Abstract
Additive manufacturing has revolutionized the manufacturing paradigm in recent years due to the possibility of creating complex shaped three-dimensional parts which can be difficult or impossible to obtain by conventional manufacturing processes. Among the different additive manufacturing techniques, wire and arc additive manufacturing (WAAM) is suitable to produce large metallic parts owing to the high deposition rates achieved, which are significantly larger than powder-bed techniques, for example. The interest in WAAM is steadily increasing, and consequently, significant research efforts are underway. This review paper aims to provide an overview of the most significant achievements in WAAM, highlighting process developments and variants to control the microstructure, mechanical properties, and defect generation in the as-built parts; the most relevant engineering materials used; the main deposition strategies adopted to minimize residual stresses and the effect of post-processing heat treatments to improve the mechanical properties of the parts. An important aspect that still hinders this technology is certification and nondestructive testing of the parts, and this is discussed. Finally, a general perspective of future advancements is presented.
Highlights
Additive manufacturing is nowadays one of the hot topics in the manufacturing and engineering worlds
The results presented in this investigation suggest that the significant differences in properties along the part’s height are due to a different thermal history
The importance of these results arise from the fact that AA2024 is an unweldable alloy, and part production is enabled by the suitable selection of the Mg content in the cold metal transfer (CMT) pulse advanced (CMT-PADV), developed by Fronius, was proven to entirely feedstock wire
Summary
Additive manufacturing is nowadays one of the hot topics in the manufacturing and engineering worlds. In the pursuit for a better and more stable process to control molten metal deposition with reduced heat input, a variant of GMAW, known as cold metal transfer (CMT), has been adapted to additive manufacturing It is an advanced material transfer process in which an incorporated control system detects when the electrode wire tip contacts with the molten pool, and by activation of a servomotor, retracts the wire in a push and pull electromechanical process, to control droplet transfer. Cold metal transfer is suitable for application in Ti-based alloys [16] Another variant is tandem GMAW, in which two wires are fed into the melt pool in order to achieve high deposition rates (160 g/min) [9,17]. Some research groups have developed new process variants to mitigate some of the above-mentioned issues, namely by applying mechanical deformation between layers or active heating and cooling, for example
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