Metal additive manufacturing (MAM) technology has great application potential in the
aerospace, medical and energy fields with its high material utilization efficiency to achieve …

Additive manufacturing (AM) has gained extensive attention and tremendous research due
to its advantages of fabricating complex-shaped parts without the need of casting mold …

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 …

Wire arc additive manufacturing (WAAM) technique became an emerging manufacturing
technology because of its cost-effective in creating large-scale metal parts with moderately …

Due to friction, chip forming, and the induced heat in the cutting area, produced parts by
using machining operations have residual stress. Residual stresses caused by machining …

Abstract DMLS or Direct Metal Laser Sintering is a technique which can be classified under
an additive manufacturing (AM). In this technique, metal powders are used to manufacture …

Laser additive manufacturing (LAM) has wide prospects in the titanium alloy for aerospace
applications because of its low consumption, high forming efficiency and digital …

The repeated localised heating-melting-cooling-solidification processes during laser beam
powder bed fusion (PBF-LB) additive manufacturing (AM) induce intricate thermal residual …

The precipitation behavior of the γ ″phase and mechanical properties in Inconel 718 alloy
during aging under an external applied stress or internal quench-in residual stress were …

Additive manufacturing (AM) is known to generate large magnitudes of residual stresses
(RS) within builds due to steep and localized thermal gradients. In the current state of …