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Hybrid compliance compensation for path accuracy enhancement in robot machining

Felix Hähn, Matthias Weigold

2020Production Engineering13 citationsDOIOpen Access PDF

Abstract

Abstract Robot machining processes with high material removal rates lack of high path accuracy mainly due to the low stiffness of industrial robots. The low stiffness leads to process forces caused deviations of the tool center point (TCP) from the planned position of more than 1 mm in industrial applications. To enhance the path accuracy a novel hybrid compliance compensation is developed. It combines a force sensor and model based online compensation with forces of an offline simulation to instantly react to predictable high force changes e.g. at a milling cutter exit from the work piece. The method is applied to a KUKA KR 300 robot. A compliance model based on a forward kinematic with virtual joints is implemented on an external controller. Cartesian or axis specific compensation values are calculated and transferred to the robot via a control circuit. A compliance measurement method is developed and a force torque sensor is mounted to the flange of the robot. The system is validated in with Cartesian and axis specific compensation values as well as with and without pilot control.

Topics & Concepts

Cartesian coordinate systemRobotCompensation (psychology)MachiningControl theory (sociology)Controller (irrigation)KinematicsStiffnessTorqueEngineeringSimulationControl engineeringComputer scienceMechanical engineeringStructural engineeringControl (management)Artificial intelligencePhysicsMathematicsThermodynamicsAgronomyClassical mechanicsPsychologyGeometryPsychoanalysisBiologyAdvanced machining processes and optimizationAdvanced Surface Polishing TechniquesAdvanced Measurement and Metrology Techniques