Download PDFOpen PDF in browserImpact of Actuator Torque Density on Expected Robot Life - A Dynamic ModelEasyChair Preprint 27278 pages•Date: February 20, 2020AbstractElectric actuators not only add weight along an articulated robot arm, but they also have torque and speed limits that impose additional dynamic constraints. Further, the useful life of a robot depends on the extent to which each actuator operates at or near its torque ratings. Cumulative damage theory offers some means of quantifying how much wear a robot arm will sustain in real time as it executes a given trajectory. The dynamic performance as well as fatigue wear of a hypothetical dual-link robot arm are examined in the context of actuator torque density - the actuator's torque-to-mass ratio. The results show that the expected wear to the most stressed joint are approximately inversely proportional to the actuator's torque density. The model also suggests how expected robot life under one or more pre-defined trajectories could be used as an additional constraint in robot arm design and actuator choice. Keyphrases: Fatigue life, Manipulator Dynamics, Manipulators, Mechatronics, Reliability, actuator mass, actuator torque, actuator torque density, cumulative damage, dual link robot arm, dynamic model, electromechanical systems, fatigue wear, gear ratio, intelligent actuators, maximum repeated torque, motion control, motion planning, nominal actuator torque density, path planning, reliability engineering, reliability theory, robot arm, robot kinematics, robot motion, torque density, torque rating, wrist actuator
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