Tendon-Driven Crawling Robot with Programmable Anisotropic Friction by Adjusting Out-of-Plane Curvature

Abstract: Origami crawling robots, inspired by the principles of origami folding, have emerged as a promising approach for developing lightweight and flexible robots capable of navigating tight spaces. These robots utilize anisotropic friction, where the frictional forces between surfaces vary depending on the direction of motion, enabling controlled movement by changing the robot’s body orientation. While various actuation methods have been explored, such as pneumatic and magnetic systems, they suffer from limitations … Show more

“…Kresling origami, as a typical pattern of non-rigid origami and cylindrical bellows, demonstrates multiple stable states, tunable stiffness, and axial/twist coupling properties [1][2][3]. Due to its amazing mechanical behaviors, Kresling origami-inspired engineering structures also gain increasing attention, including soft robots [4][5][6], force-related mechanisms [7,8], and mechanical metamaterials [9][10][11]. For the analysis on motion behaviors of the Kresling origami, the main focus is on quasistatic modeling, including truss model and bar-hinge model [12,13].…”

Kresling origami derived structures and inspired mechanical metamaterial

“…Kresling origami, as a typical pattern of non-rigid origami and cylindrical bellows, demonstrates multiple stable states, tunable stiffness, and axial/twist coupling properties [1][2][3]. Due to its amazing mechanical behaviors, Kresling origami-inspired engineering structures also gain increasing attention, including soft robots [4][5][6], force-related mechanisms [7,8], and mechanical metamaterials [9][10][11]. For the analysis on motion behaviors of the Kresling origami, the main focus is on quasistatic modeling, including truss model and bar-hinge model [12,13].…”

Kresling origami derived structures and inspired mechanical metamaterial