The Effect of Carbon Equivalent and Nodularity on Multi-axial Casting Wall Movement during Spheroidal Graphite Iron Solidification and Cooling

Noah J. Brack; Mingzhi Xu; Jingjing Qing; Simon Lekakh

doi:10.1007/s40962-025-01668-7

The Effect of Carbon Equivalent and Nodularity on Multi-axial Casting Wall Movement during Spheroidal Graphite Iron Solidification and Cooling

Noah J. Brack, Mingzhi Xu, Jingjing Qing, Simon Lekakh

Research output: Contribution to journal › Article › peer-review

Abstract

Spheroidal graphite iron, also known as ductile iron, is an iron–carbon casting alloy used in industry for its good castability, balanced mechanical properties, and low cost. Ductile iron consists of round graphite nodules in an iron matrix. During solidification and cooling, ductile iron castings experience dynamic volume changes due to the precipitation of graphite nodules and formation of austenite. These dynamic volume changes can distort external casting surfaces, causing swell and shrinkage porosity. A novel apparatus was custom-built to capture the casting wall movement in real time along three axes. This study found that casting expansion increased with carbon equivalent and decreased with nodularity.

Original language	English
Journal	International Journal of Metalcasting
DOIs	https://doi.org/10.1007/s40962-025-01668-7
State	Published - Jun 17 2025

Scopus Subject Areas

Mechanics of Materials
Industrial and Manufacturing Engineering
Metals and Alloys
Materials Chemistry

Keywords

casting
ductile iron
porosity
shrinkage
swell
wall movement

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10.1007/s40962-025-01668-7

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title = "The Effect of Carbon Equivalent and Nodularity on Multi-axial Casting Wall Movement during Spheroidal Graphite Iron Solidification and Cooling",

abstract = "Spheroidal graphite iron, also known as ductile iron, is an iron–carbon casting alloy used in industry for its good castability, balanced mechanical properties, and low cost. Ductile iron consists of round graphite nodules in an iron matrix. During solidification and cooling, ductile iron castings experience dynamic volume changes due to the precipitation of graphite nodules and formation of austenite. These dynamic volume changes can distort external casting surfaces, causing swell and shrinkage porosity. A novel apparatus was custom-built to capture the casting wall movement in real time along three axes. This study found that casting expansion increased with carbon equivalent and decreased with nodularity.",

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AU - Brack, Noah J.

AU - Xu, Mingzhi

AU - Qing, Jingjing

AU - Lekakh, Simon

N1 - Publisher Copyright: © American Foundry Society 2025.

PY - 2025/6/17

Y1 - 2025/6/17

N2 - Spheroidal graphite iron, also known as ductile iron, is an iron–carbon casting alloy used in industry for its good castability, balanced mechanical properties, and low cost. Ductile iron consists of round graphite nodules in an iron matrix. During solidification and cooling, ductile iron castings experience dynamic volume changes due to the precipitation of graphite nodules and formation of austenite. These dynamic volume changes can distort external casting surfaces, causing swell and shrinkage porosity. A novel apparatus was custom-built to capture the casting wall movement in real time along three axes. This study found that casting expansion increased with carbon equivalent and decreased with nodularity.

AB - Spheroidal graphite iron, also known as ductile iron, is an iron–carbon casting alloy used in industry for its good castability, balanced mechanical properties, and low cost. Ductile iron consists of round graphite nodules in an iron matrix. During solidification and cooling, ductile iron castings experience dynamic volume changes due to the precipitation of graphite nodules and formation of austenite. These dynamic volume changes can distort external casting surfaces, causing swell and shrinkage porosity. A novel apparatus was custom-built to capture the casting wall movement in real time along three axes. This study found that casting expansion increased with carbon equivalent and decreased with nodularity.

KW - casting

KW - ductile iron

KW - porosity

KW - shrinkage

KW - swell

KW - wall movement

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DO - 10.1007/s40962-025-01668-7

M3 - Article

AN - SCOPUS:105008553693

SN - 1939-5981

JO - International Journal of Metalcasting

JF - International Journal of Metalcasting

ER -

The Effect of Carbon Equivalent and Nodularity on Multi-axial Casting Wall Movement during Spheroidal Graphite Iron Solidification and Cooling

Abstract

Scopus Subject Areas

Keywords

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