Quantitative Correlation between Thermal Cycling and the Microstructures of X100 Pipeline Steel Laser-Welded Joints

Quantitative Correlation between Thermal Cycling and the Microstructures of X100 Pipeline Steel Laser-Welded Joints

Due to the limitations of the energy density and penetration ability of arc welding technology for long-distance pipelines, the deterioration of the microstructures in the coarse-grained heat-affected zone (HAZ) in welded joints in large-diameter, thick-walled pipeline steel leads to insufficient st...

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Main Authors: Gang Wang, Jinzhao Wang, Limeng Yin, Huiqin Hu, Zongxiang Yao
Format: Article
Language:English
Published: MDPI AG 2019-12-01
Series:Materials
Subjects:
laser welding
numerical simulation
x100 pipeline steel
welding thermal cycle
microstructure
Online Access:https://www.mdpi.com/1996-1944/13/1/121
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spelling doaj-9b64e2a72c30461ba09e17dfabf934952020-11-25T02:36:24ZengMDPI AGMaterials1996-19442019-12-0113112110.3390/ma13010121ma13010121Quantitative Correlation between Thermal Cycling and the Microstructures of X100 Pipeline Steel Laser-Welded JointsGang Wang0Jinzhao Wang1Limeng Yin2Huiqin Hu3Zongxiang Yao4School of Metallurgy and Materials Engineering, Chongqing University of Science and Technology, Chongqing 401331, ChinaGuangdong Provincial Key Laboratory of Advanced Welding Technology, Guangdong Welding Institute (China-Ukraine E.O. Paton Institute of Welding), Guangzhou 510650, ChinaSchool of Metallurgy and Materials Engineering, Chongqing University of Science and Technology, Chongqing 401331, ChinaSchool of Natural and Applied Sciences, Northwestern Polytechnical University, Xian 710129, ChinaSchool of Metallurgy and Materials Engineering, Chongqing University of Science and Technology, Chongqing 401331, ChinaDue to the limitations of the energy density and penetration ability of arc welding technology for long-distance pipelines, the deterioration of the microstructures in the coarse-grained heat-affected zone (HAZ) in welded joints in large-diameter, thick-walled pipeline steel leads to insufficient strength and toughness in these joints, which strongly affect the service reliability and durability of oil and gas pipelines. Therefore, high-energy-beam welding is introduced for pipeline steel welding to reduce pipeline construction costs and improve the efficiency and safety of oil and gas transportation. In the present work, two pieces of X100 pipeline steel plates with thicknesses of 12.8 mm were welded by a high-power robot laser-welding platform. The quantitative correlation between thermal cycling and the microstructure of the welded joint was studied using numerical simulation of the welding temperature field, optical microscopy (OM), and scanning electron microscopy (SEM) with energy-dispersive spectroscopy (EDS). The results show that the heat-source model of a Gaussian-distributed rotating body and the austenitization degree parameters are highly accurate in simulating the welding temperature field and characterizing the austenitization degree. The effects of austenitization are more significant than those of the cooling rate on the final microstructures of the laser-welded joint. The microstructure of the X100 pipeline steel in the HAZ is mainly composed of acicular ferrite (AF), granular bainite (GB), and bainitic ferrite (BF). However, small amounts of lath martensite (LM), upper bainite (UB), and the bulk microstructure are found in the columnar zone of the weld. The aim of this paper is to provide scientific guidance and a reference for the simulation of the temperature field during high-energy-beam laser welding and to study and formulate the laser-welding process for X100 pipeline steel.https://www.mdpi.com/1996-1944/13/1/121laser weldingnumerical simulationx100 pipeline steelwelding thermal cyclemicrostructure
collection DOAJ
language English
format Article
sources DOAJ
author Gang Wang
Jinzhao Wang
Limeng Yin
Huiqin Hu
Zongxiang Yao
spellingShingle Gang Wang
Jinzhao Wang
Limeng Yin
Huiqin Hu
Zongxiang Yao
Quantitative Correlation between Thermal Cycling and the Microstructures of X100 Pipeline Steel Laser-Welded Joints
Materials
laser welding
numerical simulation
x100 pipeline steel
welding thermal cycle
microstructure
author_facet Gang Wang
Jinzhao Wang
Limeng Yin
Huiqin Hu
Zongxiang Yao
author_sort Gang Wang
title Quantitative Correlation between Thermal Cycling and the Microstructures of X100 Pipeline Steel Laser-Welded Joints
title_short Quantitative Correlation between Thermal Cycling and the Microstructures of X100 Pipeline Steel Laser-Welded Joints
title_full Quantitative Correlation between Thermal Cycling and the Microstructures of X100 Pipeline Steel Laser-Welded Joints
title_fullStr Quantitative Correlation between Thermal Cycling and the Microstructures of X100 Pipeline Steel Laser-Welded Joints
title_full_unstemmed Quantitative Correlation between Thermal Cycling and the Microstructures of X100 Pipeline Steel Laser-Welded Joints
title_sort quantitative correlation between thermal cycling and the microstructures of x100 pipeline steel laser-welded joints
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2019-12-01
description Due to the limitations of the energy density and penetration ability of arc welding technology for long-distance pipelines, the deterioration of the microstructures in the coarse-grained heat-affected zone (HAZ) in welded joints in large-diameter, thick-walled pipeline steel leads to insufficient strength and toughness in these joints, which strongly affect the service reliability and durability of oil and gas pipelines. Therefore, high-energy-beam welding is introduced for pipeline steel welding to reduce pipeline construction costs and improve the efficiency and safety of oil and gas transportation. In the present work, two pieces of X100 pipeline steel plates with thicknesses of 12.8 mm were welded by a high-power robot laser-welding platform. The quantitative correlation between thermal cycling and the microstructure of the welded joint was studied using numerical simulation of the welding temperature field, optical microscopy (OM), and scanning electron microscopy (SEM) with energy-dispersive spectroscopy (EDS). The results show that the heat-source model of a Gaussian-distributed rotating body and the austenitization degree parameters are highly accurate in simulating the welding temperature field and characterizing the austenitization degree. The effects of austenitization are more significant than those of the cooling rate on the final microstructures of the laser-welded joint. The microstructure of the X100 pipeline steel in the HAZ is mainly composed of acicular ferrite (AF), granular bainite (GB), and bainitic ferrite (BF). However, small amounts of lath martensite (LM), upper bainite (UB), and the bulk microstructure are found in the columnar zone of the weld. The aim of this paper is to provide scientific guidance and a reference for the simulation of the temperature field during high-energy-beam laser welding and to study and formulate the laser-welding process for X100 pipeline steel.
topic laser welding
numerical simulation
x100 pipeline steel
welding thermal cycle
microstructure
url https://www.mdpi.com/1996-1944/13/1/121
work_keys_str_mv AT gangwang quantitativecorrelationbetweenthermalcyclingandthemicrostructuresofx100pipelinesteellaserweldedjoints
AT jinzhaowang quantitativecorrelationbetweenthermalcyclingandthemicrostructuresofx100pipelinesteellaserweldedjoints
AT limengyin quantitativecorrelationbetweenthermalcyclingandthemicrostructuresofx100pipelinesteellaserweldedjoints
AT huiqinhu quantitativecorrelationbetweenthermalcyclingandthemicrostructuresofx100pipelinesteellaserweldedjoints
AT zongxiangyao quantitativecorrelationbetweenthermalcyclingandthemicrostructuresofx100pipelinesteellaserweldedjoints
_version_ 1724800348965568512

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