J. C. Heinrich scite author profile

The formation of macrosegregation defects known as ''freckles'' was simulated using a three-dimensional finite element model that calculates the thermosolutal convection and macrosegregation during the dendritic solidification of multicomponent alloys. A recently introduced algorithm was used to calculate the complicated solidification path of alloys of many components, which can accommodate liquidus temperatures that are general functions of liquid concentrations. The calculations are started from an all-liquid state, and the growth of the mushy zone is followed in time. Simulations of a Ni-Al-Ta-W alloy were performed on a rectangular cylinder until complete solidification. The results reveal details of the formation of freckles not previously observed in two-dimensional simulations. Liquid plumes in the form of chimney convection emanate from channels within the mushy zone, with similar qualitative features previously observed in transparent systems. Associated with the formation of channels, there is a complex three-dimensional flow produced by the interaction of the different solutal buoyancies of the alloy solutes. Regions of enhanced solid growth develop around the channel mouths, which are visualized as volcanoes on top of the mushy zone. The prediction of volcanoes differs from our previous calculations with multicomponent alloys in two dimensions, in which the volcanoes were not nearly as apparent. These and other features of freckle formation phenomena are illustrated.

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A note on upwinding and anisotropic balancing dissipation in finite element approximations to convective diffusion problems

Kelly

Nakazawa

Zienkiewicz

et al. 1980

Numerical Meth Engineering

175

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SUMMARYIn one dimension, Petrov-Galerkin nonsymmetric weighting for the convective diffusion equation can be interpreted as an added dissipation. The addition of an appropriate amount of dissipation can therefore give the same oscillation-free solutions as the 'upwinding', Petrov-Galerkin, finite element methods. The 'balancing dissipation' is optimally chosen so that excessive dissipation does not occur. A scheme is presented for extending this approach to two-dimensional problems, and numerical examples show that the new method can be used with improved computational efficiency.

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Permeability for cross flow through columnar-dendritic alloys

Bhat

Poirier

Heinrich

1995

Metall Mater Trans B

126

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J. C. Heinrich

Finite element approximation to two-dimensional sine-Gordon solitons

An ‘upwind’ finite element scheme for two‐dimensional convective transport equation

Modeling freckle formation in three dimensions during solidification of multicomponent alloys

A note on upwinding and anisotropic balancing dissipation in finite element approximations to convective diffusion problems

Permeability for cross flow through columnar-dendritic alloys

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