Phase-field study on microstructure formation in Mar-M247 during electron beam welding and correlation to hot cracking susceptibility

Böttger, B.; Apel, Markus; Jokisch, Torsten; Senger, Aleksej

doi:10.1088/1757-899x/861/1/012072

Cited by 9 publications

(4 citation statements)

References 13 publications

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“…The fragmentation phenomenon had been observed by the authors in 2D-simulations of alloy melting under various conditions [22,23], especially when melting homogeneous or homogenized materials, but also for remelting not homogenized material like in this study. However, our systematic approach to reproduce this behaviour with 3D-simulations in this work has failed so far.…”

Section: Discussionsupporting

confidence: 65%

“…The second simulation step was performed using the results of the first simulation as initial microstructure. Reading of the structure was achieved without information loss by a technique using the restart output (.rest) of the former simulation [21,22]. The initial microstructure was shifted in negative z-direction according to the thickness of 40 µm of the new layer.…”

Section: Model Parameters and Datamentioning

confidence: 99%

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Phase-field simulation of the formation of new grains by fragmentation during melting of an ABD900 superalloy

Böttger

Apel

2023

IOP Conf. Ser.: Mater. Sci. Eng.

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Laser powder bed fusion (L-PBF) is an additive manufacturing method which involves local laser melting of powder particles, a partial remelting of previously deposited layers, and subsequent re-solidification under high thermal gradients and cooling rates. The transition between melting and re-solidification becomes visible as melt pool boundaries in optical micrographs and plays a crucial role: Apart from creating a strong segregation zone, the transition determines whether the microstructure is inherited and carried over to the next layer, or whether new grains with new orientations are formed. While heterogeneous nucleation is suppressed due to the lack of seeding particles at the small length scales inherent to L-PBF, alternatively, new grains can form via dendrite fragmentation, as demonstrated in this paper by phase-field simulations using the software MICRESS®. By strong coupling between the phase-field equation and a thermal 1D-cylinder approach for the long-range temperature field, consistency between latent heat and microstructure is ensured. To allow for a systematic variation of the orientation relationship between the dendrite growth direction and the respective temperature gradient, a two-step simulation procedure for two overlapping tracks with variable gradient directions is developed. Growth conditions which promote fragmentation and formation of new grains are analyzed and discussed.

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Section: Discussionsupporting

confidence: 65%

Section: Model Parameters and Datamentioning

confidence: 99%

Phase-field simulation of the formation of new grains by fragmentation during melting of an ABD900 superalloy

Böttger

Apel

2023

IOP Conf. Ser.: Mater. Sci. Eng.

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“…Phase-field simulations of microstructure evolution in general are frequently employed for the description and optimization of the physical and mechanical material behavior at mesoscale [32]. With respect to the present context, we mention the successful simulation application to the solidification of Ni-base superalloys [33][34][35] as well as to microstructure evolution during heat treatment [36][37][38]. Phase-field simulations operate with explicit microstructures, based on a diffuse interface description.…”

Section: Introductionmentioning

confidence: 99%

3D Minimum Channel Width Distribution in a Ni-Base Superalloy

Müller

Böttger

Schleifer

et al. 2023

Integr Mater Manuf Innov

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The strength of a Ni-base superalloy depends strongly on its microstructure consisting of cuboidal $${\gamma }^{^{\prime}}$$ γ ′ precipitates surrounded by narrow channels of $$\gamma $$ γ matrix. According to the theory of Orowan, a moving dislocation has to crimp through the minimal inter-precipitate spacing to admit the plastic deformation. We present a novel approach to evaluate the matrix channel width distribution of a matrix/$${\gamma }^{^{\prime}}$$ γ ′ microstructure in binary representation. Our method relies on precise determination of the matrix/precipitate interfaces and requires no additional user input. For each matrix channel between two neighboring precipitates, we identify the minimal interface to interface distance vector with its length being the channel width. The performance of this method is demonstrated on the example of the commercial alloy CSMX-4. We show that, in contrast to conventional line sectioning approaches, the approach consistently handles experimental 2D micrographs and 3D phase-field simulation data. The identified distance vectors correlate to the underlying crystal symmetry independent of the image orientation. The obtained channel width distributions compare well between the 2D and 3D data. This is in terms of similar median and $$\sigma $$ σ of a log-normal distribution. The presented method overcomes limitations of the conventional line slicing approaches and provides a versatile tool for automated microstructure characterization.

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“…Laser welding [23], electron-beam welding [24], friction stir welding [25,26], and other advanced welding methods generate less welding stress, thereby helping to reduce welding hot cracks; however, these welding methods are not yet practically applicable in repair welding. Recently, electromagnetic welding (EMS) has come to be recognized as an effective method for facilitating bead formation, as well as enhancing the microstructure and mechanical properties of the weld [27][28][29][30][31][32][33].…”

Section: Introductionmentioning

confidence: 99%

Impact of electromagnetic stirring on the gas metal arc welding of an MAR-M247 superalloy

Yu-Chih

Lu²,

Chen

2021

Int J Adv Manuf Technol

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In this paper, the impact of electromagnetic stirring (EMS) on the gas metal arc welding (GATW) of an MAR-M247 superalloy was investigated. Results revealed that, without electromagnetic stirring, it was easy for carbides in the heat-affected zone (HAZ) of the weld bead to liquefy during welding, leading to weld bead cracks. Electromagnetic stirring re ned the grains in the HAZ and the weld bead, leading to grain strengthening and subsequently resulting in the effective improvement in the hardness of the weld bead. In addition, electromagnetic stirring signi cantly facilitated the formation of the weld bead by the removal of large inclusions which in turn effectively improved crack resistance at the joint. It also accelerated the oating up of gas holes thereby reducing the generation of gas hole defects.

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Phase-field study on microstructure formation in Mar-M247 during electron beam welding and correlation to hot cracking susceptibility

Cited by 9 publications

References 13 publications

Phase-field simulation of the formation of new grains by fragmentation during melting of an ABD900 superalloy

Phase-field simulation of the formation of new grains by fragmentation during melting of an ABD900 superalloy

3D Minimum Channel Width Distribution in a Ni-Base Superalloy

Impact of electromagnetic stirring on the gas metal arc welding of an MAR-M247 superalloy

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