Abstract

Soft robotic hands and grippers are increasingly attracting attention as robotic end effectors. Compared with their rigid counterparts, they are safer for human-robot and environment-robot interactions, easier to control, and more compliant, and they cost and weigh less. Design studies of soft robotic hands have focused mostly on the soft fingers and bending actuators. However, the palm is also an essential part in grasping. In this work, we propose a novel design for an inexpensive soft humanoid hand with pneumatic soft fingers and a soft palm. The configuration of the soft palm is based on a modular design that can be applied to actuate different kinds of existing soft fingers. The splaying of the fingers, bending of the whole palm, and abduction and adduction of the thumb are implemented by the palm. Moreover, we present a new design of soft finger, called the hybrid-bending soft finger (HBSF), that can both bend in the grasping axis and deflect in the side-to-side axis, achieving human-like motion (Figure 1). The functions of the HBSF and soft palm are evaluated both in simulation, using the Simulation Open Framework Architecture (SOFA) framework, and experimentally. Six finger designs with 1-11 longitudinal segments are analyzed. The versatility of the soft hand is evaluated and demonstrated experimentally by its grasping of objects according to Feix's taxonomy. The results demonstrate a great diversity of grasps, with 31 of the 33 grasp types of the taxonomy performed successfully with the proposed design, showing promise for grasping a large variety of objects with different shapes and weights.

Highlights

  • Date of current version: 14 April 2021 the grasping axis and deflect in the side-to-side axis, achieving human-like motion (Figure 1)

  • The functions of the hybrid-bending soft finger (HBSF) and soft palm are evaluated both in simulation, using the Simulation Open Framework Architecture (SOFA) framework, and experimentally

  • Dexterous grasping is a prerequisite for task-dependent manipulation, which requires the consideration of factors such as interaction forces, stiffness and compliance, dexterity, and the number of degrees of freedom (DoF) [1]

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Summary

Introduction

Date of current version: 14 April 2021 the grasping axis and deflect in the side-to-side axis, achieving human-like motion (Figure 1). Can soft robotic hands adapt to objects of various shapes and sizes, but they can achieve contact smoothly, without the need of sophisticated control as required by rigid hands. Their soft nature helps to minimize the damage to the manipulated objects. There are different designs and applications for soft robotic hands based on pneu-nets bending-actuator [5]–[8] and fiber-reinforced actuator prototypes [1], [9]–[12]. In this article, we discuss the design of a novel HBSF in which we integrate the inner-chamber network structure inspired by pneu-nets with the fiber-reinforcement method

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