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The Chain-Link Actuator: Exploiting the Bending Stiffness of McKibben Artificial Muscles to Achieve Larger Contraction Ratios

Daniel Bruder, Robert J. Wood

2021IEEE Robotics and Automation Letters21 citationsDOI

Abstract

McKibben artificial muscles, comprised of an expandable bladder wrapped in a double-helix-braided sheath, have the ability to generate forces without restricting motion to occur exclusively along the direction of actuation. This makes them attractive for a variety of applications including soft, wearable, and biomimetic robots. Despite their advantages, the theoretical maximum contraction ratio of McKibben muscles is only 36.3%, which restricts the range of motion of the systems they actuate. This work introduces a novel ‘chain-link actuator’ that exploits the bending stiffness of McKibben muscles to achieve contraction ratios of more than 50%. A static model that captures the relationship between pressure, displacement, and force is presented and validated on several real chain-link actuator systems.

Topics & Concepts

ActuatorArtificial muscleContraction (grammar)Link (geometry)StiffnessBendingBending stiffnessControl theory (sociology)Structural engineeringMaterials scienceComputer scienceEngineeringArtificial intelligenceMedicineInternal medicineControl (management)Computer networkProsthetics and Rehabilitation RoboticsSoft Robotics and ApplicationsMuscle activation and electromyography studies
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