Wire and arc additive manufacturing (WAAM) has proven that it can produce medium to
large components because of its high-rate deposition and potentially unlimited build size …

Abstract Wire Arc Additive Manufacturing (WAAM) is attracting significant attention in
industry and academia due to its ability to capture the benefits of additive manufacturing for …

Metal additive manufacturing (MAM) techniques are continuously progressing since last
decade and have marked a remarkable impact on the industry. Amongst the numerous MAM …

This paper provides a review of the capabilities of WAAM for manufacturing steel
components for use in the construction industry, with a focus on the structural stability and …

Although wire arc additive manufacturing (WAAM) has proven its capability of fulfilling
demands of production of medium-to-large-scale components for automotive and allied …

Residual stresses and distortion in Additive Manufactured (AM) parts are two key obstacles
which seriously hinder the wide application of this technology. Nowadays, understanding …

In-process deformation methods such as rolling can be used to refine the large columnar
grains that form when wire+ arc additively manufacturing (WAAM) titanium alloys. Due to the …

Over the past years, the demand for the wire arc additive manufacturing (WAAM) is
potentially increased, and it has become a promising alternative to subtractive …

The aluminium alloy wire 2319 is commonly used for Wire+ Arc Additive Manufacturing
(WAAM). It is oversaturated with copper, like other alloys of the precipitation hardening 2### …

Additively manufactured intersections have the theoretical risk to contain hydrostatic tensile
residual stresses, which eventually cannot be thermally stress relieved. The stresses in Ti …