Oxidation Resistant Cast Iron for High Temperature Application

Nico Scheidhauer; Claudia Dommaschk; Gotthard Wolf

doi:10.4028/www.scientific.net/MSF.925.393

Paper Titles

Plastic Deformation and Creep of Two Ductile Cast Irons, SiMo51 and SiMo1000, during Thermal Cycling with Large Strains
p.361

High-Temperature Corrosion-Fatigue Behavior of Ductile Cast Irons for Exhaust Manifolds Applications
p.369

Thermo-Mechanical Fatigue of Grey Cast Iron for Cylinder Heads - Effect of Niobium, Molybdenum and Solidification Time
p.377

High Temperature Strength of Cast Irons for Cylinder Heads
p.385

Oxidation Resistant Cast Iron for High Temperature Application
p.393

Effect of C Content on High Temperature Erosive Wear Characteristics of Fe-Based V Containing Multi-Component Cast Steel with Ni
p.400

Prediction of Shrinkage Defects in Iron Castings Using a Microporosity Model
p.411

Modelling Approach and Challenges in Simulating Dross Formation in Ductile Iron Castings
p.419

Three-Dimensional Microstructural Characterization of Cast Iron Alloys for Numerical Analyses
p.427

HomeMaterials Science ForumMaterials Science Forum Vol. 925Oxidation Resistant Cast Iron for High Temperature...

Oxidation Resistant Cast Iron for High Temperature Application

Abstract:

This paper focusses on the development of materials for exhaust gas components. The present work will focus on a ferritic SiMo-cast iron to create an economic alternative to the austenitic D5S. Aluminum and silicon are essential for this material development because they increase the transformation temperature. They also improve the durability of the protective oxide layer. Additionally, aluminum improves the high temperature mechanical properties by precipitation of a kappa-phase. The ferritic SiMoAl cast iron shows very good oxidation resistance and also mechanical properties.

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Periodical:

Materials Science Forum (Volume 925)

Pages:

393-399

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.925.393

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Online since:

June 2018

Authors:

Nico Scheidhauer*, Claudia Dommaschk, Gotthard Wolf

Keywords:

Aluminum Alloyed Ferritic SiMo Cast Iron, Austenitic D5S, Oxidation Resistance, Oxide Layer Thickness

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