Novel Smart and Compliant Robotic Gripper: Design, Modelling, Experiments and Control

IEEE EUROCON 2019 -18th International Conference on Smart Technologies Pub Date : 2019-07-01 DOI:10.1109/EUROCON.2019.8861561

A. Milojevic, Miša Tomić, H. Handroos, Ž. Ćojbašić

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引用次数: 3

Abstract

This paper presents a further investigation of a novel adaptive soft robotic gripper with integrated active elements, i.e. sensors and actuators. In many contemporary robotic applications, there is a great need to grasp differently shaped and sized objects as well as objects of different stiffness or soft objects. Grippers based on classical rigid-body mechanisms cannot safely manipulate with such a wide variety of objects, as they are stiff and not adaptive. Adaptive gripper proposed here is based on elastic active compliant mechanisms. Via integrated sensors, and actuators active smart gripper changes the shape of its grasping surface and adapts to the object of unknown shape. Concept of a two-finger gripper and a functional prototype of one gripper finger are presented. Sensors are formed by using conductive graphite foam. The machine learning models of tactile foam sensors are presented. Actuators are formed by using a shape memory alloy wire nitinol. It is demonstrated that developed soft gripper concept with integrated active elements can realize multiple grasping patterns. Many potential applications in robotics are foreseen for the novel smart adaptive gripper.

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新型智能柔顺机械手:设计、建模、实验与控制

本文进一步研究了一种新型的自适应柔性机器人夹持器，它具有集成的主动元件，即传感器和执行器。在现代机器人的许多应用中，都需要抓取不同形状和大小的物体，以及不同刚度的物体或软物体。基于经典刚体机构的抓取器由于其僵硬性和不适应性，不能安全地操作如此多种类的物体。本文提出了一种基于弹性主动柔性机构的自适应夹持器。主动智能抓取器通过集成传感器和执行器来改变其抓取面形状并适应未知形状的物体。提出了两指夹持器的概念和单指夹持器的功能原型。传感器由导电石墨泡沫制成。提出了触觉泡沫传感器的机器学习模型。执行器由形状记忆合金丝镍钛诺制成。研究表明，所提出的集成主动元件的软抓取器概念可以实现多种抓取模式。这种新型智能自适应夹持器在机器人领域有许多潜在的应用前景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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IEEE EUROCON 2019 -18th International Conference on Smart Technologies

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