Modeling fluid flow in three-dimensional single crystal dendritic structures

Modeling fluid flow in three-dimensional single crystal dendritic structures

Convection during directional solidification can cause defects such as freckles and misoriented grains. To gain a better understanding of conditions associated with the onset of convective instabilities, flow was investigated using three-dimensional (3D) computational fluid dynamics simulations in a...

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Bibliographic Details
Published in:Acta materialia Vol. 58; no. 8; pp. 2864 - 2875
Main Authors: Madison, J., Spowart, J., Rowenhorst, D., Aagesen, L.K., Thornton, K., Pollock, T.M.
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 01-05-2010
Elsevier
Subjects:
Applied sciences
Dendritic growth
Directional solidification
Exact sciences and technology
Metals. Metallurgy
Modeling
Nickel alloys
Permeability
Dendritic growth
Nickel alloys
Permeability
Directional solidification
Modeling
Flow(fluid)
Magnetic permeability
Microstructure
Single crystal
Dendritic structure
Dendrite
Crystalline structure
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Summary:Convection during directional solidification can cause defects such as freckles and misoriented grains. To gain a better understanding of conditions associated with the onset of convective instabilities, flow was investigated using three-dimensional (3D) computational fluid dynamics simulations in an experimentally obtained dendritic network. A serial-sectioned, 3D data set of directionally solidified nickel-base superalloy measuring 2.3 × 2.3 × 1.5 mm was used to determine the permeability for flow parallel and normal to the solidification direction as a function of solid fraction ( f S ). Anisotropy of permeability varies significantly from 0.4 < f S < 0.6. High flow velocity channels exhibit spacings commensurate with primary dendrite arms at the base of the mushy zone but rapidly increase by a factor of three to four towards dendrite tips. Permeability is strongly dependent on interfacial surface area, which reaches a maximum at f S = 0.65. Results from the 3D simulation are also compared with empirical permeability models, and the microstructural origins of departures from these models are discussed.
ISSN:1359-6454
1873-2453
DOI:10.1016/j.actamat.2010.01.014