Abstract
Prokaryotic flagellum is considered as the only known example of a biological “wheel,” a system capable of converting the action of rotatory actuator into a continuous propulsive force. For this reason, flagella are an interesting case study in soft robotics and they represent an appealing source of inspiration for the design of underwater robots. A great number of flagellum-inspired devices exists, but these are all characterized by a size ranging in the micrometer scale and mostly realized with rigid materials. Here, we present the design and development of a novel generation of macroscale underwater propellers that draw their inspiration from flagellated organisms. Through a simple rotatory actuation and exploiting the capability of the soft material to store energy when interacting with the surrounding fluid, the propellers attain different helical shapes that generate a propulsive thrust. A theoretical model is presented, accurately describing and predicting the kinematic and the propulsive capabilities of the proposed solution. Different experimental trials are presented to validate the accuracy of the model and to investigate the performance of the proposed design. Finally, an underwater robot prototype propelled by four flagellar modules is presented.
Highlights
R OBOTICS is pushing forward the boundary of exploration, aiming toward remote planets in space and deep waters within our oceans
The role of robotics is predominant with respect to human intervention in shallow water: longer operation times, resilience to atmospheric conditions, and reduced human risk are just a few among the many advantages that motivate the employment of robots over humans
To torsional strain, ensuring the transmission of the torque from the flagellar motor to the filament. These two features allow a high number of possible kinematics, which would not be possible with a flagellum made of an homogeneous structural material [21]
Summary
R OBOTICS is pushing forward the boundary of exploration, aiming toward remote planets in space and deep waters within our oceans. Remotely operated and unmanned underwater vehicles have been introduced to replace human divers in underwater operations with incomplete success While they have been successfully applied to safely patrol open stretches of sea, they still present severe limitations in manipulation, close structure monitoring, and locomotion within cluttered environments. A soft macroscale propeller inspired by prokaryotik flagella has been recently proposed in [14] In this previous work by the authors, the design of the prototype has been presented and a first set of trials has been conducted in a controlled environment to assess the propulsive thrust.
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