阿尔法:用于社交类人机器人的混合自适应手

2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) Pub Date : 2016-10-09 DOI:10.1109/IROS.2016.7759157

Giulio Cerruti, D. Chablat, D. Gouaillier, S. Sakka

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引用次数: 13

摘要

本文提出了一种用于社交类人机器人的结构紧凑、重量轻的机械手。该系统通过在独特的设计中混合欠驱动和自适应的手部运动学，能够执行常见的手势和自适应抓取。这只手满足了在手势过程中对精确手指姿势和无传感器力反馈的需求，以及在抓取过程中对手指的适应和自主力分配的需求。这些是由手掌和手指内的双重驱动系统提供的。由于弹性体杆在减小尺寸和应变时具有较高的弹性系数，因此基于弹性体杆而不是传统的张力弹簧的柔性传动确保了共存。提出的解决方案通过使用减少数量的小致动器进行手势和单个电机进行抓取，显着减少了手的重量和尺寸。实现了手样机(ALPHA)，验证了设计的可行性和功能。控制它是为了提供安全的人机交互和保持机械完整性，以体现在人形机器人。

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ALPHA: A hybrid self-adaptable hand for a social humanoid robot

This paper presents a novel design of a compact and light-weight robotic hand for a social humanoid robot. The proposed system is able to perform common hand gestures and self-adaptable grasps by mixing under-actuated and self-adaptable hand kinematics in a unique design. The hand answers the need for precise finger postures and sensor-less force feedback during gestures and for finger adaptation and autonomous force distribution during grasps. These are provided by a dual actuation system embodied within the palm and the fingers. Coexistence is ensured by compliant transmissions based on elastomer bars rather than classical tension springs, thanks to their high elastic coefficient at reduced sizes and strains. The proposed solution significantly reduces the weight and the size of the hand by using a reduced number of small actuators for gesturing and a single motor for grasping. The hand prototype (ALPHA) is realized to confirm the design feasibility and functional capabilities. It is controlled to provide safe human-robot interaction and preserve mechanical integrity in order to be embodied on a humanoid robot.

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来源期刊

2016 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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