In Situ Reconfiguration of Assembling Pattern for Modular Continuum Robots

Abstract

Modular continuum robots possess significant versatility across various scenarios; however, conventional assembling methods typically rely on linear connection between modules. This limitation can impede the robotic interaction capabilities, especially in specific engineering applications. Herein, inspired by the assembling pattern between the femur and tibia in a human knee, we proposed a multidirectional assembling strategy. This strategy encompasses linear, oblique, and orthogonal connections, allowing a two-module continuum robot to undergo in-situ reconfiguration into three distinct initial configurations. To anticipate the final configuration resulting from diverse assembling patterns, we employed the positional formulation finite element framework to establish a mechanical model, and the theoretical results reveal that our customizable strategy can offer an effective route for robotic interactions. We showcased diverse assembling patterns for coping with interaction requirements. The experimental results indicate that our modular continuum robot not only reconfigures its initial profile in situ but also enables on-demand regulation of the final configuration. These capabilities provide a foundation for the future development of modular continuum robots, enabling them to be adaptable to diverse environments, particularly in unstructured surroundings.