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Effect of buoyancy and externally induced forces on the solidification of binary mixtures. Final report, August 1, 1987--July 31, 1997

Technical Report ·
DOI:https://doi.org/10.2172/564289· OSTI ID:564289

Research performed under this contract originated with the premise that much could be done to improve existing techniques for modeling the effects of convection on solidification in mixtures by eliminating arbitrary characterizations of the mushy region and its coupling with the melt. It was therefore proposed that a set of continuum conservation equations be derived from the principles of classical mixture theory and that the model concurrently treat melt, mushy and solid regions as a single domain (a continuum). The conservation equations would accommodate all pertinent convection effects, and closure would be achieved by assuming local composition equilibrium at phase interfaces. The need for simplifying assumptions concerning the geometric regularity of the interfaces would be eliminated, along with the need for separately tracking the interfaces and using moving numerical grids and/or coordinate mapping procedures. Accordingly, specific objectives of the work have been to (i) develop models and procedures for simultaneously solving the coupled set of conservation equations which govern mass, momentum, energy and species transfer for solidification in a mixture, (ii) use the models to predict, as a function of time and over a representative range of operating conditions, velocity, temperature, and composition fields throughout solid, mushy and liquid regions of analog and metal alloys, (iii) validate model predictions by visualizing flows and performing temperature and concentration measurements under test cell conditions which simulate those of the computations, and (iv) delineate mechanisms responsible for macrosegregation and develop control strategies for its suppression. Studies were performed for the unidirectional solidification of NH{sub 4}Cl-H{sub 2}O and Pb-Sn and Pb-Sn-Sb alloys.

Research Organization:
Purdue Univ., Lafayette, IN (United States). School of Mechanical Engineering
Sponsoring Organization:
USDOE Office of Energy Research, Washington, DC (United States)
DOE Contract Number:
FG02-87ER13759
OSTI ID:
564289
Report Number(s):
DOE/ER/13759--T1; ON: DE98002608
Country of Publication:
United States
Language:
English

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Related Subjects

36 MATERIALS SCIENCE
AMMONIUM CHLORIDES
ANTIMONY ALLOYS
BINARY ALLOY SYSTEMS
BINARY MIXTURES
CONVECTION
LEAD ALLOYS
MATHEMATICAL MODELS
PROGRESS REPORT
RESEARCH PROGRAMS
SOLIDIFICATION
TIN ALLOYS
WATER