Modelling of cracking during beam oscillation laser welding of a creep-resistant nickel alloy

Mingze Gao; Tuhin Mukherjee; Todd A. Palmer; Wei Zhang; Tarasankar DebRoy

doi:10.1177/13621718241289300

Modelling of cracking during beam oscillation laser welding of a creep-resistant nickel alloy

Mingze Gao
, Tuhin Mukherjee
, Todd A. Palmer
, Wei Zhang
, Tarasankar DebRoy

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

During high power laser welding of Inconel 740H, horizontal solidification cracks form at locations between approximately 70–80% of the weld depth. With the integration of circular beam oscillation, the laser energy density distribution and underlying thermo-mechanical conditions were altered. By coupling three-dimensional heat transfer, fluid flow, and stress modelling tools, the role that circular beam oscillation plays in the formation of the strain rates and stresses driving this cracking phenomenon was identified. While the addition of a circular oscillation pattern appeared to lower the stress levels along the solidification front, it did not eliminate the appearance of horizontal cracking. Only when the beam amplitudes reached 1.6 mm did solidification cracking disappear, but the weld depths were also significantly reduced.

Original language	English (US)
Pages (from-to)	426-435
Number of pages	10
Journal	Science and Technology of Welding and Joining
Volume	29
Issue number	7-8
DOIs	https://doi.org/10.1177/13621718241289300
State	Published - Nov 1 2024

All Science Journal Classification (ASJC) codes

General Materials Science
Condensed Matter Physics

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10.1177/13621718241289300

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title = "Modelling of cracking during beam oscillation laser welding of a creep-resistant nickel alloy",

abstract = "During high power laser welding of Inconel 740H, horizontal solidification cracks form at locations between approximately 70–80\% of the weld depth. With the integration of circular beam oscillation, the laser energy density distribution and underlying thermo-mechanical conditions were altered. By coupling three-dimensional heat transfer, fluid flow, and stress modelling tools, the role that circular beam oscillation plays in the formation of the strain rates and stresses driving this cracking phenomenon was identified. While the addition of a circular oscillation pattern appeared to lower the stress levels along the solidification front, it did not eliminate the appearance of horizontal cracking. Only when the beam amplitudes reached 1.6 mm did solidification cracking disappear, but the weld depths were also significantly reduced.",

author = "Mingze Gao and Tuhin Mukherjee and Palmer, \{Todd A.\} and Wei Zhang and Tarasankar DebRoy",

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TY - JOUR

T1 - Modelling of cracking during beam oscillation laser welding of a creep-resistant nickel alloy

AU - Gao, Mingze

AU - Mukherjee, Tuhin

AU - Palmer, Todd A.

AU - Zhang, Wei

AU - DebRoy, Tarasankar

N1 - Publisher Copyright: © The Author(s) 2024.

PY - 2024/11/1

Y1 - 2024/11/1

N2 - During high power laser welding of Inconel 740H, horizontal solidification cracks form at locations between approximately 70–80% of the weld depth. With the integration of circular beam oscillation, the laser energy density distribution and underlying thermo-mechanical conditions were altered. By coupling three-dimensional heat transfer, fluid flow, and stress modelling tools, the role that circular beam oscillation plays in the formation of the strain rates and stresses driving this cracking phenomenon was identified. While the addition of a circular oscillation pattern appeared to lower the stress levels along the solidification front, it did not eliminate the appearance of horizontal cracking. Only when the beam amplitudes reached 1.6 mm did solidification cracking disappear, but the weld depths were also significantly reduced.

AB - During high power laser welding of Inconel 740H, horizontal solidification cracks form at locations between approximately 70–80% of the weld depth. With the integration of circular beam oscillation, the laser energy density distribution and underlying thermo-mechanical conditions were altered. By coupling three-dimensional heat transfer, fluid flow, and stress modelling tools, the role that circular beam oscillation plays in the formation of the strain rates and stresses driving this cracking phenomenon was identified. While the addition of a circular oscillation pattern appeared to lower the stress levels along the solidification front, it did not eliminate the appearance of horizontal cracking. Only when the beam amplitudes reached 1.6 mm did solidification cracking disappear, but the weld depths were also significantly reduced.

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U2 - 10.1177/13621718241289300

DO - 10.1177/13621718241289300

M3 - Article

AN - SCOPUS:105004984741

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JO - Science and Technology of Welding and Joining

JF - Science and Technology of Welding and Joining

IS - 7-8

ER -

Modelling of cracking during beam oscillation laser welding of a creep-resistant nickel alloy

Abstract

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