2023
DOI: 10.1007/s11661-023-07115-8
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Residual Stress Distributions in Dissimilar Titanium Alloy Diffusion Bonds Produced From Powder Using Field-Assisted Sintering Technology (FAST-DB)

Abstract: The conventional approach when engineering components manufactured from titanium is to design the thermomechanical processing to develop an optimal microstructure in a single alloy. However, this conventional approach can lead to unnecessary over-engineering of components, particularly when only a specific subcomponent region is under demanding service stresses and environments. One approach being developed to join multiple alloys in a single component and enhance engineering performance and efficiency is FAST… Show more

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Cited by 3 publications
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“…For the manufacture of the heat resistant components used for aerospace and motorsport applications, it is a common practice to require the joining together of different titanium alloys displaying different microstructures. In general, for welding dissimilar materials, the potential issues for attaining good joints are ascribable to differences in melting temperature and thermal expansion coefficients of the two materials, which may lead to higher thermal stresses and result in cracking in the transition zone between the materials [1]. Hence, challenges in joining an α + β titanium alloy to an α Ti one are mainly represented by the mismatch in mechanical properties, melting temperatures in the case when a molten phase is involved, crystal structures, and, perhaps more importantly, mutual solubility.…”
Section: Introductionmentioning
confidence: 99%
“…For the manufacture of the heat resistant components used for aerospace and motorsport applications, it is a common practice to require the joining together of different titanium alloys displaying different microstructures. In general, for welding dissimilar materials, the potential issues for attaining good joints are ascribable to differences in melting temperature and thermal expansion coefficients of the two materials, which may lead to higher thermal stresses and result in cracking in the transition zone between the materials [1]. Hence, challenges in joining an α + β titanium alloy to an α Ti one are mainly represented by the mismatch in mechanical properties, melting temperatures in the case when a molten phase is involved, crystal structures, and, perhaps more importantly, mutual solubility.…”
Section: Introductionmentioning
confidence: 99%