Design and simulation of a cable-pulley-based transmission for artificial ankle joints

doi:10.1007/s11465-016-0383-0

Front. Mech. Eng.

2016, Vol. 11

Issue (2) : 170-183 https://doi.org/10.1007/s11465-016-0383-0

RESEARCH ARTICLE

Design and simulation of a cable-pulley-based transmission for artificial ankle joints

Huaxin LIU¹,Marco CECCARELLI^2,^*(

),Qiang HUANG³

¹. Intelligent Robotics Institute, School of Mechatronical Engineering, Beijing Institute of Technology, Beijing 100081, China; Key Laboratory of Biomimetic Robots and Systems (Beijing Institute of Technology), Ministry of Education, Beijing 100081, China
². Laboratory of Robotics and Mechatronics (LARM), DICeM, University of Cassino and South Latium, Cassino 03043, Italy
³. Intelligent Robotics Institute, School of Mechatronical Engineering, Beijing Institute of Technology, Beijing 100081, China; Key Laboratory of Biomimetic Robots and Systems (Beijing Institute of Technology), Ministry of Education, Beijing 100081, China; Beijing Innovation Center for Intelligent Robots and Systems, Beijing 100081, China; State Key Laboratory of Intelligent Control and Decision of Complex Systems, Beijing 100081, China

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Abstract

In this paper, a mechanical transmission based on cable pulley is proposed for human-like actuation in the artificial ankle joints of human-scale. The anatomy articular characteristics of the human ankle is discussed for proper biomimetic inspiration in designing an accurate, efficient, and robust motion control of artificial ankle joint devices. The design procedure is presented through the inclusion of conceptual considerations and design details for an interactive solution of the transmission system. A mechanical design is elaborated for the ankle joint angular with pitch motion. A multi-body dynamic simulation model is elaborated accordingly and evaluated numerically in the ADAMS environment. Results of the numerical simulations are discussed to evaluate the dynamic performance of the proposed design solution and to investigate the feasibility of the proposed design in future applications for humanoid robots.

Keywords biomimetic designs ankle joints cable-pulley transmissions multi-body dynamic simulation numerical characterization

Corresponding Author(s): Marco CECCARELLI

Online First Date: 23 May 2016 Issue Date: 29 June 2016

Cite this article:

Huaxin LIU,Marco CECCARELLI,Qiang HUANG. Design and simulation of a cable-pulley-based transmission for artificial ankle joints[J]. Front. Mech. Eng., 2016, 11(2): 170-183.

URL:

https://academic.hep.com.cn/fme/EN/10.1007/s11465-016-0383-0
https://academic.hep.com.cn/fme/EN/Y2016/V11/I2/170

Fig.1 Anatomy of the human ankle

Fig.2 Simplified model of the human ankle in the sagittal plane with main design parameters

Fig.3 Conceptual kinematic design of the ankle joint with cable-pulley transmission and its design parameters

Fig.4 CAD of the mechanism in Fig. 3 for artificial ankle joint

Fig.5 Flowchart for designing a cable-pulley-based solution in Fig. 4 for artificial ankle joints

Fig.6 CAD model for multi-body dynamic simulation

Tab.1 Design parameters for ankle motion simulation of the design in Fig. 4

Fig.7 Snapshot of a simulated motion of the design artificial ankle joint: (a) 3.00 s; (b) 3.25 s; (c) 3.50 s; (d) 3.75 s; (e) 4.00 s

Tab.2 Assumed parameters in the ADAMS model in Fig. 6

Fig.8 Numerical results of Mode 1 motion simulation: (a) Driven pulley kinematic history; (b) cable kinematic history

Fig.9 Numerical results of mode1 motion simulation: (a) Motor shaft reaction force; (b) ankle shaft reaction force

Fig.10 Numerical results of the cable tension in Mode 1 motion simulation

Fig.11 Numerical results of the motor driving input in Mode 1 motion simulation

Fig.12 Numerical results of Mode 2 motion simulation: (a) Driven pulley kinematic history; (b) cable kinematic history

Fig.13 Numerical results of Mode 2 motion simulation: (a) Motor shaft reaction force; (b) ankle shaft reaction force

Fig.14 Numerical results of the cable stretched tension in Mode 2 motion simulation

Fig.15 Numerical results of the motor driving input in Mode 2 motion simulation

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