Title :
Flea-Inspired Catapult Mechanism for Miniature Jumping Robots
Author :
Noh, Minkyun ; Kim, Seung-Won ; An, Sungmin ; Koh, Je-Sung ; Cho, Kyu-Jin
Author_Institution :
Sch. of Mech. & Aerosp. Eng., Seoul Nat. Univ., Seoul, South Korea
Abstract :
Fleas can jump more than 200 times their body length. They do so by employing a unique catapult mechanism: storing a large amount of elastic energy and releasing it quickly by torque reversal triggering. This paper presents a flea-inspired catapult mechanism for miniature jumping robots. A robotic design was created to realize the mechanism for the biological catapult with shape memory alloy (SMA) spring actuators and a smart composite microstructure. SMA spring actuators replace conventional actuators, transmissions, and the elastic element to reduce the size. The body uses a four-bar mechanism that simulates a flea´s leg kinematics with reduced degrees of freedom. Dynamic modeling was derived, and theoretical jumping was simulated to optimize the leg design for increased takeoff speed. A robotic prototype was fabricated with 1.1-g weight and 2-cm body size that can jump a distance of up to 30 times its body size.
Keywords :
actuators; microrobots; mobile robots; robot dynamics; robot kinematics; shape memory effects; springs (mechanical); SMA; biological catapult; degrees of freedom reduction; dynamic modeling; elastic energy; flea leg kinematics; flea-inspired catapult mechanism; four-bar mechanism; miniature jumping robots; mobile robots; robotic design; shape memory alloy spring actuators; size 2 cm; smart composite microstructure; torque reversal triggering; Actuators; Coils; DC motors; Muscles; Robots; Springs; Torque; Biologically inspired robot; biomimetics; catapult mechanism; flea robot; jumping robot; microrobot; shape memory alloy (SMA) spring; smart composite microstructure (SCM);
Journal_Title :
Robotics, IEEE Transactions on
DOI :
10.1109/TRO.2012.2198510
