The Degradation of the most Common Stainless Steels: Real Case Issues

Cristina Mosca; Christian Paglia; Albert Jornet

doi:10.4028/p-0fs6pa

Paper Titles

Thin Wire Casting Using Twin Wheel Caster Equipped with Horizontal Wheels
p.19

Numerical Simulation of CNC Incremental Forming of Straight Wall Parts Based on Model Partition and Non-Steep Surface
p.26

Influence of Different Zoning on Part Thickness in the Multi-Stage Incremental Forming Based on the Extrusion from the Forward and Reverse Side of the Sheet
p.33

Effect of Orbital Welding Parameters on the Weld Geometry
p.41

The Degradation of the most Common Stainless Steels: Real Case Issues
p.49

Study on Corrosion Behavior of Simulated Welding Microstructure of Austenitic Stainless Steel
p.55

Study on Corrosion Tendency Evaluation of Microstructure in Welding Heat Affected Zone of Austenitic Stainless Steel
p.60

Study on Grain Boundary Sensitization in Heat Affected Zone of Austenitic Stainless Steel and its Evaluation Method
p.65

Identification of Material Viscoelastic Properties using the Motion of a Rigid Sphere Located at Tissue-Mimicking Material Interface in Response to a Dynamic Force
p.73

HomeMaterials Science ForumMaterials Science Forum Vol. 1066The Degradation of the most Common Stainless...

The Degradation of the most Common Stainless Steels: Real Case Issues

Abstract:

Stainless steel may be susceptible to localized corrosion. Despite this fact, still too many infrastructures are planned with an inadeguate metal chemical composition or placed in wrong environments. In most cases, a clear underestimation of these factors affects the stainless steel durability. These unexpected issues cause a significant technical and economical impact. In this work, several case studies of Inox exposed to unfavorable environmental conditions are presented. A wide range of structures, such as house handles, a swimming pool, a parapet, an industry plant and a waste water collection tank are investigated with respect to the corrosion behavior. Temperature and humidity cyclic variation, promote the enrichments of aggressive agents and lead to degradation. A too low Molybdenum content of the steels is inadequate for some type of structures and service conditions. The weldability changes depending on the steel type and along the thermally affected zones, intergranular corrosion may appear. In addition, a galvanic contact of the stainless steel with existing low alloyed steels components promotes the deterioration of the latter.

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Periodical:

Materials Science Forum (Volume 1066)

Pages:

49-54

DOI:

https://doi.org/10.4028/p-0fs6pa

Citation:

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Online since:

July 2022

Authors:

Cristina Mosca, Christian Paglia*, Albert Jornet

Keywords:

Atmospheric Corrosion, Chloride, Infrastructure, Stainless Steels

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* - Corresponding Author

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