Soft Robotics in Industrial Automation:  Adaptive Industrial Gripper Design and Evaluation

J. Turek; L. Miskarik; Jiri Vojtesek; L. Kopecek; L. Svacinova; Ales Mizera

Authors

J. Turek Tomas Bata University in Zlín
L. Miskarik Tomas Bata University in Zlín
Jiri Vojtesek Tomas Bata University in Zlín https://orcid.org/0000-0001-9923-7128
L. Kopecek Tomas Bata University in Zlín
L. Svacinova Tomas Bata University in Zlín
Ales Mizera Tomas Bata University in Zlín https://orcid.org/0000-0001-9681-1008

Keywords:

universal jamming gripper, industrial automation, soft robotics, variable stiffness, robotic grasping, automation flexibility, adaptive gripper

Abstract

The rapid evolution of industrial automation demands more versatile gripping solutions beyond conventional vacuum, magnetic, and fingered grippers. This study introduces the development and evaluation of an adaptive Universal Jamming Gripper (UJG) optimized for industrial applications. Utilizing a flexible membrane filled with granular materials, the UJG transitions between soft and rigid states under vacuum pressure, enabling secure and adaptive grasping of objects with diverse shapes and materials. Three types of membrane fillings—ground coffee, polystyrene microspheres (EPS), and thermoplastic elastomer granules (TPE)—were assessed for grip stability and force efficiency. Experimental results demonstrate that EPS microspheres provide superior adaptability and stability, offering the highest gripping force across various object geometries. Performance tests on a universal testing machine further validate the gripper’s capability to handle differently shaped objects with minimal adjustments. The findings underscore the potential of adaptive gripping technologies in enhancing automation flexibility, reducing operational downtime, and increasing overall industrial efficiency. Future research will focus on long-term durability, integration with robotic automation, and performance assessment in real-world manufacturing environments.

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Soft Robotics in Industrial Automation: Adaptive Industrial Gripper Design and Evaluation

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