Instrumenting a Robotic Finger to Augment the Capabilities of Robotic Grippers

Robots are helping humans perform tasks, especially in industry. The collaboration between humans and machines is considered to be among the principal factors underlying the so-called Industry 4.0. To boost such a form of collaboration, robots could be provided with a higher degree of instrumentatio...

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Bibliographic Details
Published inIEEE transactions on instrumentation and measurement Vol. 72; pp. 1 - 11
Main Authors Romeo, Rocco Antonio, Zocco, Agata, Parmiggiani, Alberto, Mura, Andrea, Gesino, Michele, Accame, Marco, Maggiali, Marco, Fiorio, Luca
Format Journal Article
LanguageEnglish
Published New York IEEE 2023
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Bending moments
Cables
Center of pressure
Collaboration
Cooperation
Electronics
End effectors
Fingers
Force
Force measurement
Force/torque sensor
Grasping
Grasping force
Grippers
Industrial applications
Industry 4.0
Inertial sensing devices
inertial sensor
instrumented finger (IF)
Instruments
Robot arms
Robot sensing systems
robotic finger
robotic gripper
Robotics
Robots
Sensors
Service robots
tactile sensor
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Summary:Robots are helping humans perform tasks, especially in industry. The collaboration between humans and machines is considered to be among the principal factors underlying the so-called Industry 4.0. To boost such a form of collaboration, robots could be provided with a higher degree of instrumentation, which undoubtedly resorts to a reliable sensorization. In this regard, the robot end-effector is central, being often the interaction organ of the robot. The present article aims at delivering a device, namely, instrumented finger (IF), which can be mounted on robotic end-effectors such as grippers. The device is able to sense the grasping force and the associated bending moment, thanks to an integrated load cell. It also has a tactile matrix through which the center of pressure can be determined, as well as the slip. Furthermore, the device electronics includes an inertial sensor. Cables are protected by covers which hide the inner metallic body and the electronics. The device is compact, robust, and precise, and it constitutes a promising solution for the instrumentation of robotic grippers. In the present article, the IF functionalities, such as measurement of force, torque, acceleration, and CoP, will be demonstrated. Furthermore, it will be shown the IF integration on a real industrial gripper mounted on a robotic arm, executing slip compensation experiments and mass estimation of grasped items.
ISSN:0018-9456
1557-9662
DOI:10.1109/TIM.2023.3256477