Title :
Robotic force control for flexible assembly
Author :
Wapenhans, H. ; Seyfferth, W. ; Pfeiffer, F.
Author_Institution :
Lehrstuhl B fuer Mechanik. Tech. Univ. Munchen, Germany
Abstract :
The authors present a complete design procedure for determining an optimal force control for assembly tasks while assuring stability. Based on a constrained motion model of the robot, including elasticity of joints and force sensor, a custom design scheme may be applied for individual types of mating tasks. The approach guarantees separation of position and force controlled cartesian directions of the robot endpoint by complementary input/output decoupling. Position feedback parameters are optimized to obtain a maximum stability reserve and force feedback parameters are optimized to minimize settling time. Controller behavior is then predicted by the simulation of the potentially unsteady system dynamics including time-varying constraints on the workpiece. The design process is illustrated for a peg-in-hole insertion and verified by experimental results from a laboratory robot
Keywords :
assembling; control system synthesis; feedback; force control; industrial robots; optimal control; stability; cartesian directions; complementary input/output decoupling; constrained motion model; design procedure; elasticity; flexible assembly; force feedback parameters; force sensor; joints; mating tasks; maximum stability reserve; optimal force control; peg-in-hole insertion; position feedback parameters; robot endpoint; robotic force control; simulation; time-varying constraints; Elasticity; Force control; Force feedback; Force sensors; Predictive models; Process design; Robot sensing systems; Robotic assembly; Stability; Time varying systems;
Conference_Titel :
Robotics and Automation, 1993. Proceedings., 1993 IEEE International Conference on
Conference_Location :
Atlanta, GA
Print_ISBN :
0-8186-3450-2
DOI :
10.1109/ROBOT.1993.291987
