Climbing Robots? Mobility for Inspection and Maintenance of 3D Complex Environments

Balaguer, Carlos; Giménez, Antonio; Jardón, Alberto

doi:10.1007/s10514-005-0723-0

Cited by 98 publications

(43 citation statements)

References 6 publications

(4 reference statements)

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“…• Inspection: bridges (Balaguer et al (2005); Robert T. Pack and Kawamura (1997)), nuclear power plants (Savall et al (1999); Yan et al (1999)), pipelines (Park et al (2003)), wind turbines ), solar power plants (Azaiz (2008)), for scanning the external and internal surfaces of gas or oil tanks (Longo and Muscato (2004b); Park et al (2003); Sattar et al (2002); Yan et al (1999)), offshore platforms (Balaguer et al (2005)), and container ships );…”

Section: Climbing Robots Applicationsmentioning

confidence: 99%

A Survey of Technologies and Applications for Climbing Robots Locomotion and Adhesion

Silva¹,

Machado²

2010

Climbing and Walking Robots

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Section: Climbing Robots Applicationsmentioning

confidence: 99%

A Survey of Technologies and Applications for Climbing Robots Locomotion and Adhesion

Silva¹,

Machado²

2010

Climbing and Walking Robots

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“…Configuring different locomotion and attaching mechanisms, these robots differ significantly in mobility and flexibility. In-depth discussions on this topic could be found in [18,19]. Among these robots, SM 2 , ROMA, Shady3D, 3DCLIMBER, Treebot and Climbot, having the characteristic of bipedal climbing, are considered to be dominant.…”

Section: Introductionmentioning

confidence: 99%

Transition Analysis and Its Application to Global Path Determination for a Biped Climbing Robot

Zhu

et al. 2018

Applied Sciences

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Biped climbing robots are considered good assistants and (or) substitutes for human workers carrying out high-rise truss-associated routine tasks. Flexible locomotion on three-dimensional complex trusses is a fundamental skill for these robots. In particular, the capability to transit from one structural member to another is paramount for switching objects to be climbed upon. In this paper, we study member-to-member transition and its utility in global path searching for biped climbing robots. To compute operational regions for transition, hierarchical inspection of safety, reachability, and accessibility of grips is taken into account. A novel global path rapid determination approach is subsequently proposed based on the transition analysis. This scheme is efficient for finding feasible routes with respect to the overall structural environment, which also benefits the subsequent grip and motion planning. Simulations are conducted with Climbot, our self-developed biped climbing robot, to verify the efficiency of the presented method. Results show that our proposed method is able to accurately determine the operational region for transition within tens of milliseconds and can obtain global paths within seconds in general.

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“…On the one hand, hybrid robots have the high manoeuvrability and large workspace of serial robots, which is beneficial for exploring complex 3D structures. On the other hand, they also have the high rigidity and load-to-weight ratio of parallel robots, which is useful for climbing robots since they must support their own weight [16].…”

Section: Introductionmentioning

confidence: 99%

Inverse Kinematic Analysis of a Redundant Hybrid Climbing Robot

Peidró

Gil

Marı́n

et al. 2015

International Journal of Advanced Robotic Systems

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This paper presents the complete inverse kinematic analysis of a novel redundant truss-climbing robot with 10 degrees of freedom. The robot is bipedal and has a hybrid serial-parallel architecture, where each leg consists of two parallel mechanisms connected in series. By separating the equation for inverse kinematics into two parts -with each part associated with a different leg -an analytic solution to the inverse kinematics is derived. In the obtained solution, all the joint coordinates are calculated in terms of four or five decision variables (depending on the desired orientation) whose values can be freely decided due to the redundancy of the robot. Next, the constrained inverse kinematic problem is also solved, which consists of finding the values of the decision variables that yield a desired position and orientation satisfying the joint limits. Taking the joint limits into consideration, it is shown that all the feasible solutions that yield a given desired position and orientation can be represented as 2D and 3D sets in the space of the decision variables. These sets provide a compact and complete solution to the inverse kinematics, with applications for motion planning.

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Climbing Robots? Mobility for Inspection and Maintenance of 3D Complex Environments

Cited by 98 publications

References 6 publications

A Survey of Technologies and Applications for Climbing Robots Locomotion and Adhesion

A Survey of Technologies and Applications for Climbing Robots Locomotion and Adhesion

Transition Analysis and Its Application to Global Path Determination for a Biped Climbing Robot

Inverse Kinematic Analysis of a Redundant Hybrid Climbing Robot

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