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Enhancing fluency and productivity in human-robot collaboration through online scaling of dynamic safety zones

Lorenzo Scalera, Andrea Giusti, Renato Vidoni, Alessandro Gasparetto

2022The International Journal of Advanced Manufacturing Technology49 citationsDOIOpen Access PDF

Abstract

Abstract Industrial collaborative robotics is promising for manufacturing activities where the presence of a robot alongside a human operator can improve operator’s working conditions, flexibility, and productivity. A collaborative robotic application has to guarantee not only safety of the human operator, but also fluency in the collaboration, as well as performance in terms of productivity and task time. In this paper, we present an approach to enhance fluency and productivity in human-robot collaboration through online scaling of dynamic safety zones. A supervisory controller runs online safety checks between bounding volumes enclosing robot and human to identify possible collision dangers. To optimize the sizes of safety zones enclosing the manipulator, the method minimizes the time of potential stop trajectories considering the robot dynamics and its torque constraints, and leverages the directed speed of the robot parts with respect to the human. Simulations and experimental tests on a seven-degree-of-freedom robotic arm verify the effectiveness of the proposed approach, and collaborative fluency metrics show the benefits of the method with respect to existing approaches.

Topics & Concepts

Human–robot interactionRobotFlexibility (engineering)FluencyTask (project management)Human–computer interactionRoboticsOperator (biology)ProductivityController (irrigation)Computer scienceEngineeringArtificial intelligenceSimulationControl engineeringSystems engineeringBiologyMacroeconomicsStatisticsEconomicsTranscription factorLinguisticsGeneRepressorPhilosophyChemistryBiochemistryAgronomyMathematicsRobot Manipulation and LearningManufacturing Process and OptimizationFlexible and Reconfigurable Manufacturing Systems