Robot joint module based on universal joint configuration driven by SMA wires

Wang, Bao-Hua; Pei, Yong-Chen; Wu, Ji-Tuo; Guan, Jing-Han; Sui, Wen-Chao; Wang, Lu-Lu; Liu, Zhong-Hao

doi:10.1177/09544062231189704

Proceedings of the Institution of Mechanical Engineers, Part C:

2023

DOI: 10.1177/09544062231189704

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Robot joint module based on universal joint configuration driven by SMA wires

Bao-Hua Wang,

Yong-Chen Pei,

Ji-Tuo Wu

et al.

Abstract: Modular robots can adapt to different production needs and working conditions. However, the complexity of structures and the choice of driving modes limit the development of modularization. In this paper, a robot joint module with a universal joint configuration driven by shape memory alloy (SMA) wires is proposed, which has 2-DOFs. For lightweight, the main body of the module is made of polylactic acid materials. SMA wires are used as the actuator due to the advantages of large output displacement, high mass-… Show more

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2024

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A Novel Shape Memory Alloy Modular Robot with Spatially Stable Structure

Xiao,

Wang,

Chen

2024

Advanced Intelligent Systems

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Soft robots exhibit significant flexibility but normally lack stability owing to their inherent low stiffness. Current solutions for achieving variable stiffness or implementing lock mechanisms tend to involve complex structures. Additionally, passive solutions like bistable and multistate mechanisms lack spatial stable characteristics. This study presents a novel shape memory alloy (SMA) modular robot with spatially stable structure, by utilizing gooseneck as the backbone. This is the first time that a concept of spatially stable structure is proposed. When the power is off, the robot can still maintain its current posture in three‐dimensional space and resist external disturbance. The SMA spring and gooseneck are characterized, elucidating the mechanism behind achieving spatial stability. Then, a controller based on the inverse kinematics is designed, and validated by experiments. The results demonstrate the structural stability of the robot. Specifically, it can withstand a maximum external force of 2.5 N (0.0875 Nm) when bent at an angle of 20° without consuming energy. Moreover, with the assistance of the SMA spring, this resistance capacity surpasses 5 N (0.175 Nm).

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A Novel Shape Memory Alloy Modular Robot with Spatially Stable Structure

Xiao,

Wang,

Chen

2024

Advanced Intelligent Systems

View full text Add to dashboard Cite

show abstract

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Robot joint module based on universal joint configuration driven by SMA wires

Cited by 1 publication

References 44 publications

A Novel Shape Memory Alloy Modular Robot with Spatially Stable Structure

A Novel Shape Memory Alloy Modular Robot with Spatially Stable Structure

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