• Title/Summary/Keyword: Inpipe robot

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Development of Inpipe Inspection Robot System (배관 검사 로봇 시스템 개발)

  • Baek, Sang-Hun;Ryu, Seong-Mu;No, Se-Gon;Choe, Hyeok-Ryeol
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.25 no.12
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    • pp.2030-2039
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    • 2001
  • Recently, various inpipe inspection robots are developed and its effective values are increased in industrial use. However, it is so difficult to make a inpipe inspection robot system which has flexible mobility and accuracy of inspection in pipelines. Especially, it is very important to know the exact crack position. In this paper, we are to present a lately developed inpipe inspection robot system which can resolve the above Problems. The robot is configured as an articulated structure like a snake. Two active driving vehicles are located in front and rear of the inspection robot respectively and passive modules such as a nondestructive testing module and a control module are chained between the active vehicles. Special feature of the robot system is a ground interface, which is able to show informations of robot and pipelines. By using this, so called virtual map in this paper, user is able to know the pipelines'feature and crack position.

A Real-time and Off-line Localization Algorithm for an Inpipe Robot by Detecting Elbows (엘보 인식에 의한 배관로봇의 실시간 위치 추정 및 후처리 위치 측정 알고리즘)

  • Lee, Chae Hyeuk;Kim, Gwang Ho;Kim, Jae Jun;Kim, Byung Soo;Lee, Soon Geul
    • Journal of Institute of Control, Robotics and Systems
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    • v.20 no.10
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    • pp.1044-1050
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    • 2014
  • Robots used for pipe inspection have been studied for a long time and many mobile mechanisms have been proposed to achieve inspection tasks within pipelines. Localization is an important factor for an inpipe robot to perform successful autonomous operation. However, sensors such as GPS and beacons cannot be used because of the unique characteristics of inpipe conditions. In this paper, an inpipe localization algorithm based on elbow detection is presented. By processing the projected marker images of laser pointers and the attitude and heading data from an IMU, the odometer module of the robot determines whether the robot is within a straight pipe or an elbow and minimizes the integration error in the orientation. In addition, an off-line positioning algorithm has been performed with forward and backward estimation and Procrustes analysis. The experimental environment has consisted of several straight pipes and elbows, and a map of the pipeline has been constructed as the result.

Automated Technology for Pipelines Inspection Using Inpipe Robot (배관 로봇을 이용한 배관 검사 자동화 기술)

  • Roh, Se-Gon;Choi, Hyouk-Ryeol
    • Journal of the Korean Society for Nondestructive Testing
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    • v.22 no.3
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    • pp.261-266
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    • 2002
  • Up to now a wide variety of researches on inpipe robots for inspection have been introduced, but it still seems to be difficult to construct a robot providing mobility sufficient to navigate inside the complicated configuration of underground pipelines. The robot for the inspection of pipelines should freely move along the basic configuration of pipelines such as along horizontal or vertical pipelines. Moreover it should be able to travel along reducers and elbows, and especially the capability for steering in branches is essential to it. In this report, citical points and technologies in the development of the inpipe inspection robots are introduced and inpipe robots developed for last several years are introduced.

Development of Differentially Driven Inpipe Inspection Robot for Underground Gas Pipeline (지하 매설 가스배관용 차동 구동형 배관검사 로봇의 개발)

  • No, Se-Gon;Ryu, Seong-Mu;Choe, Hyeok-Ryeol
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.25 no.12
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    • pp.2019-2029
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    • 2001
  • Up to now a wide variety of researches on inpipe inspection robots have been introduced, but it still seems to be difficult to construct a robot providing mobility sufficient to navigate inside the complicated configuration of underground pipelines. This paper introduces a robot called MRINSPECT IV(Multifunctional Robotic Crawler for inpipe inSPECTion IV) for the inspection of urban gas pipelines with a nominal 4-inch inside diameter. The proposed robot can freely move along the basic configuration of pipelines such as along horizontal or vertical pipelines. Moreover it can travel along reducers, elbows, and steer in the branches by modulating the speeds of driving modules. Especially, its capability for steering in tile three-dimensional pipeline configuration has a competative edge over the other ones and provides excellent mobility in navigation. Its critical points in the design and construction are introduced and results of experiments are given.

Development of Inpipe Inspection Robot System for Underground Gas Pipelines (지하매설 가스배관 내부검사용 로봇시스템 개발)

  • 최혁렬;류성무;백상훈;조성휘;송성진;신현재;전재욱
    • Journal of the Korean Society for Precision Engineering
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    • v.17 no.2
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    • pp.121-129
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    • 2000
  • The robotic automation in NonDestructive Testing(NDT) is a promising field of research and it helps to expand the applications of NDT enormously. Especially, in the case of pipelines which are widely used in various industrial facilities, it is required to secure adequate ways of inspection in the usual maintenance activitites. In this paper, we present a robot system for inpipe inspection of underground urban gas pipelines. The robot is configured as an articulated structure like a snake with a tether cable. Two active driving vehicles are located in front and rear of the system, respectively and passive modules such as a NonDestructive Testing module and a control module are chained between the active vehicles. The proposed system has outstanding mobility by employing a new steering mechanism called Double Active Universal Joint, which makes it possible to cope with complicated configurations of underground pipelines. Characteristic features of the system are described and the construction of the system is briefly outlined.

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Development of a pipeline robot like foxtail (강아지풀 형상을 닮은 관내 주행로봇 개발)

  • Choi, Yong-Ho;Yang, Hyun-Suk;Park, No-Chul
    • Proceedings of the KSME Conference
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    • 2007.05a
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    • pp.1167-1172
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    • 2007
  • Generally inpipe robot needs force above standing for contacting robot to pipe. If the environment of the pipe-inside does not change, there is not a problem. But if the pipe radius change, or occur the obstacle which it does not intend, problem gets. So it uses a different system and must know an environment change, and changing the shape or a form of the robot. The research uses the flexible leg and is the robot which is adapted to the environment change of the pipe. The advantage of this robot is possible to move when it does not need to recognize a change of environment of pipe. Leg is bend with one direction. When it moves part that there are legs effect of leg direction the robot is moved with only one direction. If friction between legs and pipe is sufficient, not only verticality pipe moving, but also curved pipe moving. Also the obstacle of the pipe inside occurs and the diameter of the pipe inside changes, this robot can move if it does not use another system or device.

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Development of In-Pipe Robot Using Clutch-Based Selective Driving Algorithm (클러치기반의 선택적 구동방식을 이용한 배관로봇의 개발)

  • Kim, Do-Wan;Roh, Se-Gon;Lee, Jung-Sub;Lee, Soo-Hwan;Choi, Hyouk-Ryeol
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.32 no.3
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    • pp.223-231
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    • 2008
  • This paper introduces a robot called the MRINSPECT V (Multifunctional Robotic crawler for Inpipe in-SPECTion V) for the inspection of pipelines with a nominal 8-in inside diameter. Based on the mechanism of the previous model MRINSPECT IV, we developed a new MRINSPECT V by using the differential driving mechanism, so that just simply controlling the speed of each driving units helps the robot to travel effectively inside the pipelines. Furthermore, the robot uses clutches in transmitting driving power to wheels. This clutch mechanism enables MRINSPECT V to select the suitable driving method according to the shape of pipeline. In this paper, the critical points in design and construction of the proposed robot are described with the preliminary results to provide good mobility and increase the efficiency.