A New Method to Assess Fiber Laser Welding Quality of Stainless Steel 304 Based on Machine Vision and Hidden Markov Models

A New Method to Assess Fiber Laser Welding Quality of Stainless Steel 304 Based on Machine Vision and Hidden Markov Models

High-power fiber laser welding has a broad range of applications in industrial processing and modern intelligent manufacturing, but how to assess the quality of laser welding has always been a concern. In the welding process, the geometric feature of the keyhole generated by the high temperature of...

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Main Authors: Xin Tang, Ping Zhong, Lingling Zhang, Jun Gu, Zhaopeng Liu, Yinrui Gao, Haowei Hu, Xutong Yang
Format: Article
Language:English
Published: IEEE 2020-01-01
Series:IEEE Access
Subjects:
Fiber laser welding
hidden Markov model
image processing
keyhole behavior
process monitoring
quality evaluation
Online Access:https://ieeexplore.ieee.org/document/9141226/
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record_format Article
spelling doaj-568bfcbdec304126a9544690674edaac2021-03-30T04:48:22ZengIEEEIEEE Access2169-35362020-01-01813063313064610.1109/ACCESS.2020.30093219141226A New Method to Assess Fiber Laser Welding Quality of Stainless Steel 304 Based on Machine Vision and Hidden Markov ModelsXin Tang0https://orcid.org/0000-0003-4054-0418Ping Zhong1https://orcid.org/0000-0001-8240-7581Lingling Zhang2https://orcid.org/0000-0003-1489-2321Jun Gu3https://orcid.org/0000-0001-7117-7207Zhaopeng Liu4https://orcid.org/0000-0001-9819-1738Yinrui Gao5https://orcid.org/0000-0002-6867-2909Haowei Hu6https://orcid.org/0000-0002-8681-9687Xutong Yang7https://orcid.org/0000-0002-9400-3194College of Information Science and Technology, Donghua University, Shanghai, ChinaCollege of Information Science and Technology, Donghua University, Shanghai, ChinaShanghai Institute of Laser Technology, Shanghai, ChinaShanghai Institute of Laser Technology, Shanghai, ChinaShanghai Institute of Laser Technology, Shanghai, ChinaCollege of Science, Donghua University, Shanghai, ChinaCollege of Science, Donghua University, Shanghai, ChinaCollege of Science, Donghua University, Shanghai, ChinaHigh-power fiber laser welding has a broad range of applications in industrial processing and modern intelligent manufacturing, but how to assess the quality of laser welding has always been a concern. In the welding process, the geometric feature of the keyhole generated by the high temperature of laser can directly reflect quality of the laser welding. By using machine vision to acquire images in real time and analyze related features, the quality of laser welding can be evaluated, which reduce the cost and time in later inspection. Nevertheless, due to the dynamic complexity of the keyhole as well as the blurring of the keyhole and full penetration hole boundary caused by metal vapor and spatter, identification of multiple type defects through machine vision is still a problem that requires a solution. This paper presents a novel laser welding defect classification method using keyhole boundary-based feature based on machine vision and Hidden Markov process. After effective segmenting the collected welding image, the shapes of the keyhole as well as the full penetration hole were automatically extracted using the characteristics of gray projection distribution and the Poisson extinction method. Subsequently, a pre-trained Hidden Markov Model was employed to establish the connection between the keyhole's geometry and the welding quality defects. Experiments indicate that our theory can efficiently and accurately extract the key geometric shapes. Welding experimental data involving stainless steel 304 verifies the feasibility of the classification theory, which can monitor welding quality and reveal potential porosity and penetration defects.https://ieeexplore.ieee.org/document/9141226/Fiber laser weldinghidden Markov modelimage processingkeyhole behaviorprocess monitoringquality evaluation
collection DOAJ
language English
format Article
sources DOAJ
author Xin Tang
Ping Zhong
Lingling Zhang
Jun Gu
Zhaopeng Liu
Yinrui Gao
Haowei Hu
Xutong Yang
spellingShingle Xin Tang
Ping Zhong
Lingling Zhang
Jun Gu
Zhaopeng Liu
Yinrui Gao
Haowei Hu
Xutong Yang
A New Method to Assess Fiber Laser Welding Quality of Stainless Steel 304 Based on Machine Vision and Hidden Markov Models
IEEE Access
Fiber laser welding
hidden Markov model
image processing
keyhole behavior
process monitoring
quality evaluation
author_facet Xin Tang
Ping Zhong
Lingling Zhang
Jun Gu
Zhaopeng Liu
Yinrui Gao
Haowei Hu
Xutong Yang
author_sort Xin Tang
title A New Method to Assess Fiber Laser Welding Quality of Stainless Steel 304 Based on Machine Vision and Hidden Markov Models
title_short A New Method to Assess Fiber Laser Welding Quality of Stainless Steel 304 Based on Machine Vision and Hidden Markov Models
title_full A New Method to Assess Fiber Laser Welding Quality of Stainless Steel 304 Based on Machine Vision and Hidden Markov Models
title_fullStr A New Method to Assess Fiber Laser Welding Quality of Stainless Steel 304 Based on Machine Vision and Hidden Markov Models
title_full_unstemmed A New Method to Assess Fiber Laser Welding Quality of Stainless Steel 304 Based on Machine Vision and Hidden Markov Models
title_sort new method to assess fiber laser welding quality of stainless steel 304 based on machine vision and hidden markov models
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2020-01-01
description High-power fiber laser welding has a broad range of applications in industrial processing and modern intelligent manufacturing, but how to assess the quality of laser welding has always been a concern. In the welding process, the geometric feature of the keyhole generated by the high temperature of laser can directly reflect quality of the laser welding. By using machine vision to acquire images in real time and analyze related features, the quality of laser welding can be evaluated, which reduce the cost and time in later inspection. Nevertheless, due to the dynamic complexity of the keyhole as well as the blurring of the keyhole and full penetration hole boundary caused by metal vapor and spatter, identification of multiple type defects through machine vision is still a problem that requires a solution. This paper presents a novel laser welding defect classification method using keyhole boundary-based feature based on machine vision and Hidden Markov process. After effective segmenting the collected welding image, the shapes of the keyhole as well as the full penetration hole were automatically extracted using the characteristics of gray projection distribution and the Poisson extinction method. Subsequently, a pre-trained Hidden Markov Model was employed to establish the connection between the keyhole's geometry and the welding quality defects. Experiments indicate that our theory can efficiently and accurately extract the key geometric shapes. Welding experimental data involving stainless steel 304 verifies the feasibility of the classification theory, which can monitor welding quality and reveal potential porosity and penetration defects.
topic Fiber laser welding
hidden Markov model
image processing
keyhole behavior
process monitoring
quality evaluation
url https://ieeexplore.ieee.org/document/9141226/
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