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Title: Heat-affected zone toughness of a TMCP steel designed for low-temperature applications

Abstract

The objective of this investigation was to provide a detailed evaluation of the heat-affected zone (HAZ) toughness of a high-strength TMCP steel designed for low-temperature applications. The results form both Charpy-vee notch (CVN) and crack-tip-opening displacement (CTOD) tests conducted on two straight-walled narrow groove welds, produced at energy inputs of 1.5 and 3.0 kJ/mm, show that significantly lower toughness was exhibited by the grain-coarsened HAZ (GCHAZ) compared with the intercritical HAZ (ICHAZ) region. This is explained based on the overall GCHAZ microstructure, and the initiation mechanism which caused failure. For the particular TMCP steel investigated in this study very good ICHAZ toughness properties were recorded using both HAZ Charpy and CTOD tests. In general, this was attributable to the low hardness, relatively fine ferrite microstructure, and the formation of secondary microphases that were not overly detrimental to the toughness. The lower-bound GCHAZ CTOD results obtained for both welds (KAW-L and KAW-H) did not meet the targeted requirement of {delta} = 0.07 mm at {minus}50 C. It was found in both welds that low CTOD toughness was associated with the initiation of fracture from nonmetallic inclusions, which were complex oxides containing Ce, La, and S. The sites were located in themore » subcritical GCHAZ (SCGHAZ) region in the case of the 1.5 kJ/mm weld and in the GCHAZ for the 3.0 kJ/mm weld. Some variation in CVN toughness was observed at different through-thickness locations. Toughness was lowest for the GCHAZ of the weld deposited at 3.0 kJ/mm and was related to the proportion of GCHAZ being samples, which was {approximately} 55% for the bottom compared to 25--30% for that of the top location. Recommendations are proposed on the preferred practices and criteria that should be used in establishing guidelines and specifications for evaluating the HAZ toughness of candidate steels for construction of Arctic class ships.« less

Authors:
; ; ;  [1]
  1. CANMET Minerals and Metals, Ottawa, Ontario (Canada). Materials Technology Lab.
Publication Date:
Sponsoring Org.:
USDOE
OSTI Identifier:
500980
Resource Type:
Journal Article
Journal Name:
Journal of Offshore Mechanics and Arctic Engineering
Additional Journal Information:
Journal Volume: 119; Journal Issue: 2; Other Information: PBD: May 1997
Country of Publication:
United States
Language:
English
Subject:
36 MATERIALS SCIENCE; STEELS; FRACTURE PROPERTIES; HEAT AFFECTED ZONE; SHIPS; ARCTIC REGIONS; MECHANICAL TESTS; MICROSTRUCTURE; WELDED JOINTS; RECOMMENDATIONS

Citation Formats

Gianetto, J A, Braid, J E.M., Bowker, J T, and Tyson, W R. Heat-affected zone toughness of a TMCP steel designed for low-temperature applications. United States: N. p., 1997. Web. doi:10.1115/1.2829055.
Gianetto, J A, Braid, J E.M., Bowker, J T, & Tyson, W R. Heat-affected zone toughness of a TMCP steel designed for low-temperature applications. United States. doi:10.1115/1.2829055.
Gianetto, J A, Braid, J E.M., Bowker, J T, and Tyson, W R. Thu . "Heat-affected zone toughness of a TMCP steel designed for low-temperature applications". United States. doi:10.1115/1.2829055.
@article{osti_500980,
title = {Heat-affected zone toughness of a TMCP steel designed for low-temperature applications},
author = {Gianetto, J A and Braid, J E.M. and Bowker, J T and Tyson, W R},
abstractNote = {The objective of this investigation was to provide a detailed evaluation of the heat-affected zone (HAZ) toughness of a high-strength TMCP steel designed for low-temperature applications. The results form both Charpy-vee notch (CVN) and crack-tip-opening displacement (CTOD) tests conducted on two straight-walled narrow groove welds, produced at energy inputs of 1.5 and 3.0 kJ/mm, show that significantly lower toughness was exhibited by the grain-coarsened HAZ (GCHAZ) compared with the intercritical HAZ (ICHAZ) region. This is explained based on the overall GCHAZ microstructure, and the initiation mechanism which caused failure. For the particular TMCP steel investigated in this study very good ICHAZ toughness properties were recorded using both HAZ Charpy and CTOD tests. In general, this was attributable to the low hardness, relatively fine ferrite microstructure, and the formation of secondary microphases that were not overly detrimental to the toughness. The lower-bound GCHAZ CTOD results obtained for both welds (KAW-L and KAW-H) did not meet the targeted requirement of {delta} = 0.07 mm at {minus}50 C. It was found in both welds that low CTOD toughness was associated with the initiation of fracture from nonmetallic inclusions, which were complex oxides containing Ce, La, and S. The sites were located in the subcritical GCHAZ (SCGHAZ) region in the case of the 1.5 kJ/mm weld and in the GCHAZ for the 3.0 kJ/mm weld. Some variation in CVN toughness was observed at different through-thickness locations. Toughness was lowest for the GCHAZ of the weld deposited at 3.0 kJ/mm and was related to the proportion of GCHAZ being samples, which was {approximately} 55% for the bottom compared to 25--30% for that of the top location. Recommendations are proposed on the preferred practices and criteria that should be used in establishing guidelines and specifications for evaluating the HAZ toughness of candidate steels for construction of Arctic class ships.},
doi = {10.1115/1.2829055},
journal = {Journal of Offshore Mechanics and Arctic Engineering},
number = 2,
volume = 119,
place = {United States},
year = {1997},
month = {5}
}