Characterization of motion power loss of off-road wheeled robot in a slippery terrain

IF 4.2 2区 计算机科学 Q2 ROBOTICS Journal of Field Robotics Pub Date : 2022-09-07 DOI:10.1002/rob.22116
Seyed Mojtaba Shafaei, Hossein Mousazadeh
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引用次数: 4

Abstract

For the first time in realm of power study of off-road wheeled robots, this study deals with motion power loss due to slippage of robot wheels traversed on slippery terrain. For this purpose, effects of slippery terrain type (solid balls with diameter of 0.0127, 0.0254, and 0.0508 m), tire air pressure (20.68, 34.47, and 55.16 kPa), and robot forward speed (0.17, 0.33, and 0.5 m/s) on the power loss were characterized. Derived results proved that the increasing effect of slippery terrain type on the power loss was dominant (1.08 and 3.21 times) than that of robot forward speed and tire air pressure, respectively. Meanwhile, the increasing effect of robot forward speed on the power loss was prevailed (2.98 times) than that of tire air pressure. Hence, to minimize the power loss of the robot traversed on each type of slippery terrain, adjustment of robot forward speed should be considered as first priority. A comparison between motion power loss (43.60–249.40 W) and provided motion power for the robot (136–436.37 W) implies that 12.93–75.44% of provided motion power was wasted by slippage of the robot wheels on slippery terrains. Overall, the analytical results obtained in this study lead to open a new prospection for comprehending of the power loss trends of off-road wheeled robots traversed on slippery terrains. As slippery terrain composed of solid balls, the results can be especially utilized for final phase of unloading robotic operations of catalyst handling procedure in process towers and reactors of oil, gas, petrochemical, and chemical industries.

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滑地条件下轮式越野机器人运动功率损失特性研究
本文首次在越野轮式机器人动力研究领域,研究了轮式机器人车轮在湿滑路面上行驶时由于轮滑引起的运动功率损失。为此,研究了湿滑地形类型(直径分别为0.0127、0.0254和0.0508 m的实心球)、轮胎气压(20.68、34.47和55.16 kPa)和机器人前进速度(0.17、0.33和0.5 m/s)对动力损失的影响。推导结果表明,湿滑地形类型对动力损失的增加作用占主导地位,分别是机器人前进速度和轮胎气压的1.08倍和3.21倍。同时,机器人前进速度对动力损失的影响大于轮胎气压对动力损失的影响(2.98倍)。因此,为了使机器人在各种湿滑地形上行走时的功率损失最小,应首先考虑机器人前进速度的调整。通过对比运动功率损耗(43.60 ~ 249.40 W)和机器人提供的运动功率(136 ~ 436.37 W)可知,机器人提供的运动功率中有12.93 ~ 75.44%是由于车轮在湿滑地形上的滑动而浪费的。总的来说,本研究的分析结果为理解轮式越野机器人在湿滑地形上的动力损失趋势开辟了新的前景。由于滑溜溜的地面是由固体球组成的,因此该结果特别适用于石油、天然气、石化和化学工业的工艺塔和反应器中催化剂处理过程的最后阶段卸载机器人操作。
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来源期刊
Journal of Field Robotics
Journal of Field Robotics 工程技术-机器人学
CiteScore
15.00
自引率
3.60%
发文量
80
审稿时长
6 months
期刊介绍: The Journal of Field Robotics seeks to promote scholarly publications dealing with the fundamentals of robotics in unstructured and dynamic environments. The Journal focuses on experimental robotics and encourages publication of work that has both theoretical and practical significance.
期刊最新文献
Issue Information Cover Image, Volume 41, Number 8, December 2024 Issue Information Issue Information A CIELAB fusion-based generative adversarial network for reliable sand–dust removal in open-pit mines
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