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Study on Weldability of EN 10025-6 S550 QT Steel


Affiliations
1 Engineering Workshop, Larsen & Toubro Limited, India
2 Larsen & Toubro Limited, India
     

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Cracks developed in the 90 mm thick EN 10025-6 S550 QT steel plates assembled to form a box unit. After assembly the surface cracks generated longitudinally along the elongated grains while preheating or performing ischolar_main run. Root cause analysis was conducted to investigate the reason for the failure and also how to specify the “conditions of materials on delivery” during procurement is generated. Various tests such as visual test, chemical composition, inclusion rating, microstructure, dye penetrant test and hardness tests were conducted. The investigation revealed that the failure cracks could be due to temper embrittlement due to the segregations of impurities such as tin, arsenic, phosphorus and antimony, etc. in the grain boundaries and resulted in ductile to brittle transformation when exposed in the temperature. It is observed that, depends on the concentration of Ti and N in steel, coarse and cuboidal TiN particles of several micrometers in size act as potential sites for cleavage crack initiation. Furthermore, during the steel making process if sulfur is not properly controlled, then large MnS inclusions can also form during solidification. Soft MnS inclusions elongate during the subsequent hot rolling process, which deteriorate ductility and impact toughness. Hence, it is essential to specify the J factor value and inclusion rate during the procurement of steel.

Keywords

Inclusion Rate, Welding, Quenched Hardened Steel, Tempering, J-factor.
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  • Anmark N, Karasev A and Jonsson PG (2015); The effect of different non-metallic inclusions on the machinability of steels, Materials 8, pp. 751-783. doi:10.3390/ma 8020751.
  • Grosse-Wordemann J and Dittrich S (1983); Prevention of temper embrittlement in 21/4 Cr-1 Mo weld metal by metallurgical action, Welding Journal, 10(5) pp. 123s 128s.
  • American Society for Metals, Volume 4.

Abstract Views: 397

PDF Views: 5




  • Study on Weldability of EN 10025-6 S550 QT Steel

Abstract Views: 397  |  PDF Views: 5

Authors

K. Prakash
Engineering Workshop, Larsen & Toubro Limited, India
R. Kumar
Larsen & Toubro Limited, India
M. V. Venkatesan
Larsen & Toubro Limited, India
P. Dinesh Kumar
Engineering Workshop, Larsen & Toubro Limited, India

Abstract


Cracks developed in the 90 mm thick EN 10025-6 S550 QT steel plates assembled to form a box unit. After assembly the surface cracks generated longitudinally along the elongated grains while preheating or performing ischolar_main run. Root cause analysis was conducted to investigate the reason for the failure and also how to specify the “conditions of materials on delivery” during procurement is generated. Various tests such as visual test, chemical composition, inclusion rating, microstructure, dye penetrant test and hardness tests were conducted. The investigation revealed that the failure cracks could be due to temper embrittlement due to the segregations of impurities such as tin, arsenic, phosphorus and antimony, etc. in the grain boundaries and resulted in ductile to brittle transformation when exposed in the temperature. It is observed that, depends on the concentration of Ti and N in steel, coarse and cuboidal TiN particles of several micrometers in size act as potential sites for cleavage crack initiation. Furthermore, during the steel making process if sulfur is not properly controlled, then large MnS inclusions can also form during solidification. Soft MnS inclusions elongate during the subsequent hot rolling process, which deteriorate ductility and impact toughness. Hence, it is essential to specify the J factor value and inclusion rate during the procurement of steel.

Keywords


Inclusion Rate, Welding, Quenched Hardened Steel, Tempering, J-factor.

References





DOI: https://doi.org/10.22486/iwj%2F2018%2Fv51%2Fi4%2F176796