Microstructure and Damage Mechanisms in Thermomechanically Treated Si-Solution-Strengthened Spheroidal Graphite Cast Iron

Surendra Sujakhu; Sylvie Castagne

doi:10.4028/www.scientific.net/MSF.941.583

Paper Titles

Effect of Heat Treatmemt in (α+γ) Range on Mechanical Properties of Austempered Spheroidal Graphite Cast Iron
p.558

Influence of Annealing Conditions on the Austenite Size at the End of Soaking
p.562

Toward the Development of AHSS for Wear Resistant Applications
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Strengthening Mechanisms in Low Carbon Lath Martensite as Influenced by Austenite Conditioning
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Microstructure and Damage Mechanisms in Thermomechanically Treated Si-Solution-Strengthened Spheroidal Graphite Cast Iron
p.583

Characterisation of Long Term Aging in Esshete 1250 Welds
p.589

Low-Temperature Fracture of Ultrafine-Grained Iron
p.595

Properties of Induction Reversion-Refined Microstructures of AISI 301LN under Monotonic, Cyclic and Rolling Deformation
p.601

Reheat Furnace Thermodynamic, Kinetic and Combustion Considerations for TMCP Processing
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HomeMaterials Science ForumMaterials Science Forum Vol. 941Microstructure and Damage Mechanisms in...

Microstructure and Damage Mechanisms in Thermomechanically Treated Si-Solution-Strengthened Spheroidal Graphite Cast Iron

Abstract:

Spheroidal Graphite Irons (SGIs) are ductile cast irons with toughness and ductility comparable to those of carbon steel. In particular, high silicon Solution Strengthened Ferritic (SSF) SGIs are developed to provide higher strength with excellent ductility suitable for structural applications. The main characteristics of these materials lie in the graphite particles inclusions whose morphology and count greatly influence the mechanical properties and more specifically the fatigue crack initiation and propagation behaviour of the SGI components. In this work, SGIs specimens have been subjected to various thermomechanical treatments in order to analyse the influence of these treatments on the microstructure of the material. Observations of degenerated forms of graphite particles alongside the spheroidal nodules in the microstructure were then used as a basis for correlation with damage mechanisms at the microscale. In static tensile testing, it was observed that the matrix-nodule interface decohesion and plastic deformation of the ferrite matrix were the dominant damage mechanisms. In separately performed fatigue crack initiation and fatigue crack propagation tests, it was confirmed that the graphite particle shape played a decisive role in crack initiation and propagation. The results of the microstructural characterization have been implemented in a computational model for further study of the influence of the microstructure on the fatigue behaviour of these materials.

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Periodical:

Materials Science Forum (Volume 941)

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583-588

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.941.583

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Online since:

December 2018

Authors:

Surendra Sujakhu, Sylvie Castagne*

Keywords:

Damage, Ductile Iron, Fatigue, Graphite, Microstructure, Thermomechanical Treatment

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