Abstract
Among various additive manufacturing (AM) technologies, wire-and-arc additive manufacturing (WAAM) is one of the most suitable for the production of large-scale metallic components, also suggesting possible applications in the construction field. Several research activities have been devoted to the WAAM of steels and titanium alloys and, recently, the application of WAAM to aluminum alloys has also been explored. This paper presents the microstructural and mechanical characterization of WAAM plates produced using a commercial ER 5183 aluminum welding wire. The aim is to evaluate the possible anisotropic behavior under tensile stress of planar elements, considering three different extraction directions in relation to the deposition layer: longitudinal (L), transversal (T) and diagonal (D). Compositional, morphological, microstructural and fractographic analyses were carried out to relate the specific microstructural features induced by WAAM to the tensile properties. An anisotropic behavior was found in regard to the specimen orientation, with the lowest strength and ductility found on T specimens. Reasoning to this was found in the presence of microstructural discontinuities unfavorably oriented with regard to the tensile direction. The results of tensile tests also highlighted an overall good mechanical behavior, comparable to that of conventional AA5083-O sheets, suggesting future use in the realization of very complex geometries and optimized shapes for lightweight structural applications.
Highlights
Among the various additive manufacturing (AM) techniques, one of the most suitable for producing large metal components for structural engineering purposes is the socalled wire-and-arc additive manufacturing (WAAM) [1]
WAAM is a direct energy deposition (DED) technology that derives from conventional welding processes and, as for the latter, it can be classified as gas metal arc welding (GMAW), gas tungsten arc welding (GTAW) and plasma arc welding
By comparison to the feedstock wire, WAAM plates exhibited a higher content of the main alloy element (Mg) and a lower presence of Mn; these values fall within the range of AA5083
Summary
Among the various additive manufacturing (AM) techniques, one of the most suitable for producing large metal components for structural engineering purposes is the socalled wire-and-arc additive manufacturing (WAAM) [1]. The main advantage of this AM-based technology lies upon the possibility to realize complex-shaped large-scale structural elements, with high deposition rates and still ensuring lower overall production costs, including that of feedstock material, if compared to other additively manufactured techniques for metals [3,4,5]. Additive manufacturing of aluminum alloys has been extensively investigated considering AM process based on the fusion of a powder bed [14,15,16]; the application of WAAM technologies was recently investigated. An extensive research effort has been devoted to GMAW and GTAW-based WAAM processes for aluminum alloys [17], focusing on wrought Al–Mg alloys of the 5000 series [18,19,20,21,22,23]. The 5000 series of aluminum alloys offers an excellent combination of corrosion resistance, strength, toughness, weldability, and for
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