Preliminary Design of a Three-Finger Underactuated Adaptive End Effector with a Breakaway Clutch Mechanism-Reference-Cited by-同舟云学术

Preliminary Design of a Three-Finger Underactuated Adaptive End Effector with a Breakaway Clutch Mechanism

Published:2015-10-20 Issue:5 Volume:27 Page:496-503
ISSN:1883-8049
Container-title:Journal of Robotics and Mechatronics
language:en
Short-container-title:J. Robot. Mechatron.

Author:

Telegenov Kuat, ,Tlegenov Yedige,Hussain Shahid,Shintemirov Almas,

Abstract

<div class=""abs_img""> <img src=""[disp_template_path]/JRM/abst-image/00270005/05.jpg"" width=""300"" /> A robotic end effector prototype</div> Commercially available robotic grippers are often expensive and not easy to modify for specific purposes of robotics research and education. To extend the choice of robotic end effectors available to researchers, this paper presents the preliminary work on prototype design and analysis of a three-finger underactuated robotic end effector with a breakaway clutch mechanism suitable for research in robot manipulation of objects for industrial and service applications. Kinematic models of the finger and the breakaway clutch mechanisms are analyzed aiming to define selection criteria of design parameters. Grasping performance of the end effector prototype manufactured with a 3D printing technology and off-the-shelf components is evaluated using simulation and experimental analyses. Comparison with widely applied available robotic end effectors shows the potential advantages of the proposed end effector design. </span>

Publisher

Fuji Technology Press Ltd.

Subject

Electrical and Electronic Engineering,General Computer Science

Reference31 articles.

1. S. Jacobsen, E. Iversen, D. Knutti, R. Johnson, and K. Biggers, “Design of the Utah/M.I.T. Dextrous Hand,” Proc. of the 1986 IEEE Int. Conf. on Robotics and Automation, pp. 1520-1532, 1986.

2. M. Baril, T. Laliberte, C. Gosselin, and F. Routhier, “On the Design of a Mechanically Programmable Underactuated Anthropomorphic Prosthetic Gripper,” ASME J. of Mechanical Design, Vol.135, No.12, p. 121008, 2013.

3. T. Laliberte, L. Birglen, and C. Gosselin, “Underactuation in robotic grasping hands, Machine Intelligence & Robotic Control,” Vol.4, No.3, pp. 1-11, 2002.

4. Y. Ando, “Microgripper,” J. of Robotics and Mechatronics, Vol.2, No.3, pp. 214-216, 1990.

5. F. Chen, K. Sekiyama, B. Sun, P. Di, J. Huang, H. Sasaki, and T. Fukuda, “Design and Application of an Intelligent Robotic Gripper for Accurate and Tolerant Electronic Connector Mating,” J. of Robotics and Mechatronics, Vol.24, No.3, pp. 441-451, 2012.

Cited by 7 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Design and Analysis of an Adaptive Robotic Gripper;Lecture Notes in Mechanical Engineering;2024

2. Control of a worm-wheel gear driven rescue robot with friction compensation and its experimental verification;Advances in Mechanical Engineering;2023-10

3. Analysis of Multiple Print-Head Displacement Mechanisms in 3D Space for Material Extrusion Machine;3D Printing and Additive Manufacturing;2023-09-26

4. Toward an Improved Understanding for Design of Material Extrusion Additive Manufacturing Process‐Based 3D Printers—a Computational Study;Advanced Theory and Simulations;2022-11-18

5. A new graphical technique for acceleration analysis of four bar mechanisms using the instantaneous center of zero acceleration;SN Applied Sciences;2021-02-15