Deployable Soft Origami Modular Robotic Arm With Variable Stiffness Using Facet Buckling

Robots that share activity spaces or physically interact with humans typically benefit from appropriate payload capacity, extensible workspace, low weight, safety, and space efficiency. The soft origami design and mechanism can meet many of these beneficial factors; however, achieving a high payload...

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Bibliographic Details
Published inIEEE robotics and automation letters Vol. 8; no. 2; pp. 864 - 871
Main Authors Park, MinJo, Kim, Woongbae, Yu, Sung-Yol, Cho, Jungmin, Kang, Wonkyeong, Byun, Junghwan, Jeong, Useok, Cho, Kyu-Jin
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 01.02.2023
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Bending
Buckling
Efficiency
Electron tubes
Fabrication
Manipulators
Mathematical analysis
Modular design
Modular structures
Modules
Origami
Robot arms
Robotics
Robots
Sewing
soft robot applications
soft robot materials and design
Soft robotics
Stiffness
Tendons
variable stiffness
Weight
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Summary:Robots that share activity spaces or physically interact with humans typically benefit from appropriate payload capacity, extensible workspace, low weight, safety, and space efficiency. The soft origami design and mechanism can meet many of these beneficial factors; however, achieving a high payload capacity remains challenging. In this letter, we developed a soft origami arm module with high variable stiffness (x300) and spatial efficiency (compressed x3.1). The buckling of facets into a cylindrical tube followed by its pressurization enables the arm to be highly stiffened. High-pressure capacity was obtained via the sewing-heat press fabrication process. We used a pneumatic pressure-tendon pair and utilized the frictional force between origami and tendon to prevent unintentional gravity-induced deformation while deploying. An analytical model was developed and compared to the experimental results. With our modular design, we could easily build functional robotic structures. Two robotic demonstrations were performed to examine the expandability of the modules. A variable-length robotic arm that mimics a human arm was built to manipulate typical objects. Additionally, a soft rover, which could carry 14 kg of weight and change its volume 29 times for improved spatial efficiency, was developed. This research suggests a new design methodology for practical soft robotic systems.
ISSN:2377-3766
2377-3766
DOI:10.1109/LRA.2022.3232267