Force distribution and compliance control strategy for stable grasping of multi-arm space robot

被引：0

作者：

Chen G. ^{[1
]}

Huang Z.-Y. ^{[1
]}

Jiang T. ^{[1
]}

Li T. ^{[1
]}

You H. ^{[1
]}

机构：

[1] School of Modern Post, School of Automation), Beijing University of Posts and Telecommunications, Beijing

来源：

Kongzhi yu Juece/Control and Decision | 2024年 / 39卷 / 01期

关键词：

compliant control; force distribution; kinetic energy consumption; multi-arm space robot; stable grasping; vibration suppression;

D O I：

10.13195/j.kzyjc.2022.0073

中图分类号：

学科分类号：

摘要：

Aiming at the problem of unbalanced contact force and vibration that affects the grasping stability of multi-arm space robots, a force distribution and compliance control strategy is proposed. Firstly, the force balance conditions for stable grasping is analyzed, the safety factor based on the friction cone constraint is designed, which is then introduced into the force optimization model to distribute the grasping force, so as to minimize the force under the condition of stable grasping. Secondly, the causes of vibration in the grasping transition process are analyzed, then the end effector's output force control strategy based on kinetic energy consumption is designed to achieve rapid vibration suppression and compliant grasp. Furthermore, the control-law switching strategy is designed, so that once the contact-separation phenomenon occurs during the grasping transition process, the end effector can be quickly guided to return to the surface of the goal object. The simulation shows that the proposed method not only improves the stable grasping's safety margin, but also significantly reduces the vibration amplitude, duration and maximum contact force of the end effector, improving the stability and compliance of the multi-arm space robot for target grasping operations. © 2024 Northeast University. All rights reserved.

引用

页码：112 / 120

页数：8

共 22 条

[1] McGregor R, Oshinowo L., Flight 6A: Deployment and checkout of the space station remote manipulator system, Proceedings of the 6th International Symposium on Artificial Intelligence and Robotics & Automation in Space: i-SAIRAS 2001, pp. 1-9, (2001)
[2] Yoshida K, Hashizume K, Abiko S., Zero reaction maneuver: Flight validation with ETS-VII space robot and extension to kinematically redundant arm, IEEE International Conference on Robotics and Automation, pp. 441-446, (2001)
[3] Huang P F, Lu Y B, Wang M, Et al., Attitude takeover control for spacecraft with unknown parameter, Control and Decision, 32, 9, pp. 1547-1555, (2017)
[4] Li W J, Cheng D Y, Liu X G, Et al., On-orbit service of spacecraft: A review of engineering developments, Progress in Aerospace Sciences, 108, pp. 32-120, (2019)
[5] Ding X L, Wang Y C, Wang Y B, Et al., A review of structures, verification, and calibration technologies of space robotic systems for on-orbit servicing, Science China Technological Sciences, 64, 3, pp. 462-480, (2021)
[6] Zhou Y Q, Luo J J, Wang M M., Dynamic coupling analysis of multi-arm space robot, Acta Astronautica, 160, pp. 583-593, (2019)
[7] Xu R N, Luo J J, Wang M M., Kinematic and dynamic manipulability analysis for free-floating space robots with closed chain constraints, Robotics and Autonomous Systems, 130, (2020)
[8] Yoshikawa T, Nagai K., Evaluation and determination of grasping forces for multifingered hands, IEEE International Conference on Robotics and Automation Proceedings, pp. 245-248, (1988)
[9] Xiong C H, Xiong Y L, Zhang Z, Et al., Artificial neural network based on grasp planning for multifingered robot hand, China Mechanical Engineering, 2, (1997)
[10] Chen D J, Jiang L, Wang X Q., Computation of multi-fingered grasping force with linear combination, Journal of Harbin Institute of Technology, 45, 1, pp. 55-59, (2013)

← 1 2 3 →