多角度腔体双向软推杆的设计与应用

Yehao Wen, Chang Chen, Zhengnan Lyu, Yuandong Liang, Zhongyu Zhang
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引用次数: 0

摘要

目的 本研究旨在推出一种新型双向软致动器,作为传统气动网络致动器的改进。设计/方法/途径该设计方法在致动器的末端集成了与水平方向成 45° 角的气室,以及成 90° 角的附加气室。根据片状恒定曲率假设,为纵向和横向弯曲以及斜向连接的腔体建立了数学模型。分析了横向和纵向末端的输出力、弯曲特性和末端接触面积。研究结果由于在末端包含一个对角气腔和一个横向气动网络结构,拟议的软推杆在抓取面积上超过了传统的气动网络推杆。因此,它能在两个方向上提供扭力和抓取力。通过多角度腔体的设计,软致动器表现出多种驱动角度和形态变化,为工业抓取提供了创新的设计视角。社会意义多角度腔体的设计为研究人员个性化配置软致动器提供了便利,使其能够针对特定的交互环境量身定制角度,从而实现所需的功能。这种方法为软致动器的设计提供了新的见解,解决了更普遍的工业抓取难题。原创性/价值本研究介绍了一种新型软致动器设计,与传统的气动网络致动器相比,它能显著增强抓取能力。结合特定的气室配置和数学建模,为开发适用于工业和家庭应用的适应性强且高效的机器人抓手提供了宝贵的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design and application of bidirectional soft actuator with multiangle chambers

Purpose

This study aims to introduce a novel bidirectional soft actuator as an enhancement to conventional pneumatic network actuators. This improvement involves integrating air chambers positioned at specific angles to improve stability, adaptability and grasping efficiency in various environments.

Design/methodology/approach

The design approach incorporates air chambers positioned at a 45° angle relative to the horizontal direction at the actuator's terminus, along with additional chambers at a 90° angle. Mathematical models are developed for longitudinal and transverse bending, as well as for obliquely connected cavities, based on the assumption of piecewise constant curvature. Analyses are conducted on output forces, bending characteristics and end contact areas for both transverse and longitudinal ends.

Findings

The proposed soft actuator surpasses traditional pneumatic network actuators in gripping area due to the inclusion of a diagonal air cavity and a transverse pneumatic network structure at the terminus. As a result, it provides torsion and gripping force in both directions. Testing on a dedicated platform with two variants of grippers demonstrates superior gripping force capability and performance in complex environments.

Practical implications

Through the design of multiangle chambers, the soft actuator exhibits diverse driving angles and morphological variations, offering innovative design perspectives for industrial grasping.

Social implications

The design of multiangle chambers facilitates personalized configurations of soft actuators by researchers, enabling tailored angles for specific interaction environments to achieve desired functionalities. This approach offers novel insights into soft actuator design, addressing more prevalent industrial grasping challenges.

Originality/value

This study introduces a novel soft actuator design that significantly enhances gripping capabilities in comparison to conventional pneumatic network actuators. The incorporation of specific air chamber configurations and mathematical modeling provides valuable insights for the development of adaptable and efficient robotic grippers for industrial and household applications.

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