Structural design and kinematic analysis of a welding robot for liquefied natural gas membrane tank automatic welding

Jiang, Yi; Han, Qin; Zhaoen, Dai; Zhou, Chao; Yu, Jianfeng; Chen, Hua

doi:10.1007/s00170-022-09861-2

Int J Adv Manuf Technol

2022

DOI: 10.1007/s00170-022-09861-2

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Structural design and kinematic analysis of a welding robot for liquefied natural gas membrane tank automatic welding

Yi Jiang

Qin Han

Dai Zhaoen

et al.

Abstract: Owing to the complex structures of welding materials, special welding conditions, and challenges during the automatic welding of the liquefied natural gas (LNG) ship Mark III's membrane tank, a series-parallel-series hybrid structure mobile welding robot having sufficient adaptability for welding corrugated plates in membrane tanks was designed in this study. The configuration of the hybrid robot had good workspace characteristics, and it could always maintain a certain distance and angle between the end of th… Show more

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Cited by 3 publications

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“…The robotic manipulator design must strike a balance between these factors to ensure optimal performance across diverse operational conditions. Careful consideration during the design phase allows engineers to develop robust and reliable systems tailored to specific applications, like industrial welding, while minimizing risks and maximizing efficiency [21][22][23][24][25][26].…”

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confidence: 99%

Kinematic Modeling and Performance Analysis of a 5-DoF Robot for Welding Applications

Karupusamy,

Maruthachalam,

Veerasamy

2024

Machines

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Robotic manipulators are critical for industrial automation, boosting productivity, quality, and safety in various production applications. Key factors like the payload, speed, accuracy, and reach define robot performance. Optimizing these factors is crucial for future robot applications across diverse fields. While 6-Degrees-of-Freedom (DoF)-articulated robots are popular due to their diverse applications, this research proposes a novel 5-DoF robot design for industrial automation, featuring a combination of three prismatic and two revolute (2R) joints, and analyzes its workspace. The proposed techno-economically efficient design offers control over the robot manipulator to achieve any reachable position and orientation within its workspace, replacing traditional 6-DoF robots. The kinematic model integrates both parallel and serial manipulator principles, combining a Cartesian mechanism with rotational mechanisms. Simulations demonstrate the end effector’s flexibility for tasks like welding, additive manufacturing, and material inspections, achieving the desired position and orientation. The research encompasses the design of linear and rotational actuators, kinematic modeling, Human–Machine Interface (HMI) development, and welding application integration. The developed robot demonstrates a superior performance and user-friendliness in welding. The experimental work validates the design’s optimized joint trajectories, efficient power usage, singularity avoidance, easy access in application areas, and reduced costs due to fewer actuators.

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mentioning

confidence: 99%

Kinematic Modeling and Performance Analysis of a 5-DoF Robot for Welding Applications

Karupusamy,

Maruthachalam,

Veerasamy

2024

Machines

View full text Add to dashboard Cite

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Structural design and adaptive tracking control of automatic welding robot for liquefied natural gas containment system

Chu,

Ma,

Zhao

et al. 2024

Discov Appl Sci

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Liquefied natural gas (LNG) is commonly transported by LNG carriers and stored in cargo containment systems. The primary barrier of the MARK III cargo containment system is welded to a closed space with corrugated stainless steel plates. To meet the requirements of excellent sealing and thermal insulation for cargo containment, the welding process of the corrugated plate need to be strictly controlled, which poses a challenge to the development of related welding equipment. In this paper, we present a new five-axis automatic welding robot system used for plasma arc welding on corrugated surfaces. The moment transfer scheme of the dual linkage mechanism makes the rotary movement of the robot more accurate and stable which gives the system with simpler control algorithm and better overall force characteristics. To ensure tracking accuracy, a novel sensing method based on a LASER sensor, two contact sensors, and an angle sensor is proposed to implement multiple functions such as tracking the welding arc length, identifying corrugation shapes, and detecting welding gun posture. Based on the devised tracking sensor system and welding robot, a servo-control system with a surface-tracking welding control algorithm is established. The experimental results show that the robot system's welding speed is about 7 times that of hand welding and the welding qualification rate was 99%, significantly improving welding efficiency and quality as a critical equipment technology in the process of corrugated plate welding.

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Design and Test of Duckbill Welding Robot for Cotton Seeder

Guo

Wang

et al. 2022

Agriculture

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To improve the automation, welding efficiency, and welding quality of duckbill welding of the cotton seeder, this study designed a cotton seeder duckbill welding robot. According to the characteristics of the duckbill weldment and welding requirements, the overall structure of the welding robot was determined, including the girdle feeding mechanism, static duckbill feeding mechanism, hinge feeding mechanism, welding fixture, welding actuator, and control system. To realize the continuous automatic feeding, positioning, fixing, welding, and unloading of the workpiece in the duckbill welding, the feeding mechanism adopts the method of cooperative cooperation of inductive proximity switch, electromagnet, and cylinder. The main body of the welding fixture adopts the pneumatic clamping method; the welding actuator adopts the synchronous belt module electric drive so that the welding torch can move in a straight line along the X axis and the Z axis. The welding process of the duckbill was simulated by Simufact Welding software, and the deformation and stress changes of the weldment were compared and analyzed when the single-sided single welding, the bilateral symmetrical double welding torch, two welding forms, and two welding process parameters were used to determine the welding process parameters of the welding robot. The prototype was made and the welding test was carried out. The test results show that the duckbill welding robot of the cotton seeder has stable feeding, solid clamping, accurate positioning, and high welding efficiency. According to the national standard, the appearance of the duckbill weld is inspected. The surface of the duckbill weld and the heat-affected zone has no cracks, incomplete fusion, slag inclusion, crater, and porosity. The forming quality of the welded parts is good. The design of the duckbill welding robot for cotton seeder is helpful in solving the problems of cumbersome positioning and clamping and low efficiency in manual and semi-automatic duckbill welding robots, which provides a strong guarantee for the large-scale and standardized welding production of the dibbler duckbill.

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Structural design and kinematic analysis of a welding robot for liquefied natural gas membrane tank automatic welding

Cited by 3 publications

References 16 publications

Kinematic Modeling and Performance Analysis of a 5-DoF Robot for Welding Applications

Kinematic Modeling and Performance Analysis of a 5-DoF Robot for Welding Applications

Structural design and adaptive tracking control of automatic welding robot for liquefied natural gas containment system

Design and Test of Duckbill Welding Robot for Cotton Seeder

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