Study of Self-Locking Structure Based on Surface Microstructure of Dung Beetle Leg Joint.

IF 3.4 3区 医学 Q1 ENGINEERING, MULTIDISCIPLINARY Biomimetics Pub Date : 2024-10-14 DOI:10.3390/biomimetics9100622
Dexin Sun, Sen Lin, Yubo Wang, Jiandong Cui, Zhiwei Tuo, Zhaohua Lin, Yunhong Liang, Luquan Ren
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Abstract

Dung beetle leg joints exhibit a remarkable capacity to support substantial loads, which is a capability significantly influenced by their surface microstructure. The exploration of biomimetic designs inspired by the surface microstructure of these joints holds potential for the development of efficient self-locking structures. However, there is a notable absence of research focused on the surface microstructure of dung beetle leg joints. In this study, we investigated the structural characteristics of the surface microstructures present in dung beetle leg joints, identifying the presence of fish-scale-like, brush-like, and spike-like microstructures on the tibia and femur. Utilizing these surface microstructural characteristics, we designed a self-locking structure that successfully demonstrated functionality in both the rotational direction of the structure and self-locking in the reverse direction. At a temperature of 20 °C, the biomimetic closure featuring a self-locking mechanism was capable of generating a self-locking force of 18 N. The bionic intelligent joint, characterized by its unique surface microstructure, presents significant potential applications in aerospace and various engineering domains, particularly as a critical component in folding mechanisms. This research offers innovative design concepts for folding mechanisms, such as those utilized in satellite solar panels and solar panels for asteroid probes.

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基于蜣螂腿关节表面微观结构的自锁结构研究
蜣螂腿关节具有承受巨大负荷的非凡能力,而这种能力在很大程度上受到其表面微结构的影响。从这些关节的表面微观结构中汲取灵感,探索生物仿生设计,有望开发出高效的自锁结构。然而,关于蜣螂腿关节表面微观结构的研究明显不足。在这项研究中,我们调查了蜣螂腿关节表面微结构的结构特征,确定了胫骨和股骨上存在的鱼鳞状、刷状和穗状微结构。利用这些表面微结构特征,我们设计出了一种自锁结构,成功地展示了该结构在旋转方向和反向自锁方向上的功能。在 20 °C 的温度下,具有自锁机制的仿生闭合结构能够产生 18 N 的自锁力。这种仿生智能关节以其独特的表面微结构为特征,具有在航空航天和各种工程领域应用的巨大潜力,尤其是作为折叠机制的关键部件。这项研究为折叠机构提供了创新的设计理念,例如卫星太阳能电池板和小行星探测器太阳能电池板中使用的折叠机构。
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来源期刊
Biomimetics
Biomimetics Biochemistry, Genetics and Molecular Biology-Biotechnology
CiteScore
3.50
自引率
11.10%
发文量
189
审稿时长
11 weeks
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