[1]付鹏强,苗宇航,王义文,等.航空领域机器人自动钻孔研究进展及关键技术综述[J].智能系统学报,2022,17(5):874-885.[doi:10.11992/tis.202106049]
 FU Pengqiang,MIAO Yuhang,WANG Yiwen,et al.A review of research progress and key technologies of robotic drilling in aviation[J].CAAI Transactions on Intelligent Systems,2022,17(5):874-885.[doi:10.11992/tis.202106049]
点击复制

航空领域机器人自动钻孔研究进展及关键技术综述

《智能系统学报》[ISSN 1673-4785/CN 23-1538/TP] 卷: 17 期数: 2022年第5期 页码: 874-885 栏目: 综述 出版日期: 2022-09-05
Title:
A review of research progress and key technologies of robotic drilling in aviation
作者:
付鹏强1,2, 苗宇航1,2, 王义文1,2, 姜晓灿1,2, 许成阳3, 刘立佳2,4, 周丽杰1,2
1. 哈尔滨理工大学 机械动力工程学院,黑龙江 哈尔滨 150080;
2. 哈尔滨理工大学 先进制造智能化技术教育部重点实验室,黑龙江 哈尔滨 150080;
3. 沈阳航空航天大学 航空宇航学院,辽宁 沈阳 110136;
4. 哈尔滨理工大学 自动化学院,黑龙江 哈尔滨 150080
Author(s):
FU Pengqiang1,2, MIAO Yuhang1,2, WANG Yiwen1,2, JIANG Xiaocan1,2, XU Chengyang3, LIU Lijia2,4, ZHOU Lijie1,2
1. School of Mechanical and Power Engineering, Harbin University of Science and Technology, Harbin 150080, China;
2. Key Laboratory of Advanced Manufacturing and Intelligent Technology, Ministry of Education, Harbin University of Science and Technology, Harbin 150080, China;
3. College of Aerospace Engineering, Shenyang Aerospace University, Shenyang 110136, China;
4. School of Automation, Harbin University of Science and Technology, Harbin 150080, China
关键词:
离线编程终端执行器系统误差补偿自动钻孔系统机器人钻孔路径规划冗余度求解压脚压紧力反馈法向监测
Keywords:
offline programmingend effectorsystem error compensationautomatic drilling systemrobotdrilling path planningredundancy solutionpresser-foot device pressure-force feedbacknormal monitoring
分类号:
TP242.3; V261.2
DOI:
10.11992/tis.202106049
文献标志码:
2022-05-13
摘要:
为促进航空航天领域机器人自动钻孔技术的研究,本文介绍了国内外在该领域的研究进展,概述与总结了机器人钻孔离线编程、终端执行器、系统误差补偿等关键技术所包涵的核心思想及算法,梳理了研究中存在的问题和可能的解决方案,探讨了各关键技术对机器人自动钻孔系统产生的影响,最后在总结研究成果与分析的基础上对各关键技术的发展方向做出了展望。
Abstract:
This paper introduces the research progress of this theme at home and abroad, summarizes the core ideas and algorithms of offline programming, end effector, system error compensation, and other key technologies in robotic drilling technology, and combs through the existing problems and possible solutions in previous researches to promote the research on robotic drilling technology in the field of aerospace. Also, the paper discusses the impact of each key technology on the robotic drilling system and gives corresponding prospects on the basis of summarizing and analyzing research results.
参考文献/References:
[1] FROMMKNECHT A, KUEHNLE J, EFFENBERGER I, et al. Multi-sensor measurement system for robotic drilling[J]. Robotics and computer-integrated manufacturing, 2017, 47: 4–10.
[2] CIRILLO P, MARINO A, NATALE C, et al. A low-cost and flexible solution for one-shot cooperative robotic drilling of aeronautic stack materials[J]. IFAC-PapersOnLine, 2017, 50(1): 4602–4609.
[3] GARNIER S, SUBRIN K, WAIYAGAN K. Modelling of robotic drilling[J]. Procedia cirp, 2017, 58: 416–421.
[4] KLIMCHIK A, AMBIEHL A, GARNIER S, et al. Experimental study of robotic-based machining[J]. IFAC-PapersOnLine, 2016, 49(12): 174–179.
[5] DEVLIEG R. Expanding the use of robotics in airframe assembly via accurate robot technology[J]. SAE international journal of aerospace, 2010, 3(1): 198–203.
[6] DEVLIEG R, SITTON K, FEIKERT E, et al. Once (one-sided cell end effector) robotic drilling system[EB/OL].(2002?09?30)[2020?02?02].https://doi.org/10.4271/2002-01-2626.
[7] DEVLIEG R, FEIKERT E. One-up assembly with robots[EB/OL].(2008?09?16)[2020?12?12].https://doi.org/10.4271/2008-01-2297.
[8] DEVLIEG R. High-accuracy robotic drilling/milling of 737 inboard flaps[J]. SAE international journal of aerospace, 2011, 4(2): 1373–1379.
[9] BARTON E, WOLF R. Dramatic automatic fastening system with single robot positioner [EB/OL].(2017?09?19)[2021?10?12].?https://doi.org/10.4271/2017-01-2078.
[10] WHINNEM E, LIPCZYNSKI G, ERIKSSON I. Development of orbital drilling for the boeing 787[J]. SAE international journal of aerospace, 2008, 1(1): 811–816.
[11] LOGEMANN T. Mobile robot assembly cell (RACe) for drilling and fastening[EB/OL].(2016?09?19)[2021?11?02].https://doi.org/ 10.4271/ 2016-01-2078.
[12] MUELLER-HUMMEL P, Meiners C. New concept on drills up to 5/8″ (16mm) for one shot IT8 robot application[EB/OL].(2012?09?10)[2021?05?21]. https://doi.org/10.4271/2012-01-1865.
[13] WAURZYNIAK P. Aerospace automation stretches beyond drilling and filling[J]. Manufacturing engineering, 2015, 154(04): 73–86.
[14] EVERHART T. Neighboring mobile robot cell with drilling and fastening internation [EB/OL]. [2017–01–20]. http://doi:10.4271/2017–01–2094.
[15] M?LLER C, SCHMIDT H C, KOCH P, et al. Machining of large scaled CFRP-Parts with mobile CNC-based robotic system in aerospace industry[J]. Procedia manufacturing, 2017, 14: 17–29.
[16] VON DRIGALSKI F, HAFI L E, ELJURI P M U, et al. Vibration-reducing end effector for automation of drilling tasks in aircraft manufacturing[J]. IEEE robotics and automation letters, 2017, 2(4): 2316–2321.
[17] NEUMANN K E. True mobile/portable drilling and machining, a paradigm shift in manufacturing[C]//SAE Technical Paper Series. 400 Commonwealth Drive, Warrendale, SAE International, 2017: 10.4271/2017-01-2084.
[18] ZHAN Qiang, LIU Zengbo, CAI Yao. A back-stepping based trajectory tracking controller for a non-chained nonholonomic spherical robot[J]. Chinese journal of aeronautics, 2008, 21(5): 472–480.
[19] NGUYEN H N, ZHOU Jian, KANG H J, et al. Robot geometric parameter identification with extended Kalman filtering algorithm[M]//Communications in Computer and Information Science. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013: 165?170.
[20] NGUYEN H N, ZHOU Jian, KANG H J. A calibration method for enhancing robot accuracy through integration of an extended Kalman filter algorithm and an artificial neural network[J]. Neurocomputing, 2015, 151: 996–1005.
[21] WANG Wei, TIAN Wei, LIAO Wenhe, et al. Identifying Chinese herbal medicine by image with three deep CNNs[C]//CCEAI 2021: Proceedings of the 5th International Conference on Control Engineering and Artificial Intelligence. New York: ACM, 2021: 1?8.
[22] LI M, TIAN W, HU J, et al. Study on shear behavior of riveted lap joints of aircraft fuselage with different hole diameters and squeeze forces[J]. Engineering Failure Analysis, 2021, 127: 105499.
[23] LIU Hua, ZHU Weidong, KE Yinglin. Pose alignment of aircraft structures with distance sensors and CCD cameras[J]. Robotics and computer-integrated manufacturing, 2017, 48: 30–38.
[24] LIU Hua, ZHU Weidong, DONG Huiyue, et al. A helical milling and oval countersinking end-effector for aircraft assembly[J]. Mechatronics, 2017, 46: 101–114.
[25] LIU hua, ZHU weidong, DONG huiyue, et al. An adaptive ball-head positioning visual servoing method for aircraft digital assembly[J]. Assembly automation, 2019, 39(2): 287–296.
[26] MARTíNEZ R, CASTILLO O, AGUILAR L T. Optimization of interval type-2 fuzzy logic controllers for a perturbed autonomous wheeled mobile robot using genetic algorithms[J]. Information sciences, 2009, 179(13): 2158–2174.
[27] SAMADI M, OTHMAN M F. Global path planning for autonomous mobile robot using genetic algorithm[C]//2013 International Conference on Signal-Image Technology & Internet-Based Systems. Kyoto, Japan. IEEE, 2013: 726?730.
[28] TSAI C C, HUANG H C, CHAN Chengkai. Parallel elite genetic algorithm and its application to global path planning for autonomous robot navigation[J]. IEEE transactions on industrial electronics, 2011, 58(10): 4813–4821.
[29] THARWAT A, ELHOSENY M, HASSANIEN A E, et al. Intelligent Bézier curve-based path planning model using Chaotic Particle Swarm Optimization algorithm[J]. Cluster computing, 2019, 22(2): 4745–4766.
[30] XIAO Hong, LI Yuan, ZHANG Kaifu, et al. Multi-objective optimization method for automatic drilling and riveting sequence planning[J]. Chinese journal of aeronautics, 2010, 23(6): 734–742.
[31] LIU Jianhua, YANG Jianguo, LIU Huaping, et al. An improved ant colony algorithm for robot path planning[J]. Soft computing, 2017, 21(19): 5829–5839.
[32] LIU Yanmei, CHEN Zhen, WANG Xin, et al. Research on adaptive ant colony algorithm in robot hole making path planning[J]. International journal of control and automation, 2017, 10(5): 189–198.
[33] TIAN Wei, ZHOU Weixue, ZHOU Wei, et al. Auto-normalization algorithm for robotic precision drilling system in aircraft component assembly[J]. Chinese journal of aeronautics, 2013, 26(2): 495–500.
[34] ERKORKMAZ K, ALZAYDI A, ELFIZY A, et al. Time-optimal trajectory generation for 5-axis on-the-fly laser drilling[J]. CIRP annals, 2011, 60(1): 411–414.
[35] HUO Liguo, BARON L. The self-adaptation of weights for joint-limits and singularity avoidances of functionally redundant robotic-task[J]. Robotics and computer-integrated manufacturing, 2011, 27(2): 367–376.
[36] ZARGARBASHI S H H, KHAN W, ANGELES J. Posture optimization in robot-assisted machining operations[J]. Mechanism and machine theory, 2012, 51: 74–86.
[37] LéGER J, ANGELES J. Off-line programming of six-axis robots for optimum five-dimensional tasks[J]. Mechanism and machine theory, 2016, 100: 155–169.
[38] LA H M, LIM R S, BASILY B B, et al. Mechatronic systems design for an autonomous robotic system for high-efficiency bridge deck inspection and evaluation[J]. IEEE/ASME transactions on mechatronics, 2013, 18(6): 1655–1664.
[39] JIAO Jiachen, TIAN Wei, LIAO Wenhe, et al. Processing configuration off-line optimization for functionally redundant robotic drilling tasks[J]. Robotics and autonomous systems, 2018, 110: 112–123.
[40] LIANG Jie, BI Shusheng. Design and experimental study of an end effector for robotic drilling[J]. The international journal of advanced manufacturing technology, 2010, 50(1/2/3/4): 399–407.
[41] HEISEL U, PFEIFROTH T. Influence of point angle on drill hole quality and machining forces when drilling CFRP[J]. Procedia cirp, 2012, 1: 471–476.
[42] NORGIA M, MELCHIONNI D, MAGNANI A, et al. High-speed self-mixing laser distance sensor[J]. AIP conference proceedings, 2014, 1600(1): 422–425.
[43] LAZARO GALILEA J L, LAVEST J M, LUNA VAZQUEZ C A, et al. Calibration of a high-accuracy 3-D coordinate measurement sensor based on laser beam and CMOS camera[J]. IEEE transactions on instrumentation and measurement, 2009, 58(9): 3341–3346.
[44] RAO Gang, WANG Guolei, YANG Xiangdong, et al. Normal direction measurement and optimization with a dense three-dimensional point cloud in robotic drilling[J]. IEEE/ASME transactions on mechatronics, 2018, 23(3): 986–996.
[45] GAO Yuhao, WU Dan, DONG Yunfei, et al. The method of aiming towards the normal direction for robotic drilling[J]. International journal of precision engineering and manufacturing, 2017, 18(6): 787–794.
[46] GONG M, YUAN P, WANG T, et al. Intelligent verticality-adjustment method of end-effector in aeronautical drilling robot[J]. Bjing Hangkong Hangtian Daxue Xuebao/Journal of Bjing University of Aeronautics and Astronautics, 2012, 38(10): 1400–1404.
[47] YUAN Peijiang, WANG Qishen, SHI Zhenyun, et al. A micro-adjusting attitude mechanism for autonomous drilling robot end-effector[J]. Science China information sciences, 2014, 57(12): 1–12.
[48] OLSSON T, HAAGE M, KIHLMAN H, et al. Cost-efficient drilling using industrial robots with high-bandwidth force feedback[J]. Robotics and computer-integrated manufacturing, 2010, 26(1): 24–38.
[49] JIN Long, SHI Xin, DONG Huiyue, et al. Study on robot automatic drilling of carbon fiber reinforced plastics (CFRP)[J]. Advanced materials research, 2014, 889/890: 1144–1149.
[50] Hellstern C. Investigation of interlayer burr formation in the drilling of stacked aluminum sheets[J]. georgia institute of technology, 2009, 57(1): 33–46.
[51] MELKOTE S N, NEWTON T R, HELLSTERN C, et al. Interfacial Burr Formation in Drilling of Stacked Aerospace Materials[C]//Burrs-Analysis, Control and Removal. Berlin, Heidelberg: Springer, 2010: 89?98.
[52] KIM S J, JEON S M, NAM J K, et al. Closed-loop control of a self-positioning and rolling magnetic microrobot on 3D thin surfaces using biplane imaging[J]. IEEE transactions on magnetics, 2014, 50(11): 1–4.
[53] ERKORKMAZ K, ALZAYDI A, ELFIZY A, et al. Time-optimized hole sequence planning for 5-axis on-the-fly laser drilling[J]. CIRP annals, 2014, 63(1): 377–380.
[54] NUBIOLA A, BONEV I A. Absolute calibration of an ABB IRB 1600 robot using a laser tracker[J]. Robotics and computer-integrated manufacturing, 2013, 29(1): 236–245.
[55] MA Le, BAZZOLI P, SAMMONS P M, et al. Modeling and calibration of high-order joint-dependent kinematic errors for industrial robots[J]. Robotics and computer-integrated manufacturing, 2018, 50: 153–167.
[56] ZENG Yuanfan, TIAN Wei, LIAO Wenhe. Positional error similarity analysis for error compensation of industrial robots[J]. Robotics and computer-integrated manufacturing, 2016, 42: 113–120.
[57] ZENG Y, TIAN W, LI D, et al. An error-similarity-based robot positional accuracy improvement method for a robotic drilling and riveting system[J]. The international journal of advanced manufacturing technology, 2016, 88(9-12): 2745–2755.
[58] TIAN Wei, ZENG Yuanfan, ZHOU Wei, et al. Calibration of robotic drilling systems with a moving rail[J]. Chinese journal of aeronautics, 2014, 27(6): 1598–1604.
[59] YUAN Peijiang, CHEN Dongdong, WANG Tianmiao, et al. A compensation method based on extreme learning machine to enhance absolute position accuracy for aviation drilling robot[J]. Advances in mechanical engineering, 2018, 10(3).https://doi.org/10.1177/1687814018763411
[60] SULZER J, KOVA? I. Enhancement of positioning accuracy of industrial robots with a reconfigurable fine-positioning module[J]. Precision engineering, 2010, 34(2): 201–217.
[61] LIU Hua, ZHU Weidong, DONG Huiyue, et al. An improved kinematic model for serial robot calibration based on local POE formula using position measurement[J]. Industrial robot:an international journal, 2018, 45(5): 573–584.
[62] ZHU Weidong, MEI Biao, YAN Guorui, et al. Development of a monocular vision system for robotic drilling[J]. Journal of Zhejiang University Science C, 2014, 15(8): 593–606.
[63] ZHU Weidong, MEI Biao, YAN Guorui, et al. Measurement error analysis and accuracy enhancement of 2D vision system for robotic drilling[J]. Robotics and computer-integrated manufacturing, 2014, 30(2): 160–171.
[64] ZHAN Qiang, WANG Xiang. Hand-eye calibration and positioning for a robot drilling system[J]. The international journal of advanced manufacturing technology, 2012, 61(5/6/7/8): 691–701.
[65] LIU Yuanwei, YUAN Peijiang, CHEN Dongdong, et al. Simultaneous calibration of hand-eye relationship, robot-world relationship and robot geometric parameters with stereo vision[M]//Communications in Computer and Information Science. Singapore: Springer Singapore, 2017: 462?475.
[66] SEPEHR G, SHU Tingting, AHMED J, et al. Online pose correction of an industrial robot using an optical coordinate measure machine system[J]. International journal of advanced robotic systems, 2018, 15(4).https://doi.org/10.1177/1729881418787915.

备注/Memo

收稿日期:2021-06-30。
基金项目:国家自然科学基金项目(51475127);黑龙江省自然科学基金项目(QC2018064; JJ2022LH0716);普通高等学校创新人才培养计划(UNPYSCT-2018196)
作者简介:付鹏强,副教授,博士,中国机械工程学会生产工程分会(机床)委员会委员,中国振动工程学会动态测试专业委员会会员,主要研究方向为机器人自动制孔加工技术、精密超精密加工与检测技术。主持和参与国家科技重大专项、国家自然科学基金、黑龙江省自然科学基金、企事业委托项目等科研项目20余项。发表学术论文20余篇;苗宇航,硕士,主要研究方向为机器人加工、复合材料加工、动力电池设计。参与国家自然科学基金、黑龙江省自然科学基金等,专利10余项,发表学术论文3篇;王义文,教授,博士,黑龙江省刀具技术协会理事,中国振动工程学会动态测试专业委员会委员。主要研究方向为超硬材料加工、制造过程检测技术、机电产品开发。主持国家863项目、国家重大专项、黑龙江省应用技术研究项目等多个项目。发表学术 论文20余篇
通讯作者:付鹏强. E-mail:pqfu@hrbust.edu.cn

更新日期/Last Update: 1900-01-01
Copyright © 《 智能系统学报》 编辑部
地址:(150001)黑龙江省哈尔滨市南岗区南通大街145-1号楼 电话:0451- 82534001、82518134 邮箱:tis@vip.sina.com