Welding and repairing of nickel-base alloys and superalloys plays a crucial role in developing a new sustainability-based world. High power density welding is preferred to conventional arc welding because of its lower heat input that minimizes heat-induced alterations to the material. However, when dealing with nickel-base alloys, the challenge is to obtain a sound joint while avoiding the formation of solidification cracks. The present work is aimed at summarizing the preliminary results of a numerical study about the effects of laser welding parameters on thermal and mechanical fields of IN792 butt-welded joints. The effects of preheating temperature, heat input and welding speed on thermal and residual stress were investigated. Finally, some melt-run trials were carried out and the structural integrity of the obtained samples was discussed based on the numerical results.
Computational welding mechanics-based approach for the optimization of process parameters in laser welding of IN792 nickel-base alloy / Ferro, P.; Varone, A.; Angella, G.; Cognini, F.; Montanari, R.; Berto, F.; Bonollo, F.; Barbieri, G.; Bergamini, F.. - 68:(2025), pp. 988-1002. ( 24th European Conference on Fracture, ECF 2024 Zagreb, Croatia ) [10.1016/j.prostr.2025.06.161].
Computational welding mechanics-based approach for the optimization of process parameters in laser welding of IN792 nickel-base alloy
Berto F.;
2025
Abstract
Welding and repairing of nickel-base alloys and superalloys plays a crucial role in developing a new sustainability-based world. High power density welding is preferred to conventional arc welding because of its lower heat input that minimizes heat-induced alterations to the material. However, when dealing with nickel-base alloys, the challenge is to obtain a sound joint while avoiding the formation of solidification cracks. The present work is aimed at summarizing the preliminary results of a numerical study about the effects of laser welding parameters on thermal and mechanical fields of IN792 butt-welded joints. The effects of preheating temperature, heat input and welding speed on thermal and residual stress were investigated. Finally, some melt-run trials were carried out and the structural integrity of the obtained samples was discussed based on the numerical results.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
