Design of Soft, Modular Appendages for a Bio-inspired Multi-Legged Terrestrial Robot

TL;DR

This paper presents a novel soft, modular, pneumatically driven appendage for a bio-inspired multi-legged robot, enabling effective locomotion and load transport in complex terrestrial and underwater environments.

Contribution

It introduces a simple, low-cost design method for soft, rigid, and hybrid appendages that enhance mobility in challenging terrains for bio-inspired robots.

Findings

Effective force generation in various environments

Successful underwater and terrestrial locomotion tests

Low-cost, adaptable design approach

Abstract

Soft robots have the ability to adapt to their environment, which makes them suitable for use in disaster areas and agricultural fields, where their mobility is constrained by complex terrain. One of the main challenges in developing soft terrestrial robots is that the robot must be soft enough to adapt to its environment, but also rigid enough to exert the required force on the ground to locomote. In this paper, we report a pneumatically driven, soft modular appendage made of silicone for a terrestrial robot capable of generating specific mechanical movement to locomote and transport loads in the desired direction. This two-segmented soft appendage uses actuation in between the joint and the lower segment of the appendage to ensure adequate rigidity to exert the required force to locomote. A prototype of a soft-rigid-bodied tethered physical robot was developed and two sets of experiments were carried out in both air and underwater environments to assess its performance. The experimental results address the effectiveness of the soft appendage to generate adequate force to navigate through various environments and our design method offers a simple, low-cost, and efficient way to develop terradynamically capable soft appendages that can be used in a variety of locomotion applications.