On the Primary Solidification of Compacted Graphite Iron: Microstructure Evolution during Isothermal Coarsening

Juan Carlos Hernando; Attila Diószegi

doi:10.4028/www.scientific.net/MSF.925.90

Paper Titles

Degenerated Graphite Growth in Ductile Iron
p.62

Effect of Si and Ni Addition on Graphite Morphology in Heavy-Section Spheroidal Graphite Iron Parts
p.70

The Influence of Trace Elements on the Nature of the Nuclei of the Graphite in Ductile Iron
p.78

The Structure of Cast Irons
p.86

On the Primary Solidification of Compacted Graphite Iron: Microstructure Evolution during Isothermal Coarsening
p.90

Stereological Analysis of the Statistical Distribution of the Size of Graphite Nodules in DI
p.98

X-Ray Imaging of Formation and Growth of Spheroidal Graphite in Ductile Cast Iron
p.104

Evolution of the Macrostructure of Gray Cast Iron from Eutectic to Hypereutectic Composition
p.110

Revisiting Models for Spheroidal Graphite Growth
p.118

HomeMaterials Science ForumMaterials Science Forum Vol. 925On the Primary Solidification of Compacted...

On the Primary Solidification of Compacted Graphite Iron: Microstructure Evolution during Isothermal Coarsening

Abstract:

It is widely accepted that in most commercial hypoeutectic alloys, both static mechanical properties and feeding characteristics during solidification, are extremely linked to the coarseness of the primary phase. It is therefore of critical importance to provide tools to control and predict the coarsening process of the dendritic phase present in hypoeutectic melts. The characterization of the primary phase, a product of the primary solidification, has traditionally been neglected when compared to the eutectic solidification characterization in cast iron investigations. This work presents the morphological evolution of the primary austenite present in a hypoeutectic compacted graphite cast iron (CGI) under isothermal conditions. To that purpose, a base spheroidal graphite cast iron (SGI) material with high Mg content is re-melted in a controlled atmosphere and reversed into a CGI melt by controlling the Mg fading. An experimental isothermal profile is applied to the solidification process of the experimental alloy to promote an isothermal coarsening process of the primary austenite dendrite network during solid and liquid coexistence. Through interrupted solidification experiments, the primary austenite is preserved and observed at room temperature. By application of stereological relations, the primary phase and its isothermal coarsening process are characterized as a function of the coarsening time applied. The microstructural evolution observed in the primary austenite in CGI and the measured morphological parameters show a similar trend to that observed for lamellar graphite cast iron (LGI) in previous investigations. The modulus of the primary austenite, Mγ, and the nearest distance between the centre of gravity of neighbouring austenite particles, Dγ, followed a linear relation with the cube root of coarsening time.

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