Optimization for Industrial Robot Joint Movement in Non-Horizontal 3D Printing Application (2024-05)¶
Lu Ming, ,
Journal Article - Architectural Intelligence, Vol. 3, Iss. 1
Abstract
When a robot is printing a sequence of non-horizontal goal poses, its joint values often undergo significant variations, resulting in challenges such as singularities or exceeding joint limits. This paper proposes two new methods aimed at optimizing goal poses to solve the problem. The first method, employing an analytical approach, modifies the goal poses to maintain the 4th joint value of a 6-axis industrial robot at zero. This adjustment effectively reduces the motion range of the 5th and 6th axes. The second method utilizes numerical optimization to adjust the goal poses, aiming to minimize the motion range of all joints. Leveraging the analytical method to obtain one good initial value, numerical optimization is subsequently applied to complete the entire path optimization, creating an optimization workflow. It is also possible to use only analytical methods for computational efficiency. The feasibility and effectiveness of these two methods are validated through simulation and real project case.
¶
14 References
- Breseghello Luca, Sanin Sandro, Naboni Roberto (2021-04)
Tool-Path Simulation, Design and Manipulation in Robotic 3D Concrete Printing - Furet Benoît, Poullain Philippe, Garnier Sébastien (2019-04)
3D Printing for Construction Based on a Complex Wall of Polymer-Foam and Concrete - Khoshnevis Behrokh (2003-11)
Automated Construction by Contour Crafting:
Related Robotics and Information Technologies - Li Shuai, Nguyen-Xuan Hung, Tran Jonathan (2022-11)
Digital Design and Parametric Study of 3D Concrete Printing on Non-Planar Surfaces - Lu Ming, Yuan Philip (2020-08)
A New Algorithm to Get Optimized Target Plane on Six-Axis Robot for Fabrication - Nematollahi Behzad, Xia Ming, Sanjayan Jay (2017-07)
Current Progress of 3D Concrete Printing Technologies - Rehman Atta, Kim Jung-Hoon (2021-07)
3D Concrete Printing:
A Systematic Review of Rheology, Mix Designs, Mechanical, Microstructural, and Durability Characteristics - Siddika Ayesha, Mamun Md., Ferdous Wahid, Saha Ashish et al. (2019-12)
3D Printed Concrete:
Applications, Performance, and Challenges - Vantyghem Gieljan, Corte Wouter, Shakour Emad, Amir Oded (2020-01)
3D Printing of a Post-Tensioned Concrete Girder Designed by Topology-Optimization - Wu Hao, Li Ziyan, Zhou Xinjie, Wu Xinyu et al. (2022-04)
Digital Design and Fabrication of a 3D Concrete Printed Funicular Spatial Structure - Xiao Jianzhuang, Ji Guangchao, Zhang Yamei, Ma Guowei et al. (2021-06)
Large-Scale 3D Printing Concrete Technology:
Current Status and Future Opportunities - Yuan Philip, Zhan Qiang, Wu Hao, Beh Hooi et al. (2021-11)
Real-Time Tool-Path-Planning and Extrusion-Control-Method for Variable-Width 3D Concrete Printing - Zhang Jing, Khoshnevis Behrokh (2012-09)
Optimal Machine Operation Planning for Construction by Contour Crafting - Zhang Jingchuan, Wang Jialiang, Dong Sufen, Yu Xun et al. (2019-07)
A Review of the Current Progress and Application of 3D Printed Concrete
BibTeX
@article{lu_wu_yuan.2024.OfIRJMiNH3PA,
author = "Ming Lu and Hao Wu and Philip F. Yuan",
title = "Optimization for Industrial Robot Joint Movement in Non-Horizontal 3D Printing Application",
doi = "10.1007/s44223-024-00058-z",
year = "2024",
journal = "Architectural Intelligence",
volume = "3",
number = "1",
}
Formatted Citation
M. Lu, H. Wu and P. F. Yuan, “Optimization for Industrial Robot Joint Movement in Non-Horizontal 3D Printing Application”, Architectural Intelligence, vol. 3, no. 1, 2024, doi: 10.1007/s44223-024-00058-z.
Lu, Ming, Hao Wu, and Philip F. Yuan. “Optimization for Industrial Robot Joint Movement in Non-Horizontal 3D Printing Application”. Architectural Intelligence 3, no. 1 (2024). https://doi.org/10.1007/s44223-024-00058-z.