Locomotion control of a rigid-soft coupled snake robot in multiple environments

Biomimetic Intelligence and Robotics Pub Date : 2024-02-25 DOI:10.1016/j.birob.2024.100148

Xuanyi Zhou , Yuqiu Zhang , Zhiwei Qiu , Zhecheng Shan , Shibo Cai , Guanjun Bao

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引用次数: 0

Abstract

The versatile motion capability of snake robots offers themselves robust adaptability in varieties of challenging environments where traditional robots may be incapacitated. This study reports a novel flexible snake robot featuring a rigid–flexible coupling structure and multiple motion gaits. To better understand the robot’s behavior, a bending model for the soft actuator is established. Furthermore, a dynamic model is developed to map the relationship between the input air pressure and joint torque, which is the model base for controlling the robot effectively. Based on the wave motion generated by the joint coupling direction function in different planes, multiple motion gait planning methods of the snake-like robot are proposed. In order to evaluate the adaptability and maneuverability of the developed snake robot, extensive experiments were conducted in complex environments. The results demonstrate the robot’s effectiveness in navigating through intricate settings, underscoring its potential for applications in various fields.

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多环境下刚柔耦合蛇形机器人的运动控制

蛇形机器人具有多种运动能力，可在各种具有挑战性的环境中发挥强大的适应能力，而传统的机器人可能无法胜任这些环境。本研究报告介绍了一种新型柔性蛇形机器人，它具有刚柔耦合结构和多种运动步态。为了更好地理解机器人的行为，我们建立了软致动器的弯曲模型。此外，还建立了一个动态模型，以映射输入气压与关节扭矩之间的关系，这也是有效控制机器人的模型基础。根据关节耦合方向函数在不同平面上产生的波浪运动，提出了蛇形机器人的多种运动步态规划方法。为了评估所开发的蛇形机器人的适应性和可操作性，在复杂环境中进行了大量实验。实验结果表明，蛇形机器人能在复杂的环境中有效穿行，突出了其在各个领域的应用潜力。

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来源期刊

Biomimetic Intelligence and Robotics

CiteScore

1.80

自引率

0.00%

发文量