Proximal Actuation of an Elastically Loaded Scissors Mechanism for the Leg Design of a Quadruped Robot

Spring Loaded Pantographs (SLPs) are frequently used in designing lightweight limbs for multi-legged robots. Quadruped robots that incorporate cable-pulled SLP legs have proven to be agile, robust and capable of conserving energy during their gait cycle. In such designs, the extension of the distal...

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Bibliographic Details
Published in:IEEE access 2020, Vol.8, p.208240-208252
Main Authors: Nizami, Muhammad Hamza Asif, Shah, Zaid Ahsan, Ayaz, Yasar, Khan, Muhammad Jawad, Ali, Sara, Naveed, Muhammad, Akhtar, Khalid, Dancey, Darren, Nawaz, Raheel
Format: Article
Language:English
Subjects:
Actuation
Actuators
compliant mechanisms
Cutting tools
Design
elastically loaded scissors mechanism
Experimentation
Foot
Gait
Joints (anatomy)
Knee
leg mechanism
Legged locomotion
Loading
Motion capture
Pantographs
robot design
Robot kinematics
Robot locomotion
Robots
spring loaded pantograph
Springs
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Summary:Spring Loaded Pantographs (SLPs) are frequently used in designing lightweight limbs for multi-legged robots. Quadruped robots that incorporate cable-pulled SLP legs have proven to be agile, robust and capable of conserving energy during their gait cycle. In such designs, the extension of the distal segments via the knee joint is dependent upon the length of the cable. In this article we propose the use of an Elastically Loaded Scissors Mechanism (ELS Mechanism or ELSM), which is a variant of the SLP. Driven by 'pulling' onto the proximal joint of the scissors as opposed to the distal joint, this proposed leg utilizes the increased mechanical advantage of the scissors mechanism to 'amplify' input angles to larger output displacement by the knee joint. Analysis and Simulations reveal that the proposed mechanism achieves increased motion speed as compared to the SLP mechanism. This, however, comes at the cost of higher load on the actuator which serves as an engineering trade-off. This is validated by experimentation using motion capture and load motor techniques of the SLP and ELS configurations in a physical quadruped robot.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2020.3037250