Joint design influence on hybrid laser arc welding of maraging steel

Hybrid laser arc welding (HLAW) was performed in a single-pass on M250 maraging steel plates of 10-mm thickness with three modified joint designs. A Y-groove joint preparation with included angles (IA) of 16°, 24°, and 30° and root face of 2.5 mm was used. Welding was performed using M250 W2 filler...

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Published inWelding in the world Vol. 68; no. 6; pp. 1611 - 1624
Main Authors Subashini, L., Prabhakar, K. V. Phani, Ghosh, Swati
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 01.06.2024
Springer Nature B.V
Subjects
Aging (metallurgy)
Arc welding
Base metal
Chemistry and Materials Science
Fracture toughness
Grooves
Hardness
Heat treating
Laser beam welding
Laser fusion
Lasers
Maraging steels
Materials Science
Melting
Metallic Materials
Research Paper
Solid Mechanics
Steel plates
Tensile strength
Theoretical and Applied Mechanics
Welded joints
Welding wire
fracture toughness
Maraging steel
Reverted austenite
Laser-hybrid
Fusion zone
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Summary:Hybrid laser arc welding (HLAW) was performed in a single-pass on M250 maraging steel plates of 10-mm thickness with three modified joint designs. A Y-groove joint preparation with included angles (IA) of 16°, 24°, and 30° and root face of 2.5 mm was used. Welding was performed using M250 W2 filler wire. The heat input for welding increased as the IA increased. The composition of weld fusion zone affected the reverted austenite (RA) volume fraction formed on aging. With an increase in base metal melting, the fusion zone was enriched with solute elements such as Ni, Mo, and Ti, ultimately increasing RA after aging. The fusion zone hardness of joints 1 and 2 was in the range 500–550 HV. The fusion zone of joint 3 exhibited a lower hardness of 475–525 HV due to the increased heat input involved in making the joint. When the transverse tensile strength of all welds was comparable to that of the parent metal, a significant reduction in K Ic fracture toughness of fusion zone (FZ) was observed as the RA increased. K Ic fracture toughness values were in the order, base > joint 1 > joint 2 > joint 3. The space between neighboring RA pools was smaller in the laser fusion zone (LFZ) owing to its fine cell size compared to the arc fusion zone (AFZ), and the welds failed by connecting series of cavities that only arise in the RA. LFZ appears to play an important role in determining weld toughness of HLAW welds.
ISSN:0043-2288
1878-6669
DOI:10.1007/s40194-024-01751-3