Determination of damage mechanisms and damage evolution in fiber metal laminates containing friction stir welded thin foils

Determination of damage mechanisms and damage evolution in fiber metal laminates containing friction stir welded thin foils

Synchrotron tomography was carried out during in-situ tensile tests of fiber metal laminates formed by 3 layers of friction stir welded AlMg4.5Sc0.2 (AA5024) alloy foils and 2 layers of glass fiber reinforced polymer. The aim of these investigations was to identify the damage mechanisms and their se...

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Veröffentlicht in:International journal of materials research 2020-01, Vol.111 (1), p.23-31
Hauptverfasser: Mercado, Ulises Alfaro, Sket, Federico, Wilde, Fabian, Besel, Michael, Requena, Guillermo
Format: Artikel
Sprache:eng
Schlagworte:
Aluminum
Damage accumulation
Damage detection
Damage localization
Damage mechanisms
Fiber metal laminates
Fiber reinforced polymers
Friction stir welding
Glass fiber reinforced plastics
Heat treating
Metal foils
Splice-free
Strain localization
Tensile properties
Tensile tests
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Zusammenfassung:Synchrotron tomography was carried out during in-situ tensile tests of fiber metal laminates formed by 3 layers of friction stir welded AlMg4.5Sc0.2 (AA5024) alloy foils and 2 layers of glass fiber reinforced polymer. The aim of these investigations was to identify the damage mechanisms and their sequence during quasi-static loading conditions of the fiber metal laminate as well as to determine microstructural features responsible for tensile damage. The microstructural and geometric changes produced by the friction stir welding process on the aluminum foils resulted in a strain localization and further damage accumulation in the welded aluminum foils, where the smallest transverse areas and lowest tensile properties were found.
ISSN:1862-5282
2195-8556
DOI:10.3139/146.111815