A variable stiffness robotic gripper based on structure-controlled principle

This paper presents a novel structure-controlled variable stiffness robotic gripper that enables adaptive gripping of soft and rigid objects with a wide range of compliance. With the structure-controllable principle, the stiffness is controlled by the mechanical structure configurations rather than...

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Main Authors: Li, Xiong, Chen, Wenjie, Lin, Wei, Low, Kin Huat
Other Authors: School of Mechanical and Aerospace Engineering
Format: Article
Language:English
Published: 2020
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Online Access:https://hdl.handle.net/10356/140179
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1401792020-05-27T04:31:56Z A variable stiffness robotic gripper based on structure-controlled principle Li, Xiong Chen, Wenjie Lin, Wei Low, Kin Huat School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Adaptive Gripper Robotic Gripper This paper presents a novel structure-controlled variable stiffness robotic gripper that enables adaptive gripping of soft and rigid objects with a wide range of compliance. With the structure-controllable principle, the stiffness is controlled by the mechanical structure configurations rather than by material properties or electronic means. The principle is realized by changing the effective second moment of area of the gripper finger through rotating a built-in flexure hinge shaft. Based on this principle, the states of the stiffness can be continuously, instead of discretely, studied and assessed over the intermediate states from compliant to almost completely rigid. A variable stiffness mechanism has been developed to demonstrate the validity of the proposed principle. It enables that the finger stiffness and gripping position are independently controlled. With the introduction of flexure hinges, the undesired lateral buckling resulted from the rotation of a normal leaf spring is eliminated. In addition, a two-finger parallel gripper with this variable stiffness mechanism is developed which can provide the grasping stiffness according to the grasping task requirements. The effectiveness of the gripper has been demonstrated to handle the objects range from light, fragile to heavy, rigid without using any feedback loop or soft pads. Note to Practitioners - This work was inspired by the fact that the capability of variable stiffness in the robot actuator can reduce the undesired impacts to the robot arms. It can also allow a safer interaction between robot and human. Gripping of objects with uncertainties in shapes and position, as well as large variations in fragility and weight can also benefit from the concept of the variable stiffness. However, existing designs of variable stiffness grippers either have limited stiffness range or bulky configurations. They compromised the practical applications. This paper introduces a design in that a rotating flexure hinge shaft is embedded inside the robotic gripper finger. The mechanical stiffness of such fingers can be varied by changing the rotation angle of the flexure hinges. We present the working principle supported by mathematical models in the design and development. We also show an example design of a two-finger parallel gripper equipped with the VSFs. Extensive experiments demonstrated that the gripper is effective in gripping objects with wide range of uncertainties. Such gripper design avoids the use of soft pads as well as closed-loop control and high-precision sensors. In the future work, we shall implement such grippers for actual industrial applications. ASTAR (Agency for Sci., Tech. and Research, S’pore) 2020-05-27T04:31:56Z 2020-05-27T04:31:56Z 2017 Journal Article Li, X., Chen, W., Lin, W., Low, K. H. (2018). A variable stiffness robotic gripper based on structure-controlled principle. IEEE Transactions on Automation Science and Engineering, 15(3), 1104-1113. doi:10.1109/TASE.2017.2732729 1545-5955 https://hdl.handle.net/10356/140179 10.1109/TASE.2017.2732729 2-s2.0-85028500886 3 15 1104 1113 en IEEE Transactions on Automation Science and Engineering © 2017 IEEE. All rights reserved.
institution Nanyang Technological University
building NTU Library
country Singapore
collection DR-NTU
language English
topic Engineering::Mechanical engineering
Adaptive Gripper
Robotic Gripper
spellingShingle Engineering::Mechanical engineering
Adaptive Gripper
Robotic Gripper
Li, Xiong
Chen, Wenjie
Lin, Wei
Low, Kin Huat
A variable stiffness robotic gripper based on structure-controlled principle
description This paper presents a novel structure-controlled variable stiffness robotic gripper that enables adaptive gripping of soft and rigid objects with a wide range of compliance. With the structure-controllable principle, the stiffness is controlled by the mechanical structure configurations rather than by material properties or electronic means. The principle is realized by changing the effective second moment of area of the gripper finger through rotating a built-in flexure hinge shaft. Based on this principle, the states of the stiffness can be continuously, instead of discretely, studied and assessed over the intermediate states from compliant to almost completely rigid. A variable stiffness mechanism has been developed to demonstrate the validity of the proposed principle. It enables that the finger stiffness and gripping position are independently controlled. With the introduction of flexure hinges, the undesired lateral buckling resulted from the rotation of a normal leaf spring is eliminated. In addition, a two-finger parallel gripper with this variable stiffness mechanism is developed which can provide the grasping stiffness according to the grasping task requirements. The effectiveness of the gripper has been demonstrated to handle the objects range from light, fragile to heavy, rigid without using any feedback loop or soft pads. Note to Practitioners - This work was inspired by the fact that the capability of variable stiffness in the robot actuator can reduce the undesired impacts to the robot arms. It can also allow a safer interaction between robot and human. Gripping of objects with uncertainties in shapes and position, as well as large variations in fragility and weight can also benefit from the concept of the variable stiffness. However, existing designs of variable stiffness grippers either have limited stiffness range or bulky configurations. They compromised the practical applications. This paper introduces a design in that a rotating flexure hinge shaft is embedded inside the robotic gripper finger. The mechanical stiffness of such fingers can be varied by changing the rotation angle of the flexure hinges. We present the working principle supported by mathematical models in the design and development. We also show an example design of a two-finger parallel gripper equipped with the VSFs. Extensive experiments demonstrated that the gripper is effective in gripping objects with wide range of uncertainties. Such gripper design avoids the use of soft pads as well as closed-loop control and high-precision sensors. In the future work, we shall implement such grippers for actual industrial applications.
author2 School of Mechanical and Aerospace Engineering
author_facet School of Mechanical and Aerospace Engineering
Li, Xiong
Chen, Wenjie
Lin, Wei
Low, Kin Huat
format Article
author Li, Xiong
Chen, Wenjie
Lin, Wei
Low, Kin Huat
author_sort Li, Xiong
title A variable stiffness robotic gripper based on structure-controlled principle
title_short A variable stiffness robotic gripper based on structure-controlled principle
title_full A variable stiffness robotic gripper based on structure-controlled principle
title_fullStr A variable stiffness robotic gripper based on structure-controlled principle
title_full_unstemmed A variable stiffness robotic gripper based on structure-controlled principle
title_sort variable stiffness robotic gripper based on structure-controlled principle
publishDate 2020
url https://hdl.handle.net/10356/140179
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