Title :
Pop-up assembly of a quadrupedal ambulatory MicroRobot
Author :
Baisch, Andrew T. ; Wood, Robert J.
Author_Institution :
Sch. of Eng. & Appl. Sci., Harvard Univ., Cambridge, MA, USA
Abstract :
Here we present the design of a 1.27g quadrupedal microrobot manufactured using “Pop-up book MEMS” the first such device capable of locomotion. Implementing popup assembly techniques enables manufacturing of the robot´s exoskeleton and drivetrain transmissions from a single 23-layer laminate. Its demonstrated capabilities include payload capacity greater than 1.35g (106% of body mass), maneuverability on flat terrain, and high-speed locomotion up to 37cm/s. Additionally, locomotion performance is compared to a hand-assembled quadruped with similar design parameters. The results demonstrate that the pop-up manufacturing methodology enables more complex mechanisms while simultaneously increasing performance over hand-assembled alternatives.
Keywords :
control system synthesis; legged locomotion; microassembling; microrobots; motion control; power transmission (mechanical); robot dynamics; 1.27g quadrupedal microrobot; complex mechanisms; design parameters; drivetrain transmissions; flat terrain maneuverability; hand-assembled quadruped; high-speed locomotion; payload capacity; pop-up assembly techniques; pop-up book MEMS; pop-up manufacturing methodology; quadrupedal ambulatory microrobot; robot exoskeleton; Assembly; Couplings; Heat-assisted magnetic recording; Laminates; Legged locomotion;
Conference_Titel :
Intelligent Robots and Systems (IROS), 2013 IEEE/RSJ International Conference on
Conference_Location :
Tokyo
DOI :
10.1109/IROS.2013.6696550
