A cellular automaton (CA)-finite element (FE) model and a phase field (PF)-FE model were used to simulate equiaxed dendritic growth during the solidification of hexagonal metals. In the CA-FE model, the conservation equations of mass and energy were solved in order to calculate the temperature field, solute concentration, and the dendritic growth morphology. CA-FE simulation results showed reasonable agreement with the previously reported experimental data on secondary dendrite arm spacing (SDAS) vs cooling rate. In the PF model, a PF variable was used to distinguish solid and liquid phases similar to the conventional PF models for solidification of pure materials. Another PF variable was considered to determine the evolution of solute concentration. Validation of both models was performed by comparing the simulation results with the analytical model developed by Lipton-Glicksman-Kurz (LGK), showing quantitatively good agreement in the tip growth velocity at a given melt undercooling. Application to magnesium alloy AZ91 (approximated with the binary Mg-8.9 wt% AI) illustrates the difficulty of modeling dendrite growth in hexagonal systems using CA-FE regarding mesh-induced anisotropy and a better performance of PF-FE in modeling multiple arbitrarily-oriented dendrites growth.
参考文献
| [1] | J. A. WARREN;W. J. BOETTINGER .PREDICTION OF DENDRITIC GROWTH AND MICROSEGREGATION PATTERNS IN A BINARY ALLOY USING THE PHASE-FIELD METHOD[J].Acta Metallurgica et Materialia,1995(2):689-703. |
| [2] | M. F. ZHU;C. P. HONG .Modeling of Irregular Eutectic Microstructures in Solidification of Al-Si Alloys[J].Metallurgical and Materials Transactions, A. Physical Metallurgy and Materials Science,2004(5):1555-1563. |
| [3] | Y. H. SHIN;C. P. HONG .Modeling of Dendritic Growth with Convection Using a Modified Cellular Automaton Model with a Diffuse Interface[J].ISIJ International,2002(4):359-367. |
| [4] | W. Wang;P. D. Lee;M. McLean .A model of solidification microstructures in nickel-based superalloys: predicting primary dendrite spacing selection[J].Acta materialia,2003(10):2971-2987. |
| [5] | B. Bottger;J. Eiken;I. Steinbach .Phase field simulation of equiaxed solidification in technical alloys[J].Acta materialia,2006(10):2697-2704. |
| [6] | Z. Y. Liu;Q. Y. Xu;B. C. Liu .Dendrite growth modelling of cast magnesium alloy[J].International Journal Cast Metals Research,2007(3):109-112. |
| [7] | A. Jacot;M. Rappaz .A pseudo-front tracking technique for the modelling of solidification microstructures in multi-component alloys[J].Acta materialia,2002(8):1909-1926. |
| [8] | Q. Du;A. Jacot .A two-dimensional microsegregation model for the description of microstructure formation during solidification in multicomponent alloys: Formulation and behaviour of the model[J].Acta materialia,2005(12):3479-3793. |
| [9] | L. NASTAC .NUMERICAL MODELING OF SOLIDIFICATION MORPHOLOGIES AND SEGREGATION PATTERNS IN CAST DENDRITIC ALLOYS[J].Acta materialia,1999(17):4253-4262. |
| [10] | D. Danilov;B. Nestler .Phase-field modelling of solute trapping during rapid solidification of a Si-As alloy[J].Acta materialia,2006(18):4659-4664. |
| [11] | M. Asle-Zaeem;S.Dj. Mesarovic.Investigation of Phase Transformation in Thin Film UsingFinite Element Method[J].Diffusion and Defect Data. Solid State Data, Part B. Solid State Phenomena,2009:29-41. |
| [12] | D. Dube;A. Couture;Y. Carbonneat;M. Fiset;R. Angers;R. Tremblay .Secondary dendrite arm spacings in magnesium alloy AZ91D: from plaster moulding to laser remelting[J].International Journal Cast Metals Research,1998(3):139-144. |
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