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Restoring Force Design of Active Self-healing Tension Transmission System and Application to Tendon-driven Legged Robot

Shinsuke Nakashima, Kento Kawaharazuka, Manabu Nishiura, Yuki Asano, Yohei Kakiuchi, Kei Okada, Koji Kawasaki, Masayuki Inaba

Year
2021
Citations
3

Abstract

Self-healing function is a promising approach for damage management of high-load robot applications such as legged robots. Although the function is getting major in soft robotics, its application to life-sized "stiff" robots is of relatively minor interest. Although the authors have devised several self-healing tensile modules for tendon-driven robots, the design guideline to satisfy the large load endurance and large stroke is still unclear. The paper focuses on the parametric design for unleaked liquid-assisted healing of low melting point alloy structure. The method was validated with a benchtop module test. Moreover, the module enabled tendon-driven monopod testbed to perform squat motion three times after the landing impact fracture and the self-healing sequence, which was never accomplished.

Keywords

TestbedRobotComputer scienceSelf-healingTendonSquatSimulationEngineeringArtificial intelligencePhysical medicine and rehabilitation

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