Title :
Robotic grinding force regulation: design, implementation and benefits
Author :
Liu, L. ; Ulrich, B.J. ; Elbestawi, M.A.
Author_Institution :
Dept. of Mech. Eng., McMaster Univ., Hamilton, Ont., Canada
Abstract :
The design and implementation of force control for robotic rigid disk grinding are described. Experiments were conducted using a PUMA 762/VAL II industrial robot equipped with a 4-hp pneumatic grinder and a JR3 force sensor. An external, 386-based host microcomputer, communicating with VAL II online, performs the force control algorithm calculations. The robotic grinding force model used was an experimentally verified analytic model. It was found that the grinding forces are very sensitive to the robot arm stiffness. Also, the end-effector path tracking errors, caused by the limited accuracy of the PUMA robot, significantly affect the grinding forces. The experimental results show, however, that a finely tuned PID force-feedback controller is able to maintain the grinding forces at a specified value. It can effectively compensate for force errors caused by both step force disturbances and robot path-tracking errors. The benefits of such force control are demonstrated by improved profiles of finished workpieces
Keywords :
control system synthesis; feedback; force control; grinding; industrial robots; microcomputer applications; three-term control; 386 micros; JR3 force sensor; PID force-feedback controller; PUMA 762/VAL II industrial robot; end-effector path tracking errors; force control; host microcomputer; pneumatic grinder; robot arm stiffness; robotic rigid disk grinding; step force disturbances; Force control; Force sensors; Mechanical engineering; Mobile robots; Robot control; Robot sensing systems; Robotics and automation; Service robots; Testing; Wheels;
Conference_Titel :
Robotics and Automation, 1990. Proceedings., 1990 IEEE International Conference on
Conference_Location :
Cincinnati, OH
Print_ISBN :
0-8186-9061-5
DOI :
10.1109/ROBOT.1990.125983
