DocumentCode
2622591
Title
Double Actuator Unit with Planetary Gear Train for a Safe Manipulator
Author
Kim, Byeong-Sang ; Park, Jung-Jun ; Song, Jae-Bok
Author_Institution
Dept. of Mech. Eng., Korea Univ., Seoul, NY
fYear
2007
fDate
10-14 April 2007
Firstpage
1146
Lastpage
1151
Abstract
Control of a robot manipulator in contact with the environment is usually conducted by the direct feedback control system using a force-torque sensor or the indirect impedance control scheme. Although these methods have been successfully applied to many applications, simultaneous control of force and position cannot be achieved. Furthermore, collision safety has been of primary concern in recent years with emergence of service robots in direct contact with humans. To cope with such problems, redundant actuation has been used to enhance the performance of a position/force controller. In this paper, the novel design of a double actuator unit (DAU) composed of double actuators and a planetary gear train is proposed to provide the capability of simultaneous control of position and force as well as the improved collision safety. Since one actuator controls position and the other actuator modulates stiffness, DAU can control the position and stiffness simultaneously at the same joint. The torque exerted on the joint can be estimated without an expensive torque/force sensor. DAU is capable of detecting dynamic collision by monitoring the speed of the stiffness modulator. Upon detection of dynamic collision, DAU immediately reduces its joint stiffness according to the collision magnitude, thus providing the optimum collision safety. It is shown from various experiments that DAU can provide good performance of position tracking, force estimation and collision safety.
Keywords
actuators; feedback; force control; manipulators; mobile robots; position control; collision safety; direct feedback control system; double actuator unit; force control; force-torque sensor; indirect impedance control; planetary gear train; position control; robot manipulator; service robots; Actuators; Control systems; Force control; Force sensors; Gears; Manipulators; Robot control; Robot sensing systems; Safety; Torque;
fLanguage
English
Publisher
ieee
Conference_Titel
Robotics and Automation, 2007 IEEE International Conference on
Conference_Location
Roma
ISSN
1050-4729
Print_ISBN
1-4244-0601-3
Electronic_ISBN
1050-4729
Type
conf
DOI
10.1109/ROBOT.2007.363139
Filename
4209243
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