单电机驱动(4 + 2)翼机器人抓手可在极度狭窄的环境中扩展工作空间

IF 4.6 2区 计算机科学 Q2 ROBOTICS IEEE Robotics and Automation Letters Pub Date : 2024-11-13 DOI:10.1109/LRA.2024.3497753
Toshihiro Nishimura;Keisuke Akasaka;Subaru Ishikawa;Tetsuyou Watanabe
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引用次数: 0

摘要

这封信提出了一种新颖的机器人抓手,它可以在目标环境中扩大可工作空间,从狭窄的空间中拾取物体。建议的机械手对于从可变形的环境中取回物体最为有效,例如从拉绳袋中取出物体,或提取位于周围物体后面的目标物体。拟议的机械手只需使用一个电机就能实现工作空间扩展和抓取运动。该机械手配备了四个用于扩展环境的外手指和两个用于抓取物体的内手指。内手指和外手指向不同方向运动,分别实现抓取和空间扩展功能。为了实现手指的两种不同运动,开发了一种新型的自运动切换机构,可在进给螺杆和齿轮齿条机构的功能之间进行切换。该机构根据施加在内侧手指上的力的大小来切换运动。这封信介绍了所开发的机械手的机构设计,包括自运动切换机构和扩大工作空间的驱动策略。此外,还介绍了机械分析,并通过实验验证了分析结果。此外,还利用所开发的机械手构建了一个自动拾取物体系统,以对机械手进行评估。
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Single-Motor-Driven (4 + 2)-Fingered Robotic Gripper Capable of Expanding the Workable Space in the Extremely Confined Environment
This letter proposes a novel robotic gripper that can expand workable spaces in a target environment to pick up objects from confined spaces. The proposed gripper is most effective for retrieving objects from deformable environments, such as taking an object out of a drawstring bag, or for extracting target objects located behind surrounding objects. The proposed gripper achieves both work-space expansion and grasping motion by using only a single motor. The gripper is equipped with four outer fingers for expanding the environment and two inner fingers for grasping an object. The inner and outer fingers move in different directions for their respective functions of grasping and spatial expansion. To realize two different movements of the fingers, a novel self-motion switching mechanism that switches between the functions as feed-screw and rack-and-pinion mechanisms is developed. The mechanism switches the motions according to the magnitude of the force applied to the inner fingers. This letter presents the mechanism design of the developed gripper, including the self-motion switching mechanism and the actuation strategy for expanding the workable space. The mechanical analysis is also presented, and the analysis result is validated experimentally. Moreover, an automatic object-picking system using the developed gripper is constructed to evaluate the gripper.
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来源期刊
IEEE Robotics and Automation Letters
IEEE Robotics and Automation Letters Computer Science-Computer Science Applications
CiteScore
9.60
自引率
15.40%
发文量
1428
期刊介绍: The scope of this journal is to publish peer-reviewed articles that provide a timely and concise account of innovative research ideas and application results, reporting significant theoretical findings and application case studies in areas of robotics and automation.
期刊最新文献
Integrated Grasping Controller Leveraging Optical Proximity Sensors for Simultaneous Contact, Impact Reduction, and Force Control Single-Motor-Driven (4 + 2)-Fingered Robotic Gripper Capable of Expanding the Workable Space in the Extremely Confined Environment CMGFA: A BEV Segmentation Model Based on Cross-Modal Group-Mix Attention Feature Aggregator Visual-Inertial Localization Leveraging Skylight Polarization Pattern Constraints Demonstration Data-Driven Parameter Adjustment for Trajectory Planning in Highly Constrained Environments
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