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W7Ni3Fe-Ti6Al4V bimetallic layered structures via directed energy deposition

Yanning Zhang, Cory Groden, Eric A. Nyberg, Amit Bandyopadhyay

2022Virtual and Physical Prototyping15 citationsDOIOpen Access PDF

Abstract

Bimetallic structures of Ti6Al4V-W7Ni3Fe were fabricated via directed energy deposition (DED)-based additive manufacturing (AM). Our research demonstrates the ability of DED-based AM to control Ti6Al4V-W7Ni3Fe bimetallic structures with tailorable mechanical and thermal performance. The thermal conductivity of the bimetallic structures was three times higher than Ti6Al4V at 300°C. Uniaxial compression along the transverse direction showed a failure strain of 63% compared to pure Ti6Al4V, while the longitudinal direction showed a failure strain of only 37% of Ti6Al4V. Variable hardness was observed throughout the sample due to diffusion of elements and intermetallic phase formations. Scanning electron microscopy revealed that the interfaces in the as-printed samples were crack-free with elemental gradients.

Topics & Concepts

Bimetallic stripTitanium alloyMaterials scienceIntermetallicTitaniumScanning electron microscopeComposite materialDeposition (geology)Ductility (Earth science)Strain energyMetallurgyAlloyStructural engineeringFinite element methodGeologySedimentEngineeringCreepPaleontologyMetalAdditive Manufacturing Materials and ProcessesAdvanced materials and compositesHigh Entropy Alloys Studies
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