INTECIN   20395
INSTITUTO DE TECNOLOGIAS Y CIENCIAS DE LA INGENIERIA "HILARIO FERNANDEZ LONG"
Unidad Ejecutora - UE
artículos
Título:
An Al–Si–Ti hierarchical metal–metal composite manufactured by co-spray
Autor/es:
A. KELLY; J. MI; G. SINHA; P. KRUG; F. CROSA; F. AUDEBERT; P. GRANT
Revista:
JOURNAL OF MATERIALS PROCESSING TECHNOLOGY
Editorial:
ELSEVIER SCIENCE SA
Referencias:
Año: 2011 vol. 211 p. 2045 - 2049
ISSN:
0924-0136
Resumen:
Spray forming with co-injection of a solid particulate phase to form a homogeneous distribution within the final spray formed billet has been studied as a new route to manufacturing metal–metal composites at large scale with negligible oxide. 12 wt%Ti particles were co-injected into an atomised Al alloy droplet spray and co-deposited to form a ∼300 kg billet at Peak Werkstoff GmbH, Germany. The microstructure comprised refined equiaxed -Al grains (∼5 um), spherical Si particles (∼1 um) and uniformly distributed Ti particles (∼80 um). Sections of the billet were extruded under a range of conditions into long strips 20 mm wide and 6 mm, 2.5 mm and 1 mm thickness. At high strains, the Ti particles were deformed into continuous fibres of a few microns in thickness. The large interfacial area between the fcc -Al and hcp Ti inhibited dislocation motion and enhanced tensile properties. Accumulative roll bonding was then performed to higher total strains, while maintaining a constant cross-section, reducing the Ti fibres to sub-micron thickness. The fibres were studied by extraction after selective dissolution of the -Al matrix.There was no interfacial reaction between -Al and Ti or any measurable oxide formation.∼300 kg billet at Peak Werkstoff GmbH, Germany. The microstructure comprised refined equiaxed -Al grains (∼5 um), spherical Si particles (∼1 um) and uniformly distributed Ti particles (∼80 um). Sections of the billet were extruded under a range of conditions into long strips 20 mm wide and 6 mm, 2.5 mm and 1 mm thickness. At high strains, the Ti particles were deformed into continuous fibres of a few microns in thickness. The large interfacial area between the fcc -Al and hcp Ti inhibited dislocation motion and enhanced tensile properties. Accumulative roll bonding was then performed to higher total strains, while maintaining a constant cross-section, reducing the Ti fibres to sub-micron thickness. The fibres were studied by extraction after selective dissolution of the -Al matrix.There was no interfacial reaction between -Al and Ti or any measurable oxide formation.