Design and experimental verification of an intelligent wall-climbing welding robot system

Gui, Zhongcheng; Deng, Yongjun; Sheng, Zhongxi; Xiao, Tangjie; Lü, Yonglong; Zhang, Fan; Dong, Ning; Wu, Jinyi

doi:10.1108/ir-08-2014-0384

Cited by 9 publications

(2 citation statements)

References 4 publications

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“…Typically, the design of the adhesion and locomotion mechanisms, which determine the payload, moving velocity, and energy supply, vary according to the working conditions and working content. In a number of applications where the WCRs are designed for heavy work, such as rust-removal [3,20], wall cleaning [8,9,17], and automatic welding [4,21], the robots are optimized for high loads and high energy consumption to ensure the working progress. The locomotion and adhesion mechanisms of these robots could be large-sized and heavy, and a number of types of locomotion and adhesion mechanisms could even be combined to meet specific requirements.…”

mentioning

confidence: 99%

Tracked Wall-Climbing Robot for Calibration of Large Vertical Metal Tanks

Chen

Hao

et al. 2019

Applied Sciences

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Large vertical metal tanks are the primary vessels for the storage and turnover of crude oil, and the accuracy of their capacity calibrations are of great significance. The optical reference line method (ORLM) is used for capacity calibration and is time-consuming, labor-intensive, and hazardous, because of the elevated work. This paper aims to present a robot to overcome the problems above. We propose a tracked wall-climbing robot (TWCR) with permanent magnetic adhesion tracks, a collapsible scale, and an optional shovel-like rust remover that enable the TWCR to move stably on tank surfaces and perform the ORLM. Two sets of field tests (internal ORLM and external ORLM) indicate that capacity calibration by the TWCR is time saving, convenient, and safe, in addition to being accurate and reliable.

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confidence: 99%

Tracked Wall-Climbing Robot for Calibration of Large Vertical Metal Tanks

Chen

Hao

et al. 2019

Applied Sciences

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“…Minghui Wu et al [8] focused on adhesion force and the mechanism for passing over obstacles for a wheel robot. The mechanism included lifting the body of the robot to avoid obstacles by varying adhesive forces.Zhongcheng Gui et al [9] developed a robot for welding with colossal load-carrying capacity and high adsorption reliability. They showcased an inchworm mechanism with two switchable magnets for adhesion.…”

Section: Literature Reviewmentioning

confidence: 99%

Design And Analysis of a Pipe Inspection Caterpillar Robot Using Different Materials

A. Johnson, Dr. P. Rajendran, Dr. Sriram Venkatesh

2023

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The development of a pipe inspection robot employing caterpillar locomotion and constructed with PLA and ABS materials entails a comprehensive process. Beginning with the delineation of specific requirements, such as size and inspection capabilities, the conceptual design is conceived, outlining the robot's features. The subsequent phase involves meticulous 3D modelling using software like SolidWorks, followed by ANSYS analysis to simulate and optimize the robot's structural integrity, stress distribution, and overall performance. PLA and ABS are chosen as 3D printing materials, with PLA offering ease of printing and biodegradability, while ABS contributes durability and temperature resistance. The prototype is then constructed, incorporating motors, sensors, and the caterpillar locomotion system. ANSYS analysis is employed to assess the robot's behaviour under varying conditions, ensuring robustness and reliability. The iterative process of testing and refining the design leads to the optimization of the robot's performance. The final steps involve thorough documentation, regulatory compliance checks, and potential scalability for diverse applications, culminating in the deployment of the caterpillar robot for effective pipe inspection tasks. This paper delves into the design and static structural analysis of a caterpillar robot model utilizing ANSYS, with a specific emphasis on assessing two distinct materials: Acrylonitrile Butadiene Styrene (ABS) and Polylactic acid (PLA). The study involves a comprehensive comparison of various parameters between the two materials, aiming to provide insights into their respective performance and suitability for the caterpillar robot's structural components.

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