Reversible Adhesive Bio-Toe with Hierarchical Structure Inspired by Gecko

The agile locomotion of adhesive animals is mainly attributed to their sophisticated hierarchical feet and reversible adhesion motility. Their structure-function relationship is an urgent issue to be solved to understand biologic adhesive systems and the design of bionic applications. In this study,...

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Bibliographic Details
Published in:Biomimetics (Basel, Switzerland) Switzerland), 2023-01, Vol.8 (1), p.40
Main Authors: Wang, Liuwei, Wang, Zhouyi, Wang, Bingcheng, Yuan, Qingsong, Weng, Zhiyuan, Dai, Zhendong
Format: Article
Language:English
Subjects:
Abdomen
Adaptability
Adhesion
Adhesives
bio-toe
Biomimetics
Climbing
Deformation
Design and construction
Fault tolerance
Fingers & toes
Friction
gecko
Geckos
Geometry
hierarchical structure
Investigations
Lamellae
Locomotion
Mathematical models
Mechanical properties
Methods
Mobile robots
Physiological aspects
Pressure
reversible adhesion
Robots
Silicon wafers
Structure-function relationships
Toe
Toes
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Summary:The agile locomotion of adhesive animals is mainly attributed to their sophisticated hierarchical feet and reversible adhesion motility. Their structure-function relationship is an urgent issue to be solved to understand biologic adhesive systems and the design of bionic applications. In this study, the reversible adhesion/release behavior and structural properties of gecko toes were investigated, and a hierarchical adhesive bionic toe (bio-toe) consisting of an upper elastic actuator as the supporting/driving layer and lower bionic lamellae (bio-lamellae) as the adhesive layer was designed, which can adhere to and release from targets reversibly when driven by bi-directional pressure. A mathematical model of the nonlinear deformation and a finite element model of the adhesive contact of the bio-toe were developed. Meanwhile, combined with experimental tests, the effects of the structure and actuation on the adhesive behavior and mechanical properties of the bio-toe were investigated. The research found that (1) the bending curvature of the bio-toe, which is approximately linear with pressure, enables the bio-toe to adapt to a wide range of objects controllably; (2) the tabular bio-lamella could achieve a contact rate of 60% with a low squeeze contact of less than 0.5 N despite a ±10° tilt in contact posture; (3) the upward bending of the bio-toe under negative pressure provided sufficient rebounding force for a 100% success rate of release; (4) the ratio of shear adhesion force to preload of the bio-toe with tabular bio-lamellae reaches approximately 12, which is higher than that of most existing adhesion units and frictional gripping units. The bio-toe shows good adaptability, load capacity, and reversibility of adhesion when applied as the basic adhesive unit in a robot gripper and wall-climbing robot. Finally, the proposed reversible adhesive bio-toe with a hierarchical structure has great potential for application in space, defense, industry, and daily life.
ISSN:2313-7673
2313-7673
DOI:10.3390/biomimetics8010040