C. Jung, W. Chung, J. Ahn, Myung Sik Kim, Gi Soo Shin, Soon Jea Kwon
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The proposed in-pipe cleaning robot for GACF can have forward/backward movement itself as well as rotation of brush in cleaning. The robot body should have the limited size suitable for the smaller pipe with diameter of 300mm. In addition, for the pipe with diameter of 400mm, the links of robot should stretch to fit into the diameter of the pipe by using the sliding mechanism. Based on the conceptual design using TRIZ, we will set up the initial design of the robot in collaboration with a field engineer of Robot Valley, Inc. in Korea. For the optimal design of in-pipe cleaning robot, the maximum impulsive force of collision between the robot and the inner face of pipe is simulated by using RecurDyn® when the link of sliding mechanism is stretched to fit into the 400mm diameter of the pipe. The stresses exerted on the 6 links of sliding mechanism by the maximum impulsive force will be simulated by using ANSYS® Workbench based on the Design Of Experiment(in short DOE). 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引用次数: 20
摘要
最近,随着垃圾自动收集设施(GACF)在首都圈的普及,对管道内清扫机器人(管内清扫机器人)的关注日益增加。迄今为止,管道机器人的研究主要集中在检测上,而不是清洁上。在GACF中,当垃圾移动时,我们要去除粘在管道内表面的杂质(直径:300mm或400mm)。因此,在本文中,我们将利用TRIZ(俄语缩写:Inventive Theory of Problem Solving)提出一种GACF管道内清洁机器人,该机器人具有六连杆滑动机构,可以通过气动压力(而不是弹簧)调节以适应管道内表面。本文提出的GACF管道内清扫机器人在清扫过程中既可以实现自身的向前/向后运动,也可以实现刷体的旋转。机器人本体应具有适用于直径为300mm的较小管道的极限尺寸。此外,对于直径为400mm的管道,机器人的连杆应通过滑动机构拉伸以适应管道的直径。基于使用TRIZ的概念设计,我们将与韩国robot Valley, Inc.的现场工程师合作建立机器人的初步设计。为了优化管道内清扫机器人的设计,利用RecurDyn®软件对机器人在将滑动机构的连杆拉伸到400mm直径的管道内时,与管道内壁碰撞产生的最大冲力进行了仿真。在实验设计(Design of Experiment,简称DOE)的基础上,利用ANSYS®Workbench对滑动机构6个连杆在最大冲力作用下的应力进行仿真。最后确定4个连杆的最优尺寸,包括厚度,以使本文的最佳安全系数为2,并使4个连杆的质量最小。与Robot Valley, Inc.的专家进行的初始设计相比,将验证4个连杆的优化设计具有接近2的最佳安全系数以及4个连杆的最小质量。此外,还将对管道内清洁机器人的原型进行进一步的研究。
Optimal mechanism design of in-pipe cleaning robot
Recently, interests on cleaning robots workable in pipes (termed as in-pipe cleaning robot) are increasing because Garbage Automatic Collection Facilities (i.e, GACF) are widely being installed in Seoul metropolitan area of Korea. So far research on in-pipe robot has been focused on inspection rather than cleaning. In GACF, when garbage is moving, we have to remove the impurities which are stuck to the inner face of the pipe (diameter: 300mm or 400mm). Thus, in this paper, by using TRIZ (Inventive Theory of Problem Solving in Russian abbreviation), we will propose an in-pipe cleaning robot of GACF with the 6-link sliding mechanism which can be adjusted to fit into the inner face of pipe using pneumatic pressure(not spring). The proposed in-pipe cleaning robot for GACF can have forward/backward movement itself as well as rotation of brush in cleaning. The robot body should have the limited size suitable for the smaller pipe with diameter of 300mm. In addition, for the pipe with diameter of 400mm, the links of robot should stretch to fit into the diameter of the pipe by using the sliding mechanism. Based on the conceptual design using TRIZ, we will set up the initial design of the robot in collaboration with a field engineer of Robot Valley, Inc. in Korea. For the optimal design of in-pipe cleaning robot, the maximum impulsive force of collision between the robot and the inner face of pipe is simulated by using RecurDyn® when the link of sliding mechanism is stretched to fit into the 400mm diameter of the pipe. The stresses exerted on the 6 links of sliding mechanism by the maximum impulsive force will be simulated by using ANSYS® Workbench based on the Design Of Experiment(in short DOE). Finally the optimal dimensions including thicknesses of 4 links will be decided in order to have the best safety factor as 2 in this paper as well as having the minimum mass of 4 links. It will be verified that the optimal design of 4 links has the best safety factor close to 2 as well as having the minimum mass of 4 links, compared with the initial design performed by the expert of Robot Valley, Inc. In addition, the prototype of in-pipe cleaning robot will be stated with further research.
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