A snake-like robot for internal inspection of complex pipe structures (PIKo)

Fjerdingen, Sigurd Aksnes; Liljebäck, Pål; Transeth, Aksel Andreas

doi:10.1109/iros.2009.5354751

Cited by 84 publications

(36 citation statements)

References 13 publications

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“…The model parameters are based on the snake robot PIKo which has been developed at the Norwegian research organization SINTEF in Trondheim, Norway [6].…”

Section: Modeling For Simulationmentioning

confidence: 99%

“…FTL approaches have already been used in several designs for motion through bends [1], [6]. We therefore consider it an important benchmark against the proposed algorithm.…”

Section: Module Coordination By Follow-the-leadermentioning

confidence: 99%

“…It utilizes a very basic principle for control: All modules should repeat the pattern of the first module -the leader -at the exact same spatial position as the leader module. This can either be done by adjusting the speed of the wheels to match the curvature shift [1], or by measuring the distance traveled by the wheels to set correct curvatures [6]. In either case slip will introduce inaccurate movements.…”

Section: Module Coordination By Follow-the-leadermentioning

confidence: 99%

“…The model parameters used for simulation are based on the snake robot PIKo which is developed at the Norwegian research institution SINTEF in Trondheim, Norway [6]. We employ n = 6 links in the simulations and for each link i we have that −4 s. However, the head controller only calculates new joint angle and wheels velocity references every 0.025 s in order to make the simulations more similar to a control system on an actual snake robot.…”

Section: A Simulation Parameters and Implementation Descriptionmentioning

confidence: 99%

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Modeling and path-following for a snake robot with active wheels

Murugendran

Transeth

Fjerdingen

2009

2009 IEEE/RSJ International Conference on Intelligent Robots and Systems

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Abstract-Snake robots with active wheels provide interesting opportunities within many areas such as inspection and maintenance and search and rescue operations. The highlyarticulated body of a snake robot combined with the advantages of wheeled locomotion makes it ideal for locomotion in, for example, pipes and other narrow or constricted structures. In this paper we present a mathematical model of the dynamics of a snake robot with active wheels together with a novel path-following approach for such robots. The path-following approach includes both how to find a desired turning angle for the snake robot head given a reference path, together with a module coordination strategy based on a n-trailer kinematic model. The path-following approach is tested and verified by simulations with the dynamic model. In addition, simulations suggest that the proposed approach results in reduced commanded joint and wheels shaft torques and, in most cases, a reduced path-following error compared to an implementation of a follow-the-leader algorithm.

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“…The model parameters are based on the snake robot PIKo which has been developed at the Norwegian research organization SINTEF in Trondheim, Norway [6].…”

Section: Modeling For Simulationmentioning

confidence: 99%

“…FTL approaches have already been used in several designs for motion through bends [1], [6]. We therefore consider it an important benchmark against the proposed algorithm.…”

Section: Module Coordination By Follow-the-leadermentioning

confidence: 99%

Section: Module Coordination By Follow-the-leadermentioning

confidence: 99%

Section: A Simulation Parameters and Implementation Descriptionmentioning

confidence: 99%

See 2 more Smart Citations

Modeling and path-following for a snake robot with active wheels

Murugendran

Transeth

Fjerdingen

2009

2009 IEEE/RSJ International Conference on Intelligent Robots and Systems

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“…In order to adapt to the particular in-pipe environment, many of the modifications have been tried. One is to add weight and equip the robot with more wheels for climbing, taking MAKRO 10 and Piko 11,12 for example. As the number of wheels increases, the degrees of freedom and the complexity of control strategies also increase.…”

Section: Introductionmentioning

confidence: 99%

Design of in-pipe robot based on inertial positioning and visual detection

Song

et al. 2016

Advances in Mechanical Engineering

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The horizontal directional drilling technology is widely used to lay the underground pipelines. These pipelines are of small or medium diameters with a dip angle ranging from 10°to 20°, special pipelines to 30°. In-pipe robot is commonly used to detect the pipeline fault. A new type of telescopic in-pipe robot is designed in this article, which is driven by step motor and screw, and supported by wheels. The robot has advantages of waterproof grade of IP68, stable motion state, and larger traction force. The speed is between telescopic robots and wheeled robots. Through force analysis and calculation, its maximum climbing angle is larger than 35°. The robot has good passing ability through the pipelines with bends. The inertial technology is used to locate the robot under the condition of disturbances. The pipeline fault detection algorithm based on the visual identification technology is designed to detect the pipeline fault. It can not only achieve autonomic positioning but also detect the pipeline fault.

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Control Methods for Wheeeler – The Hypermobile Robot

Granosik

Pytasz

2012

Robot Motion and Control 2011

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A snake-like robot for internal inspection of complex pipe structures (PIKo)

Cited by 84 publications

References 13 publications

Modeling and path-following for a snake robot with active wheels

Modeling and path-following for a snake robot with active wheels

Design of in-pipe robot based on inertial positioning and visual detection

Control Methods for Wheeeler – The Hypermobile Robot

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