Three-dimensional granular model of semi-solid metallic alloys undergoing solidification: Fluid flow and localization of feeding

Sistaninia, M.; Phillion, A.B.; Drezet, Jean‐Marie; Rappaz, M.

doi:10.1016/j.actamat.2012.03.036

Cited by 51 publications

(70 citation statements)

References 22 publications

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“…The hydromechanical coupled model for solidification and semisolid deformation, [3][4][5] which was recently developed by Sistaninia et al uses a granular approach to fulfill the above requirements and simulate hot tearing. The use of a granular approach enables each grain to exist as a discrete element while allowing for efficient simulation of an ensemble of grains making up the microstructure.…”

Section: Introductionmentioning

confidence: 99%

Prediction of Hot Tear Formation in Vertical DC Casting of Aluminum Billets Using a Granular Approach

Sistaninia

Drezet

Phillion

et al. 2013

JOM

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Section: Introductionmentioning

confidence: 99%

Prediction of Hot Tear Formation in Vertical DC Casting of Aluminum Billets Using a Granular Approach

Sistaninia

Drezet

Phillion

et al. 2013

JOM

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“…These bumps are associated with the formation and coalescence of grain clusters as reported by Verne`de et al [26] and Sistaninia et al [27] As soon as those grain clusters tend to weld together, macroscopic tensile strain develops owing to the constrained configuration of the dog-bone-shaped casting and leads to the formation of hot tears as shown in Figure 3. Stresses and strains are then relaxed and the lattice parameter continues to decrease.…”

Section: B Determination Of Rigidity Temperature and Solid Volume Frmentioning

confidence: 84%

“…With the in situ XRD measurements, the lattice parameter is expected to exhibit such a behavior as long as individual grains or grain clusters grow without transmitting any macroscopic tensile strains. [26,27] At mechanical coherency, solid bridges are well established between grains and grain clusters and macroscopic strains and stresses start to develop possibly leading to the formation of micropores and hot tears, as reported in Figure 3.…”

Section: ½2mentioning

confidence: 96%

Measurement of Mechanical Coherency Temperature and Solid Volume Fraction in Al-Zn Alloys Using In Situ X-ray Diffraction During Casting

Drezet

Mireux

Kurtuldu

et al. 2015

Metall Mater Trans A

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During solidification of metallic alloys, coalescence leads to the formation of solid bridges between grains or grain clusters when both solid and liquid phases are percolated. As such, it represents a key transition with respect to the mechanical behavior of solidifying alloys and to the prediction of solidification cracking. Coalescence starts at the coherency point when the grains begin to touch each other, but are unable to sustain any tensile loads. It ends up at mechanical coherency when the solid phase is sufficiently coalesced to transmit macroscopic tensile strains and stresses. Temperature at mechanical coherency is a major input parameter in numerical modeling of solidification processes as it defines the point at which thermally induced deformations start to generate internal stresses in a casting. This temperature has been determined for Al-Zn alloys using in situ X-ray diffraction during casting in a dog-bone-shaped mold. This setup allows the sample to build up internal stress naturally as its contraction is prevented. The cooling on both extremities of the mold induces a hot spot at the middle of the sample which is irradiated by X-ray. Diffraction patterns were recorded every 0.5 seconds using a detector covering a 426 9 426 mm 2 area. The change of diffraction angles allowed measuring the general decrease of the lattice parameter of the fcc aluminum phase. At high solid volume fraction, a succession of strain/stress build up and release is explained by the formation of hot tears. Mechanical coherency temperatures, 829 K to 866 K (556°C to 593°C), and solid volume fractions, ca. 98 pct, are shown to depend on solidification time for grain refined Al-6.2 wt pct Zn alloys.

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“…Results showed that carbide bridging improve cast ability for the same reason. Sistaninia et al (2012) studied grain boundaries as they are the location for solidification cracking. Rappaz et al (2003) showed that intragranular coalescence occurs at a low solid fraction whereas grain coalescence (intergranular) takes place much deeper in the mushy zone at a higher solid fraction around 99%.…”

Section: Introductionmentioning

confidence: 99%

Hot tearing in polycrystalline Ni-based IN738LC superalloy: Influence of Zr content

Heydari

Fard

Bakhshi

et al. 2014

Journal of Materials Processing Technology

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a b s t r a c tZirconium is always present in Ni base superalloys as it enhances their creep properties. In the present study, the influence of very small Zr additions, 100-400 ppm, i.e. 0.01-0.04 wt.%, on hot tearing of IN738LC superalloy is experimentally investigated using dedicated turbine blade castings. Although the Zr content remains very small, it has a strong effect on hot tearing tendency. Microstructure of hot tear in as-cast samples reveal that grain size and secondary dendrite arm spacing have no significant effect on hot tearing. On the other hand eutectic phase volume fraction and its dispersion or spreading along grain boundaries drastically affect the hot tearing propensity and strongly increase with increasing amounts of Zr. Hence grain coalescence becomes impossible at grain boundaries covered with eutectic phase films. With increasing Zr content, gain coalescence between two distinct grains with no interdendritic phase requires more undercooling. Coalescence is retarded and occurs deeper in the mush zone, i.e. at lower temperatures resulting in a higher sensitivity to hot tearing. Finally, it is shown that a reduction of Zr content to 0.02 wt.% is required to fully suppress hot tearing in polycrystalline IN738LC blades.

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Three-dimensional granular model of semi-solid metallic alloys undergoing solidification: Fluid flow and localization of feeding

Cited by 51 publications

References 22 publications

Prediction of Hot Tear Formation in Vertical DC Casting of Aluminum Billets Using a Granular Approach

Prediction of Hot Tear Formation in Vertical DC Casting of Aluminum Billets Using a Granular Approach

Measurement of Mechanical Coherency Temperature and Solid Volume Fraction in Al-Zn Alloys Using In Situ X-ray Diffraction During Casting

Hot tearing in polycrystalline Ni-based IN738LC superalloy: Influence of Zr content

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