[1]TIAN Yong,WANG Hongguang,PAN Xinan,et al.Research on configuration analysis of collaborative robots[J].CAAI Transactions on Intelligent Systems,2019,14(2):217-223.[doi:10.11992/tis.201806044]
Copy

Research on configuration analysis of collaborative robots

CAAI Transactions on Intelligent Systems[ISSN 1673-4785/CN 23-1538/TP] Volume: 14 Number of periods: 2019 2 Page number: 217-223 Column: 学术论文—智能系统 Public date: 2019-03-05
Title:
Research on configuration analysis of collaborative robots
Author(s):
TIAN Yong12 WANG Hongguang1 PAN Xinan1 HU Mingwei12
1. State Key Laboratory of Robotics, Shenyang Institute of Automation, Chinese Academy of Sciences, Shenyang 110016;
2. University of Chinese Academy of Sciences, Beijing 100049
Keywords:
collaborative robotsconfigurationevolutionaryoffsetperformance Index
CLC:
TP241
DOI:
10.11992/tis.201806044
Abstract:
In this study, by analyzing the configurations of collaborative robots, it is concluded that offset is an important factor affecting the configuration. First, the configurations of existing typical collaborative robots were analyzed to obtain the difference of configurations through the evolutionary process between the configurations. Then, the offset was defined using the difference between configurations and was divided into S-type and Y-type according to the influence on the range of motion of the joint. Finally, the global performance index, the workspace volume index, and the flexible workspace index were used as performance evaluation criteria to simulate the performance of collaborative robots, namely iiwa, Sawyer, and Yumi. Through comparative analysis, it was seen that the existence of offset reduced the global performance of configuration and the volumetric performance of workspace, but improved the performance of flexible workspace. The results show that offset is an important factor influencing robot performance. This analysis provides a theoretical basis for the configuration design of collaborative robots.
References:
[1] International Organization for Standardization (ISO). Robots and robotic devices-Collaborative robots[EB/OL]. (2016-02-04)[2017-03-15]. https://www.iso.org/standard/62996.html.
[2] 胡明伟, 王洪光, 潘新安, 等. 一种协作型机器人运动性能分析与仿真[J]. 智能系统学报, 2017, 12(1):75-81 HU Mingwei, WANG Hongguang, PAN Xin’an, et al. Analysis and simulation on kinematics performance of a collaborative robot[J]. CAAI transactions on intelligent systems, 2017, 12(1):75-81
[3] 侯澈, 王争, 赵忆文, 等. 面向直接示教的机器人负载自适应零力控制[J]. 机器人, 2017, 39(4):439-448 HOU Che, WANG Zheng, ZHAO Yiwen, et al. Load adaptive force-free control for the direct teaching of robots[J]. Robot, 2017, 39(4):439-448
[4] STOLT A, LINDEROTH M, ROBERTSON A, et al. Robotic assembly of emergency stop buttons[C]//Proceedings of 2013 IEEE/RSJ International Conference on Intelligent Robots and Systems. Tokyo, Japan, 2013.
[5] GUIZZO E, ACKERMAN E. How rethink robotics built its new Baxter robot worker[R]. IEEE Spectrum, 2012.
[6] WANG Kesheng, LIEN T K. The structure design and kinematics of a robot manipulator-I. Theory[J]. Robotics and computer-integrated manufacturing, 1989, 5(2/3):153-158.
[7] HOLLERBACH J M. Optimum kinematic design for a seven degree of freedom manipulator[C]//Proceedings of the Robotics Research:The Second International Symposium. Cambridge, USA, 1985:215-222.
[8] 归彤, 原培章. 7自由度机器人的图谱问题[J]. 机器人, 1991, 13(4):27-30 GUI Tong, YUAN Peizhang. An atlas of 7-DOF robot manipulators[J]. Robot, 1991, 13(4):27-30
[9] 赵占芳. 七自由度机器人机构的选型[J]. 机器人, 1989, 3(1):53-56 ZHAO Zhanfang. The selection of seven degrees of freedom robot mechanism[J]. Robot, 1989, 3(1):53-56
[10] STEVENSON R, SHIRINZADEH B, ALICI G. Singularity avoidance and aspect maintenance in redundant manipulators[C]//Proceedings of the 7th International Conference on Control, Automation, Robotics and Vision. Singapore, Singapore, 2002:857-862.
[11] YU Chao, JIN Minghe, LIU Hong. An analytical solution for inverse kinematic of 7-DOF redundant manipulators with offset-wrist[C]//Proceedings of 2012 IEEE International Conference on Mechatronics and Automation. Chengdu, China, 2012:92-97.
[12] SINGH G K, CLAASSENS J. An analytical solution for the inverse kinematics of a redundant 7DoF manipulator with link offsets[C]//Proceedings of 2010 IEEE/RSJ International Conference on Intelligent Robots and Systems. Taipei, Taiwan, China, 2010:2976-2982.
[13] GOGU G. Structural synthesis of fully-isotropic parallel robots with Sch?nflies motions via theory of linear transformations and evolutionary morphology[J]. European journal of mechanics-A/solids, 2007, 26(2):242-269.
[14] TSAI Y C, SONI A H. The effect of link parameter on the working space of general 3R robot arms[J]. Mechanism and machine theory, 1984, 19(1):9-16.
[15] VAHRENKAMP N, ASFOUR T, METTA G, et al. Manipulability analysis[C]//Proceedings of the 12th IEEE-RAS International Conference on Humanoid Robots. Osaka, Japan, 2012:568-573.
[16] PORGES O, STOURAITIS T, BORST C, et al. Reachability and capability analysis for manipulation tasks[M]//ARMADA M A, SANFELIU A, FERRE M. ROBOT2013:First Iberian Robotics Conference. Cham:Springer, 2014:703-718.
Similar References:

Memo

-

Last Update: 2019-04-25

Copyright © CAAI Transactions on Intelligent Systems