Robot-process precision modelling for the improvement of productivity in flexible manufacturing cells

Industrial robots are traditionally used at machining cells for machine feeding and workpiece handling. A reassignment of tasks to improve the productivity requires a modelling of the robot behaviour from the point of view of its position precision. This paper characterizes and predicts the precisio...

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Bibliographic Details
Published inRobotics and computer-integrated manufacturing Vol. 65; p. 101966
Main Authors Ferreras-Higuero, E., Leal-Muñoz, E., García de Jalón, J., Chacón, E., Vizán, A.
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.10.2020
Elsevier BV
Subjects
Cutting parameters
Cutting tools
Drilling
Drilling robot
Flexible manufacturing systems
Industrial robots
Machining
Model testing
Modelling
Multibody system with mixed coordinates
Multibody systems
Position tolerance
Productivity
Quaternions
Robots
Stiffness
Uncertainty
Uncertainty analysis
Workpieces
Drilling robot
Position tolerance
Quaternions
Multibody system with mixed coordinates
Uncertainty analysis
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Summary:Industrial robots are traditionally used at machining cells for machine feeding and workpiece handling. A reassignment of tasks to improve the productivity requires a modelling of the robot behaviour from the point of view of its position precision. This paper characterizes and predicts the precision achievable when drilling with an industrial robot in order to use it in machining operations. Robot behaviour and drilling phenomena are analysed to determine working accuracy and their contribution in position deviation and uncertainty. An efficient model for drilling is developed, applying quaternions and considering the influence of all cutting tool angles, providing a very precise estimation of drilling torques and forces. An innovative model for the robot is developed based on multibody systems, using mixed natural coordinates that enhance the computing and deliver outputs with direct interpretation. Besides, the effect of stiffness is added in joints as additional element. The complete robot-process model shows the significative process influence in working precision against robot influence. This influence is responsible of up to 40% of the total uncertainty. The model and the tests performed show that the deviations and their uncertainties depend strongly on drilling forces and the robot configuration. In the other hand, the model allows to correct the systematic behaviour in robot deviations and improve with that the position tolerance of the holes to be drilled.
ISSN:0736-5845
1879-2537
DOI:10.1016/j.rcim.2020.101966