access icon openaccess Research on compliant configuration of hydraulic manipulator with passive following characteristic

This is an open access article published by the IET under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0/)
Received 05/02/2020, Accepted 21/05/2020, Published 11/08/2020

To decrease the injury caused by an accidental collision between the hydraulic manipulator and human, a hydraulic rotating angle self-servo compliant robot driver joint is designed. Based on this joint, a variable stiffness passive servo-hydraulic rotary joint is improved. The passive follow-up characteristics of the improved servo-hydraulic rotary joint enable it to enter the low stiffness mode by itself when it encounters collisions beyond the force limit. Combining this characteristic, the research method of the hydraulic mechanical arm flexible configuration is proposed. Firstly, the joint motion mode is defined by the Euler angle, and a variety of configurations conforming to the motion characteristics of the manipulator are determined. Then, the virtual prototype and collision environment are built, and the dynamic characteristics of the end effector of the arm under high and low stiffness are measured. The results show that the flexible configurations with passive follow-up characteristics can significantly suppress the collision force. Finally, the visual method is employed to solve, draw, and compare the workspace of the selected compliant configuration, to obtain the optimal compliant configuration with both flexibility and motion, which provides theoretical guidance for the subsequent design of the compliant manipulator.

Inspec keywords: servomotors; end effectors; hydraulic systems; virtual prototyping; force control; springs (mechanical); manipulator dynamics; motion control; position control; control system synthesis; hydraulic actuators; manipulators; collision avoidance

Other keywords: hydraulic rotating angle self-servo compliant robot driver joint; collision environment; variable stiffness passive servo-hydraulic rotary joint; motion characteristics; virtual prototype; joint motion mode; optimal compliant configuration; Euler angle; flexibility; collision force; hydraulic manipulator; accidental collision; dynamic characteristics; compliant manipulator; hydraulic mechanical arm flexible configuration

Subjects: Spatial variables control; Mechanical variables control; Hydraulic and pneumatic control equipment; Manipulators; Control system analysis and synthesis methods

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