TY - JOUR
T1 - Convection and macrosegregation in Al-19Cu alloy directionally solidified through an abrupt contraction in cross-section
T2 - A comparison with Al-7Si
AU - Ghods, M.
AU - Lauer, M.
AU - Grugel, R. N.
AU - Tewari, S. N.
AU - Poirier, D. R.
N1 - Funding Information:
This work was supported by NASA Grant NX10AV40G and NNX14AM18G. The Al-19% Cu and Al-7% Si alloys for this research were kindly provided by Dr. Men G. Chu at ALCOA Technical Center. M. Lauer would like to acknowledge support from the Sandia National Laboratories Campus Executive Fellowship program.
Publisher Copyright:
© 2016 Elsevier B.V.
PY - 2017/2/1
Y1 - 2017/2/1
N2 - Hypoeutectic Al-19 wt. % Cu alloys were directionally solidified in cylindrical molds that featured an abrupt cross-section decrease 9.5 to 3.2 mm in diameter). Thermo-solutal convection and cross-section-change-induced shrinkage flow effects on macrosegregation were investigated. Dendrite clustering and extensive radial macrosegregation was seen, particularly in the larger cross-section before contraction. This alloy shows positive longitudinal macrosegregation near the contraction followed by negative macrosegregation right after it; the extent of macrosegregation, however, decreases with increasing growth speed. The degree of thermo-solutal convection was compared to another study investigating directional solidification of Al-7 wt. % Si [1] in order to study the effect of solutal expansion coefficient on macrosegregation. An interesting change of the radial macrosegregation profile, attributable to the area-change-induced-shrinkage flow, was observed very close to the contraction. A two-dimensional model accounting for both shrinkage and thermo-solutal convection was used to simulate solidification, the resulting steepling as well as axial and radial macrosegregation. The experimentally observed macrosegregation associated with the contraction during directional solidification was well predicted by the numerical simulations.
AB - Hypoeutectic Al-19 wt. % Cu alloys were directionally solidified in cylindrical molds that featured an abrupt cross-section decrease 9.5 to 3.2 mm in diameter). Thermo-solutal convection and cross-section-change-induced shrinkage flow effects on macrosegregation were investigated. Dendrite clustering and extensive radial macrosegregation was seen, particularly in the larger cross-section before contraction. This alloy shows positive longitudinal macrosegregation near the contraction followed by negative macrosegregation right after it; the extent of macrosegregation, however, decreases with increasing growth speed. The degree of thermo-solutal convection was compared to another study investigating directional solidification of Al-7 wt. % Si [1] in order to study the effect of solutal expansion coefficient on macrosegregation. An interesting change of the radial macrosegregation profile, attributable to the area-change-induced-shrinkage flow, was observed very close to the contraction. A two-dimensional model accounting for both shrinkage and thermo-solutal convection was used to simulate solidification, the resulting steepling as well as axial and radial macrosegregation. The experimentally observed macrosegregation associated with the contraction during directional solidification was well predicted by the numerical simulations.
KW - A1. Computer simulation
KW - A1. Convection
KW - A1. Cross-section decrease
KW - A1. Directional solidification
KW - A1. Segregation
KW - B1. Aluminum alloys
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U2 - 10.1016/j.jcrysgro.2016.11.111
DO - 10.1016/j.jcrysgro.2016.11.111
M3 - Article
AN - SCOPUS:84999711333
SN - 0022-0248
VL - 459
SP - 135
EP - 145
JO - Journal of Crystal Growth
JF - Journal of Crystal Growth
ER -