AFRL Additive Manufacturing Modeling Series: Challenge 4, In Situ Mechanical Test of an IN625 Sample with Concurrent High-Energy Diffraction Microscopy Characterization

AFRL Additive Manufacturing Modeling Series: Challenge 4, In Situ Mechanical Test of an IN625 Sample with Concurrent High-Energy Diffraction Microscopy Characterization

We describe 3D characterization of an additively manufactured Inconel 625 nickel-base superalloy specimen conducted during a uniaxial tension test using a suite of nondestructive x-ray techniques. High-energy diffraction microscopy in both near- and far-field modalities are employed in situ to track...

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Veröffentlicht in:Integrating materials and manufacturing innovation 2021-09, Vol.10 (3), p.338-347
Hauptverfasser: Menasche, David B., Musinski, William D., Obstalecki, Mark, Shah, Megna N., Donegan, Sean P., Bernier, Joel V., Kenesei, Peter, Park, Jun-Sang, Shade, Paul A.
Format: Artikel
Sprache:eng
Schlagworte:
Additive manufacturing
Characterization and Evaluation of Materials
Chemistry and Materials Science
Computed tomography
Data transmission
Field tests
HEDM
materials characterization
MATERIALS SCIENCE
Mechanical tests
Metal Additive Manufacturing Modeling Challenge Series 2020
Metallic Materials
Microscopy
microstructure
Modelling
Nanotechnology
Nickel base alloys
Nondestructive testing
Strain
Structural Materials
Superalloys
Surfaces and Interfaces
synchrotron
Tension tests
Thematic Section: Metal Additive Manufacturing Modeling Challenge Series 2020
Thin Films
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Zusammenfassung:We describe 3D characterization of an additively manufactured Inconel 625 nickel-base superalloy specimen conducted during a uniaxial tension test using a suite of nondestructive x-ray techniques. High-energy diffraction microscopy in both near- and far-field modalities are employed in situ to track evolution of the material orientation and stress–strain fields at six points during the mechanical test, and these data streams are registered with micro-computed tomography reconstructions which probe the material density. This data volume was matched to a multi-modal serial sectioning characterization of the specimen taken after loading, described in this article’s companion. Twenty-eight grains which were monitored throughout the experiment were selected to form the basis for AFRL AM Modeling Series Challenge 4, Microscale Structure-to-Properties.
ISSN:2193-9764
2193-9772
DOI:10.1007/s40192-021-00218-3