Mesoscopic modeling of spacing and grain selection in columnar dendritic solidification: Envelope versus phase-field model

Viardin, Alexandre; Založnik, Miha; Souhar, Youssef; Apel, Markus; Combeau, Hervé

doi:10.1016/j.actamat.2016.10.004

Cited by 44 publications

(26 citation statements)

References 49 publications

(68 reference statements)

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“…For our simulations we use the in-house computer code CrystalFOAM, which employs the finite-volume library OpenFOAM [27]. The complete description of CrystalFOAM is available in [15,16].…”

Section: Mesoscopic Envelope Modelmentioning

confidence: 99%

“…Several mesoscopic models exist, such as the dendrite needle network (DNN) model, already applied for equiaxed [8] and columnar dendritic grain growth [9], the cellular-automaton finite-element (CAFE) model [10,11] and the dendrite envelope model. In the envelope model, the complex dendritic structure of a crystal grain is described by means of an envelope, a smooth surface that wraps the tips of the actively growing branches of the dendrite [12,13,14,15,16]. The time-evolution of the envelope is computed by means of an analytical dendrite tip growth model coupled to the numerical solution of the solute concentration in the liquid surrounding the grain.…”

Section: Introductionmentioning

confidence: 99%

“…The time-evolution of the envelope is computed by means of an analytical dendrite tip growth model coupled to the numerical solution of the solute concentration in the liquid surrounding the grain. This method can accurately predict the morphology of the actual dendritic grains for both columnar [14,17,16] and equiaxed morphologies [12,13,15]. The mesoscopic envelope model can be used to simulate solidification phenomena for which interactions at the scale of a group of grains (up to 100 grains) are important, such as grain competition in columnar growth [16], or interactions in equiaxed growth [15].…”

Section: Introductionmentioning

confidence: 99%

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Quantitative 3D mesoscopic modeling of grain interactions during equiaxed dendritic solidification in a thin sample

2019

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A 3D mesoscopic envelope model is used to numerically simulate the experimental X-ray observations of isothermal equiaxed dendritic solidification of a thin sample of Al-20 wt%Cu alloy. We show the evolution of the system composed of multiple grains growing under influence of strong solutal interactions. We emphasize the three-dimensional effects in the thin sample thickness on the growth kinetics, focusing on three aspects: (i) the impact of the third dimension on the solute diffusion, (ii) the influence of the orientation of the preferential grain growth directions 100 on the interactions with the confining sample walls, and (iii) the influence of the grain position along the sample thickness. We demonstrate the importance of considering the three-dimensional structure of the thin samples despite the small thickness. We further show that the mesoscopic envelope model can accurately describe the shape and the time-evolution of the equiaxed grains growing under influence of strong solutal interactions.

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“…For our simulations we use the in-house computer code CrystalFOAM, which employs the finite-volume library OpenFOAM [27]. The complete description of CrystalFOAM is available in [15,16].…”

Section: Mesoscopic Envelope Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Quantitative 3D mesoscopic modeling of grain interactions during equiaxed dendritic solidification in a thin sample

2019

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“…They proposed that the coupling effect of the heat flow direction, the preferred growth direction and the geometrical restriction of the spiral wall makes a contribution to the crystal selection in the spiral passage. There are other simulation methods used to model competitive grain growth, such as envelope method and phase-field model [ 23 ], which still attract researchers’ attentions.…”

Section: Introductionmentioning

confidence: 99%

Simulation and Experimental Studies on Grain Selection and Structure Design of the Spiral Selector for Casting Single Crystal Ni-Based Superalloy

Zhang

2017

Materials

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Grain selection is an important process in single crystal turbine blades manufacturing. Selector structure is a control factor of grain selection, as well as directional solidification (DS). In this study, the grain selection and structure design of the spiral selector were investigated through experimentation and simulation. A heat transfer model and a 3D microstructure growth model were established based on the Cellular automaton-Finite difference (CA-FD) method for the grain selector. Consequently, the temperature field, the microstructure and the grain orientation distribution were simulated and further verified. The average error of the temperature result was less than 1.5%. The grain selection mechanisms were further analyzed and validated through simulations. The structural design specifications of the selector were suggested based on the two grain selection effects. The structural parameters of the spiral selector, namely, the spiral tunnel diameter (dw), the spiral pitch (hb) and the spiral diameter (hs), were studied and the design criteria of these parameters were proposed. The experimental and simulation results demonstrated that the improved selector could accurately and efficiently produce a single crystal structure.

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“…An additional contribution that lowers the solid fraction is the segregation of solute that transports solute by diffusion through the mushy zone towards the tips. In steady-state directional solidification, this segregation results in an increased average solute concentration (C > C 0 ) behind the tips and thus delays solidification [21,2]. The difference near the base of the mushy zone is due to the fact that the phase field simulation includes diffusion in the solid, while the Scheil equation does not [2].…”

Section: Application Of Volume Averaging In a Columnar Mushy Zonementioning

confidence: 99%

Evolution of a mushy zone in a static temperature gradient using a volume average approach

et al. 2017

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A volume average model to study the transition of a semi-solid mushy zone to a planar solid/liquid interface in a static temperature gradient is presented. This model simulates the principal phenomena governing mushy zone dynamics including solute diffusion in the interdendritic and bulk liquids, migration of both the solid-liquid interface and the mushy-liquid boundary at the bottom and top of the mushy zone, and solidification. The motion of the solid-liquid interface is determined analytically by performing a microscopic solute balance between the solid and mushy zones. The motion of the mushy-liquid boundary is more complex as it consists of a transition between the mushy and bulk liquid zones with rapidly changing macroscopic properties. In order to simulate this motion, a control volume characterized by continuity in the solute concentration and a jump in both the liquid fraction and the solute concentration gradient was developed. The volume average model has been validated by comparison against prior in-situ X-ray radiography measurements [1], and phase-field simulations [2] of the mushy-to-planar transition in an Al-Cu alloy. A very good similarity was achieved between the observed experimental and phase-field dynamics with this new model even though the described system was only one-dimensional. However, an augmentation of the solute diffusion coefficient in the bulk liquid was required in order to mimic the convective solute transport occurring in the in situ X-ray study. This new model will be useful for simulating a wide range of natural and engineering processes.

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Mesoscopic modeling of spacing and grain selection in columnar dendritic solidification: Envelope versus phase-field model

Cited by 44 publications

References 49 publications

Quantitative 3D mesoscopic modeling of grain interactions during equiaxed dendritic solidification in a thin sample

Quantitative 3D mesoscopic modeling of grain interactions during equiaxed dendritic solidification in a thin sample

Simulation and Experimental Studies on Grain Selection and Structure Design of the Spiral Selector for Casting Single Crystal Ni-Based Superalloy

Evolution of a mushy zone in a static temperature gradient using a volume average approach

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