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用于机器人应用的基于离子溶液的软传感运动系统。

Soft Sensory-Motor System Based on Ionic Solution for Robotic Applications.

作者信息

Santos Sender Rocha Dos, Rohmer Eric

机构信息

DCA-FEEC-UNICAMP, Sao Paulo 13083-852, Brazil.

出版信息

Sensors (Basel). 2024 May 1;24(9):2900. doi: 10.3390/s24092900.

DOI:10.3390/s24092900
PMID:38733007
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11086320/
Abstract

Soft robots claim the architecture of actuators, sensors, and computation demands with their soft bodies by obtaining fast responses and adapting to the environment. Sensory-motor coordination is one of the main design principles utilized for soft robots because it allows the capability to sense and actuate mutually in the environment, thereby achieving rapid response performance. This work intends to study the response for a system that presents coupled actuation and sensing functions simultaneously and is integrated in an arbitrary elastic structure with ionic conduction elements, called as soft sensory-motor system based on ionic solution (SSMS-IS). This study provides a comparative analysis of the performance of SSMS-IS prototypes with three diverse designs: toroidal, semi-toroidal, and rectangular geometries, based on a series of performance experiments, such as sensitivity, drift, and durability. The design with the best performance was the rectangular SSMS-IS using silicon rubber RPRO20 for both internal and external pressures applied in the system. Moreover, this work explores the performance of a bioinspired soft robot using rectangular SSMS-IS elements integrated in its body. Further, it investigated the feasibility of the robot to adapt its morphology online for environment variability, responding to external stimuli from the environment with different levels of stiffness and damping.

摘要

软体机器人通过其柔软的身体来满足执行器、传感器和计算方面的架构要求,从而实现快速响应并适应环境。传感-运动协调是软体机器人所采用的主要设计原则之一,因为它使机器人能够在环境中相互感知和驱动,从而实现快速响应性能。这项工作旨在研究一种同时具备耦合驱动和传感功能的系统的响应,该系统集成在带有离子传导元件的任意弹性结构中,被称为基于离子溶液的软传感-运动系统(SSMS-IS)。本研究基于一系列性能实验,如灵敏度、漂移和耐久性,对具有三种不同设计(环形、半环形和矩形几何形状)的SSMS-IS原型的性能进行了对比分析。性能最佳的设计是在系统施加的内部和外部压力下均使用硅橡胶RPRO20的矩形SSMS-IS。此外,这项工作还探索了一种将矩形SSMS-IS元件集成在其身体中的仿生软体机器人的性能。此外,研究了该机器人在线调整其形态以适应环境变化的可行性,即对来自环境的具有不同刚度和阻尼水平的外部刺激做出响应。

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