In this paper, the wire+ arc additive manufacturing process-induced plastic anisotropy of
316L stainless steel is analyzed by means of detailed 3D microstructural modeling and …

In this paper, the anisotropic mechanical response triggered by specific microstructures
encountered in wire+ arc additively manufactured 316L stainless steels is analyzed. For this …

In this study the mechanical anisotropy of laser powder bed fusion (LPBF) 316L stainless
steel under tensile, compressive, and shear loading in different orientations with respect to …

The underlying cause of mechanical anisotropy in additively manufactured (AM) parts is not
yet fully understood and has been attributed to several different factors like microstructural …

Abstract Wire Arc Additive Manufacturing (WAAM) is an emerging group of methods for
producing large parts with complex geometries and varying wall thicknesses. These parts …

The mechanical anisotropy created by additive manufacturing (AM) is not yet fully
understood and can depend on many factors, such as powder material, manufacturing …

Different manufacturing processes such as flow forming, rolling, wire drawing and additive
manufacturing induce anisotropic structure and texture evolution at the micro scale, which …

In this paper, the evolution of the plastic anisotropy of stainless steel 316L samples is
investigated under proportional loading paths using a customized cruciform specimen. The …

Build orientation-induced mechanical anisotropy is critical for additive manufacturing metals.
To leverage the existing research on anisotropy between Z and X/Y build orientations, this …

Additively manufactured (AM) metallic materials often comprise as-printed dislocation cells
inside grains. These dislocation cells can give rise to substantial microscale internal …