Litcius/Paper detail

Additive manufacturing as a processing route for steel-aluminum bimetallic structures

Rangasayee Kannan, Yousub Lee, D.T. Pierce, Kinga A. Unocic, Blane Fillingim, Thomas Feldhausen, Andrés Márquez Rossy, Hsin Wang, Peeyush Nandwana

2023Materials & Design37 citationsDOIOpen Access PDF

Abstract

Here we present results on the fabrication of steel-aluminum bi-metallic structures using directed energy deposition additive manufacturing. The challenges associated with the fabrication of a sharp transition from steel to aluminum are uncovered using ex-situ characterization techniques and thermo-mechanical modeling of the deposition process. It was found that the fabrication of a sharp steel-aluminum transition is challenging with extensive cracking observed at the interface. The cracking was attributed to the combined effect of residual stress development due to thermal expansion coefficient mismatch and the presence of ordered intermetallics with low ductility at the interface. Using a coupled thermodynamic and thermo-mechanical modeling approach, potential pathways to enable the fabrication of steel-aluminum bi-metallic structures using additive manufacturing are proposed. The results presented here can lay the foundation for future work on the fabrication of bi-metallic steel-aluminum structures using directed energy deposition.

Topics & Concepts

Materials scienceFabricationBimetallic stripAluminiumDuctility (Earth science)Residual stressMetallurgyDeposition (geology)IntermetallicThermal expansionComposite materialMetalPaleontologyAlternative medicineSedimentAlloyBiologyPathologyMedicineCreepAdditive Manufacturing Materials and ProcessesAdditive Manufacturing and 3D Printing TechnologiesHigh Entropy Alloys Studies