Soft Air Pocket Force Sensors for Large Scale Flexible Robots

TL;DR

This paper introduces a novel soft air pocket force sensor that is flexible, scalable, and cost-effective, enabling large-scale flexible robots to sense contact forces without hindering their shape-changing capabilities.

Contribution

The paper presents a new soft air pocket force sensor design that is highly flexible, lightweight, and scalable, suitable for large and complex soft robots.

Findings

Sensor's pressure change is linear with applied force

Sensor sensitivity is affected by contact location and area

Successful application on a vine robot demonstrating growth and steering

Abstract

Flexible robots have advantages over rigid robots in their ability to conform physically to their environment and to form a wide variety of shapes. Sensing the force applied by or to flexible robots is useful for both navigation and manipulation tasks, but it is challenging due to the need for the sensors to withstand the robots' shape change without encumbering their functionality. Also, for robots with long or large bodies, the number of sensors required to cover the entire surface area of the robot body can be prohibitive due to high cost and complexity. We present a novel soft air pocket force sensor that is highly flexible, lightweight, relatively inexpensive, and easily scalable to various sizes. Our sensor produces a change in internal pressure that is linear with the applied force. We present results of experimental testing of how uncontrollable factors (contact location and contact area) and controllable factors (initial internal pressure, thickness, size, and number of interior seals) affect the sensitivity. We demonstrate our sensor applied to a vine robot-a soft inflatable robot that "grows" from the tip via eversion-and we show that the robot can successfully grow and steer towards an object with which it senses contact.