Steerable Burrowing Robot: Design, Modeling and Experiments

2020 IEEE International Conference on Robotics and Automation (ICRA) Pub Date : 2020-05-01 DOI:10.1109/ICRA40945.2020.9196648

M. Barenboim, A. Degani

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引用次数: 7

Abstract

This paper investigates a burrowing robot that can maneuver and steer while being submerged in a granular medium. The robot locomotes using an internal vibro-impact mechanism and steers using a rotating bevel-tip head. We formulate and investigate a non-holonomic model for the steering mechanism and a hybrid dynamics model for the thrusting mechanism. We perform a numerical analysis of the dynamics of the robot's thrusting mechanism using a simplified, orientation and depth dependent model for the drag forces acting on the robot. We first show, in simulation, that by carefully tuning various control input parameters, the thrusting mechanism can drive the robot both forward and backward. We present several experiments designed to evaluate and verify the simulative results using a proof-of-concept robot. We show that different input amplitudes indeed affect the direction of motion, as suggested by the simulation. We further demonstrate the ability of the robot to perform a simple S-shaped trajectory. These experiments demonstrate the feasibility of the robot's design and fidelity of the model.

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操纵性挖洞机器人:设计、建模与实验

本文研究了一种能够在颗粒介质中进行机动和转向的挖洞机器人。机器人移动使用内部振动冲击机构和转向使用一个旋转的斜尖头。我们建立并研究了转向机构的非完整模型和推力机构的混合动力学模型。我们对机器人的推力机构的动力学进行了数值分析，使用了一个简化的、方向和深度相关的模型来描述作用在机器人上的阻力。我们首先在仿真中表明，通过仔细调整各种控制输入参数，推力机构可以驱动机器人向前和向后。我们提出了几个实验，旨在评估和验证使用概念验证机器人的模拟结果。我们表明，不同的输入幅度确实会影响运动方向，正如仿真所表明的那样。我们进一步展示了机器人执行简单s形轨迹的能力。这些实验证明了机器人设计的可行性和模型的保真性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2020 IEEE International Conference on Robotics and Automation (ICRA)

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