Path planning and intelligent control of a soft robot arm based on gas-structure coupling actuators

Xu, Yan; Li, Hongwei; Li, Hua; Fang, Guanhui; He, Jie

doi:10.3389/fmats.2022.1052538

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Cited by 3 publications

References 20 publications

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Mitigate Inertia for Wrist and Forearm Towards Safe Interaction in 5-DOF Cable-Driven Robot Arm

Nguyen,

Bohra Dhyan,

Hoang

et al. 2023

2023 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM)

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Mitigate Inertia for Wrist and Forearm Towards Safe Interaction in 5-DOF Cable-Driven Robot Arm

Nguyen,

Bohra Dhyan,

Hoang

et al. 2023

2023 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM)

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SPONGE: Open-Source Designs of Modular Articulated Soft Robots

Habich,

Haack,

Belhadj

et al. 2024

IEEE Robot. Autom. Lett.

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Low-Cost Cable-Driven Robot Arm with Low-Inertia Movement and Long-Term Cable Durability

Nguyen,

Chow,

Dhyan

et al. 2024

Robotics

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Our study presents a novel design for a cable-driven robotic arm, emphasizing low cost, low inertia movement, and long-term cable durability. The robotic arm shares similar specifications with the UR5 robotic arm, featuring a total of six degrees of freedom (DOF) distributed in a 1:1:1:3 ratio at the arm base, shoulder, elbow, and wrist, respectively. The three DOF at the wrist joints are driven by a cable system, with heavy motors relocated from the end-effector to the shoulder base. This repositioning results in a lighter cable-actuated wrist (weighing 0.8 kg), which enhances safety during human interaction and reduces the torque requirements for the elbow and shoulder motors. Consequently, the overall cost and weight of the robotic arm are reduced, achieving a payload-to-body weight ratio of 5:8.4 kg. To ensure good positional repeatability, the shoulder and elbow joints, which influence longer moment arms, are designed with a direct-drive structure. To evaluate the design’s performance, tests were conducted on loading capability, cable durability, position repeatability, and manipulation. The tests demonstrated that the arm could manipulate a 5 kg payload with a positional repeatability error of less than 0.1 mm. Additionally, a novel cable tightener design was introduced, which served dual functions: conveniently tightening the cable and reducing the high-stress concentration near the cable locking end to minimize cable loosening. When subjected to an initial cable tension of 100 kg, this design retained approximately 80% of the load after 10 years at a room temperature of 24 °C.

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Path planning and intelligent control of a soft robot arm based on gas-structure coupling actuators

Cited by 3 publications

References 20 publications

Mitigate Inertia for Wrist and Forearm Towards Safe Interaction in 5-DOF Cable-Driven Robot Arm

Mitigate Inertia for Wrist and Forearm Towards Safe Interaction in 5-DOF Cable-Driven Robot Arm

SPONGE: Open-Source Designs of Modular Articulated Soft Robots

Low-Cost Cable-Driven Robot Arm with Low-Inertia Movement and Long-Term Cable Durability

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