Integrated Manufacturing, 2008, 24(3): 299-309.
[23] LEW J Y. Contact control of flexible micro/macro-manipulators[C]// Proceedings of International Conference on Robotics and Automation. Albuquerque, NM: IEEE, 1997: 2850-2855.
[24] BONE G M, ELBESTAWI M A. Active end effector control of a low precision robot in deburring [J]. Robotics and Computer-Integrated Manufacturing, 1991, 8(2): 87-96.
[25] TIAN Y, SHIRINZADEH B, ZHANG D. Closed-form compliance equations of filleted V-shaped flexure hinges for compliant mechanism design [J]. Precision Engineering, 2010, 34(3): 408-418.
[26] LI R, YANG Z, CHEN G, et al. Analytical solutions for nonlinear deflections of corner-fillet leaf-springs [J]. Mechanism and Machine Theory, 2021, 157: 104182.
[27] LI R, YANG Z, CAI B, et al. A compliant guiding mechanism utilizing orthogonally oriented flexures with enhanced stiffness in Degrees-of-Constraint [J]. Mechanism and Machine Theory, 2022, 167: 104555.
[28] 李瑞奇. 倒圆角弹片式柔性铰链非线性变形分析、优化与应用[D]. 广州: 广东工业大学, 2021.
[1] Zou Heng, Gao Jun-li, Zhang Shu-wen, Song Hai-tao. Design and Implementation of a Dropping Guidance Device for Go Robot [J]. Journal of Guangdong University of Technology, 2023, 40(01): 77-82,91.
[2] Wang Jiang-qi, Zhang Miao, Li Yue, Su Teng. An Asymmetric Topology of Three-phase Active Power Filter [J]. Journal of Guangdong University of Technology, 2023, 40(01): 100-106.
[3] Liang Shi-yong, Yu Zhao-qin, Huang Wen-bin, Xiao Cheng-long. A Research on EDM Drilling High Precision Blind Hole [J]. Journal of Guangdong University of Technology, 2020, 37(04): 75-78.
[4] ZHANG Miao, SU Xie-fei. Research on Proportional-Resonant Controller and Harmonic Compensation for Grid-Connected Inverter [J]. Journal of Guangdong University of Technology, 2016, 33(05): 59-64.
[5] TANG Xiong-Min, DU Fang-Zhou, CHEN Si-Zhe. Research on a New Implementation Method for Single-Phase Shunt Active Power Filter [J]. Journal of Guangdong University of Technology, 2016, 33(03): 11-18.
[6] Lu Ye,Peng Shi-guo. Robust Control of T-S Fuzzy Stochastic System with Time-Delay [J]. Journal of Guangdong University of Technology, 2013, 30(1): 68-72.
[7] LIAO Hui, WU Bai-Hai, XIAO Ti-Bing, LI Wei-Hua. Nonlinear Dynamic Analysis of Motion Compensation of Marine Drill Strings  [J]. Journal of Guangdong University of Technology, 2011, 28(1): 1-4.
[8] LI Xue-Wen, CAO Ping, LIU Jun, SUN Ke-Ping. The Research on Improved Control Strategy of STATCOM [J]. Journal of Guangdong University of Technology, 2010, 27(4): 92-95.
[9] LI Xiang, HU Yi-Hua, WANG Yin-Hai, FU Chu-Jun, WU Hao-Yi, KANG Feng-Wen, JU Gui-Fang, MOU Zhong-Fei. On the Synthesis of Nax Sr1-2x MoO4:Eux3+and Their Luminescent Properties [J]. Journal of Guangdong University of Technology, 2010, 27(4): 32-35.
[10] HUANG Ying-jie,CHEN Wei,DENG Ze-ming,WANG Qin-ruo,LI Jun,DU Yu-xiao. The Study of the Tension Control System about the Color Precoated Steel [J]. Journal of Guangdong University of Technology, 2006, 23(4): 45-49.
[11] YANG Jun. Speed Control System of D.C.Motor with Load Torque Compensation [J]. Journal of Guangdong University of Technology, 2006, 23(2): 58-62.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Copyright © 2017 Journal of Guangdong University of Technology
Add:729 East Dongfeng RD., Guangzhou PRC. Postcode: 510090
Tel:020-37626653,020-37626139,020-37626396
Email:xbzrb@gdut.edu.cn
Supported:Beijing Magtech