Seongmin Seo scite author profile

IEEE Robot. Autom. Lett.

Bae

2019

Various robotic grippers have been developed over the past several decades for robotic manipulators. Especially, the soft grippers based on the soft pneumatic actuator (SPA) have been studied actively, since it offers more pliable bending motion, inherent compliance, and a simple morphological structure. However, few studies have focused on simultaneously improving the fingertip force and actuation speed within the specified design parameters. In this study, we developed a hybrid gripper that incorporates both soft and rigid components to improve the fingertip force and actuation speed simultaneously based on three design principles: first, the degree of bending is proportional to the ratio of the rigid structure; second, a concave chamber design is preferred for large longitudinal strain; and third, a round shape between soft and rigid materials increases the fingertip force. The suggested principles were verified using the finite element methods. The improved performance of the hybrid gripper was verified experimentally and compared with the performance of a conventional SPAs. The ability of the hybrid gripper to grasp different objects was evaluated and was applied in a teleoperated system. Index Terms-Soft material robotics, grippers and other endeffectors, flexible robots. I. INTRODUCTION R ECENTLY, the limitations of rigid gripper due to the necessity of additional linkages, complicated controls, and so on, have been overcome by the soft gripper [1]. Especially, the soft grippers based on soft pneumatic actuators (SPAs), which offer better compliance, and a higher degree of freedom than the rigid robot, have been actively developed [2]-[9]. Due to the inherent compliance of soft materials, complicated controls and additional structures are not needed with soft grippers, as the proper selection of materials of various stiffness allows for simple control. Furthermore, soft grippers with SPAs are constructed from low-cost and readily-available elastomers.

show abstract

A Sensorized Hybrid Gripper to Evaluate a Grasping Quality Based on a Largest Minimum Wrench

IEEE Robot. Autom. Lett.

et al. 2020

Soft pneumatic grippers, which are based on soft pneumatic actuators have been widely studied owing to their simple morphological structure, inherent compliance, and pliable grasp. Additionally, the integration of the soft gripper with various sensors to improve its functionality has also been extensively studied. Although the soft gripper is known to exhibit a robust grasping performance without accurate control, the grasping quality of the soft gripper has rarely been studied due to the lack of adequate embedded sensors and quality metrics of the soft gripper. Therefore, a hybrid gripper, which is a soft gripper with rigid components, was sensorized by embedding a soft force sensor and a bending sensor to evaluate the grasping quality. Furthermore, a new grasping quality metric for a soft gripper was proposed, which calculates the largest minimum wrench of a convex hull in the wrench space. The proposed grasping quality metric was experimentally verified, and a real-time program was developed to evaluate the grasping quality.

show abstract

Origami-Structured Actuating Modules for Upper Limb Support

IEEE Robot. Autom. Lett.

Lee

et al. 2021

Development of a Hybrid Gripper with Soft Material and Rigid Structures

Park¹,

Seo²,

Bae³

2018

Development of a Sensorized Hybrid Gripper to Evaluate Grasping Quality

Bae

2019