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Influence of equal channel angular pressing on high cycle fatigue behavior of ultrafine-grained iron: role of anisotropy
journal contribution
posted on 2018-01-10, 00:00 authored by E Bruder, C Gangaraju, Rimma LapovokRimma LapovokThe high cycle fatigue behavior of ARMCO® Iron processed by equal-channel angular pressing (ECAP) was investigated for routes A and BC, which results in ultrafine-grained microstructures with high and low grain elongations, respectively. Rotating bending fatigue tests along two different testing directions show a significant anisotropy in the fatigue strength for route BCbut only marginal differences for route A, in spite of the higher grain elongation and stronger crystallographic texture that is generated by route A. Still, the fatigue damage at the surface of samples processed by route A is highly anisotropic, as it is confined to regions with a certain alignment of the microstructural elongation plane with regard to the surface plane. The anisotropy in high cycle fatigue strength for route BCas well as the surface orientation dependent resistance to fatigue damage for route A are discussed with regard to the alignment of the shear plane during the last ECAP pass and the correlation between the microstructural morphology and subgrain coarsening that lead to fatigue crack initiation.
History
Journal
Materials science and engineering AVolume
711Pagination
650 - 658Publisher
ElsevierLocation
Amsterdam, The NetherlandsPublisher DOI
ISSN
0921-5093Language
engPublication classification
C1 Refereed article in a scholarly journalCopyright notice
2017, ElsevierUsage metrics
Keywords
Science & TechnologyTechnologyNanoscience & NanotechnologyMaterials Science, MultidisciplinaryMetallurgy & Metallurgical EngineeringScience & Technology - Other TopicsMaterials ScienceFatigueSevere plastic deformation (SPD)Ultrafine grained microstructuresAnisotropyIron alloysElectron microscopySEVERE PLASTIC-DEFORMATIONINTERSTITIAL-FREE STEELNANOSTRUCTURED MATERIALSCRACK GROWTHECAPREFINEMENTSUPERPLASTICITYMECHANISMSEXTRUSIONTEXTUREMechanical Engineering
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