Design of adaptive weld quality monitoring for multiple‐conditioned robotic welding tasks

Xia, Suibo; Pang, Chee Khiang; Mamun, Abdullah Al; Wong, Fook Seng; Chew, Chee-Meng

doi:10.1002/asjc.2574

Cited by 1 publication

(1 citation statement)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…At the same time, considering the problem of image noise, a method based on attention dense convolutional blocks is adopted to solve the problem of image noise. Finally, the research model will be applied to specific robot welding scenarios, and the technology studied can accurately extract weld texture features, thereby ensuring the quality of welding robots (Xia et al, 2022) Mikkelstrup et al found that in some complex welding robot work scenarios, traditional welding robots are difficult to effectively ensure the quality of welding. On the basis of digital twin technology, this study focuses on high-frequency mechanical impact treatment.…”

Section: Related Workmentioning

confidence: 99%

Welding robot automation technology based on digital twin

Kang,

Chen

2024

Front. Mech. Eng.

View full text Add to dashboard Cite

In the era of intelligence and automation, robots play a significant role in the field of automated welding, enhancing efficiency and precision. However, challenges persist in scenarios demanding complexity and higher precision, such as low welding planning efficiency and inaccurate weld seam defect detection. Therefore, based on digital twin technology and kernel correlation filtering algorithm, a welding tracking model is proposed. Firstly, the kernel correlation filtering algorithm is used to train the filter on the first frame of the collected image, determine the position of image features in the region, extract histogram features of image blocks, and then train the filter using ridge regression to achieve welding trajectory tracking. Additionally, an intelligent weld seam detection model is introduced, employing a backbone feature network for feature extraction, feature fusion through a feature pyramid, and quality detection of weld seams through head classification. During testing of the tracking model, the maximum tracking error is −0.232 mm, with an average absolute tracking error of 0.08 mm, outperforming other models. Comparatively, in tracking accuracy, the proposed model exhibits the fastest convergence with a precision rate of 0.845, surpassing other models. In weld seam detection, the proposed model excels with a detection accuracy of 97.35% and minimal performance loss at 0.023. In weld seam quality and melt depth error detection, the proposed model achieves errors within the range of −0.06 mm, outperforming the other two models. These results highlight the outstanding detection capabilities of the proposed model. The research findings will serve as technical references for the development of automated welding robots and welding quality inspection.

show abstract

Section: Related Workmentioning

confidence: 99%