DocumentCode
3437964
Title
Notice of Retraction
Assessing the effects of the welding processes on the environmental strength of an multi-pass welded A106 Gr B steel pipe
Author
Gyu Young Lee ; Young Soo Park ; Dong Ho Bae
Author_Institution
R&D Center, KNR Syst., Hwasung, South Korea
fYear
2013
fDate
15-18 July 2013
Firstpage
762
Lastpage
766
Abstract
Notice of Retraction
After careful and considered review of the content of this paper by a duly constituted expert committee, this paper has been found to be in violation of IEEE´s Publication Principles.
We hereby retract the content of this paper. Reasonable effort should be made to remove all past references to this paper.
The presenting author of this paper has the option to appeal this decision by contacting TPII@ieee.org.
The fusion welding process generates formidable welding residual stresses and metallurgical change, which increase the crack driving force and reduce the resistance of the brittle fracture as well as the environmental fracture. This is a serious problem with many alloys as well as the A106 Gr B steel pipe. This pipe is used in petrochemical and heavy chemical plants either degrades due to corrosive environments, e.g., chlorides and sulfides, and/or become damaged during service due to the various corrosion damage mechanisms. In particular, environmental strength of the multipass welded A106 Gr B steel pipe is influenced considerably by welding technology, welding condition, heat input, etc. On the base of this understanding, in this study, a sulfide stress corrosion cracking tests, which is based on the NACE TM 0177-90, on multipass welded A106 Gr B steel pipe was conducted in 3.5wt.% NaCl solution saturated with H2S gas at room temperature. And SSCC resistance according to the various welding processes was assessed. From the results, the welds by FCAW and GTAW+FCAW showed the good resistance against SSCC.
After careful and considered review of the content of this paper by a duly constituted expert committee, this paper has been found to be in violation of IEEE´s Publication Principles.
We hereby retract the content of this paper. Reasonable effort should be made to remove all past references to this paper.
The presenting author of this paper has the option to appeal this decision by contacting TPII@ieee.org.
The fusion welding process generates formidable welding residual stresses and metallurgical change, which increase the crack driving force and reduce the resistance of the brittle fracture as well as the environmental fracture. This is a serious problem with many alloys as well as the A106 Gr B steel pipe. This pipe is used in petrochemical and heavy chemical plants either degrades due to corrosive environments, e.g., chlorides and sulfides, and/or become damaged during service due to the various corrosion damage mechanisms. In particular, environmental strength of the multipass welded A106 Gr B steel pipe is influenced considerably by welding technology, welding condition, heat input, etc. On the base of this understanding, in this study, a sulfide stress corrosion cracking tests, which is based on the NACE TM 0177-90, on multipass welded A106 Gr B steel pipe was conducted in 3.5wt.% NaCl solution saturated with H2S gas at room temperature. And SSCC resistance according to the various welding processes was assessed. From the results, the welds by FCAW and GTAW+FCAW showed the good resistance against SSCC.
Keywords
arc welding; fusion welding; internal stresses; pipes; steel; stress corrosion cracking; A106 Gr B steel pipe degradation; FCAW; FeCMnSiPSNiCrMoTiCu; GTAW; SSCC resistance; brittle fracture; corrosion damage mechanisms; crack driving force; environmental strength; flux cored arc welding; fusion welding; gas tungsten arc welding; metallurgical change; multipass welding; residual stresses; sulfide stress corrosion cracking tests; Corrosion; Residual stresses; Resistance; Steel; Welding; heat affected zone; residual stress; sulfide stress corrosion cracking (SSCC); welding; welding process;
fLanguage
English
Publisher
ieee
Conference_Titel
Quality, Reliability, Risk, Maintenance, and Safety Engineering (QR2MSE), 2013 International Conference on
Conference_Location
Chengdu
Print_ISBN
978-1-4799-1014-4
Type
conf
DOI
10.1109/QR2MSE.2013.6625684
Filename
6625684
Link To Document