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1. Origami-based earthworm-like locomotion robots

Author

Kon-Well Wang, Hongbin Fang, and Y. Zhang

Subjects

Paper, 0209 industrial biotechnology, Computer science, Biophysics, 02 engineering and technology, Models, Biological, Biochemistry, 020901 industrial engineering & automation, Biomimetics, Animals, Oligochaeta, Engineering (miscellaneous), Multistability, Simulation, Robot locomotion, business.industry, Robotics, Equipment Design, 021001 nanoscience & nanotechnology, Gait, Robot control, Scalability, Molecular Medicine, Robot, Artificial intelligence, 0210 nano-technology, business, Actuator, Biotechnology

Abstract

Inspired by the morphology characteristics of the earthworms and the excellent deformability of origami structures, this research creates a novel earthworm-like locomotion robot through exploiting the origami techniques. In this innovation, appropriate actuation mechanisms are incorporated with origami ball structures into the earthworm-like robot 'body', and the earthworm's locomotion mechanism is mimicked to develop a gait generator as the robot 'centralized controller'. The origami ball, which is a periodic repetition of waterbomb units, could output significant bidirectional (axial and radial) deformations in an antagonistic way similar to the earthworm's body segment. Such bidirectional deformability can be strategically programmed by designing the number of constituent units. Experiments also indicate that the origami ball possesses two outstanding mechanical properties that are beneficial to robot development: one is the structural multistability in the axil direction that could contribute to the robot control implementation; and the other is the structural compliance in the radial direction that would increase the robot robustness and applicability. To validate the origami-based innovation, this research designs and constructs three robot segments based on different axial actuators: DC-motor, shape-memory-alloy springs, and pneumatic balloon. Performance evaluations reveal their merits and limitations, and to prove the concept, the DC-motor actuation is selected for building a six-segment robot prototype. Learning from earthworms' fundamental locomotion mechanism-retrograde peristalsis wave, seven gaits are automatically generated; controlled by which, the robot could achieve effective locomotion with qualitatively different modes and a wide range of average speeds. The outcomes of this research could lead to the development of origami locomotion robots with low fabrication costs, high customizability, light weight, good scalability, and excellent re-configurability.

Published

2017