基于张拉整体结构的仿生手腕设计方法

IF 1.6 Q4 ENGINEERING, BIOMEDICAL Biosurface and Biotribology Pub Date : 2020-04-19 DOI:10.1049/bsbt.2019.0022
Jianwei Sun, Xuemin Cao, Guangsheng Song
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引用次数: 7

摘要

传统的仿生上肢结构设计受到运动副的限制,不能保证机械结构的灵活性。张拉整体结构具有变形性高、自适应性强、抗多向冲击等特点。根据人体上肢的生物学特性,对实现内收/外展、屈伸/外展的上肢腕关节进行解剖学研究,获得相关骨骼和肌肉的运动关系,简化腕关节的形状和结构。基于两杆拉伸性能的力学模型的等效映射。通过弹簧的收缩和拉伸,实现人体肌肉的运动特性,进一步得到优化后的无运动副的仿生上肢腕部张力机器人。通过Adams仿真验证了仿生拉伸手腕能够模拟人类手腕的变化运动。搭建了实验平台,制作了实物样机并对样机进行了测试。结果表明,仿生张力腕能较好、稳定地实现人体手腕的自适应运动特性,证明了该设计方法的有效性和可行性。
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Design method for a bionic wrist based on tensegrity structures

The traditional bionic upper limb structure design is limited by the motion pair and cannot guarantee the flexibility of the mechanical structure. The tensegrity structure has the characteristics of high deformability, strong self-adaptability, and resistance to multi-directional impact. According to the biological characteristics of the upper limbs of the human body, an anatomical study is performed on the upper limb wrist joints that achieve adduction/abduction, flexion/extension, to obtain the relationship between the movements of the related bones and muscles, and to simplify the shape and structure of the wrist. Equivalent mapping of a mechanical model based on two-bar tensile properties. Through the contraction and stretching of the spring, the movement characteristics of the human muscles are realised, and the optimised bionic upper limb wrist tensioning robot without motion pair is further obtained. Adams simulation is used to verify that the bionic tensile wrist can simulate the change movement of the human wrist. The experimental platform was built and a physical prototype was made and the prototype was tested. The results show that the bionic tensile wrist can realise the adaptive motion characteristics of the human wrist well and stably, which proves the validity and feasibility of this design method.

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来源期刊
Biosurface and Biotribology
Biosurface and Biotribology Engineering-Mechanical Engineering
CiteScore
1.70
自引率
0.00%
发文量
27
审稿时长
11 weeks
期刊最新文献
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