6533b85cfe1ef96bd12bd200

RESEARCH PRODUCT

Evolution of microstructures and mechanical properties during dissimilar electron beam welding of titanium alloy to stainless steel via copper interlayer

Pierre SallamandMichel PillozIryna TomashchukN. Belyavina

subject

Materials scienceMechanical EngineeringMetallurgyIntermetallicTitanium alloyWeldingengineering.materialCondensed Matter Physicslaw.inventionBrittlenessMechanics of MaterialslawElectron beam weldingUltimate tensile strengthengineeringGeneral Materials ScienceAustenitic stainless steelBeam (structure)

description

Abstract The influence of operational parameters on the local phase composition and mechanical stability of the electron beam welds between titanium alloy and AISI 316L austenitic stainless steel with a copper foil as an intermediate layer has been studied. It was shown that two types of weld morphologies could be obtained depending on beam offset from the center line. Beam shift toward the titanium alloy side results in formation of a large amount of the brittle TiFe2 phase, which is located at the steel/melted zone interface and leads to reducing the mechanical resistance of the weld. Beam shift toward the steel side inhibits the melting of titanium alloy and, so, the formation of brittle intermetallics at the titanium alloy/melted zone interface. Mechanical stability of the obtained junctions was shown to depend on the thickness of this intermetallic layer. The fracture zone of the weld was found to be a mixture of TiCu (3–42 wt%), TiCu1−xFex (x=0.72–0.84) (22–68 wt%) and TiCu1−xFex (x=0.09–0.034) (0–22 wt%). In order to achieve the maximal ultimate tensile strength (350 MPa), the diffusion path length of Ti in the melted zone should be equal to 40–80 µm.

yearjournalcountryeditionlanguage
2013-11-01Materials Science and Engineering: A
https://doi.org/10.1016/j.msea.2013.07.050