Abstract
Aluminium alloys processed by wire arc additive manufacturing (WAAM) exhibit a relatively coarse microstructure with a columnar morphology. A powerful measure to refine the microstructure and to enhance mechanical properties is to promote grain refinement during solidification. Addition of ceramic nanoparticles has shown great potential as grain refiner and strengthening phase in aluminium alloys. Thus, an Al-Mg alloy mixed with TiC nanoparticles was manufactured by the novel metal screw extrusion method to a wire and subsequently deposited by WAAM. Measures to restrict oxidation of magnesium during metal screw extrusion were examined. Purging of CO2 gas into the extrusion chamber resulted in a remarkable reduction in formation of MgO and Mg(OH)2. TiC decomposed to Al3Ti during WAAM deposition, leading to a significant grain refinement of 93% compared to a commercial benchmark. The presence of remaining TiC nanoparticles accounted for an increased hardness of the WAAM material through thermal expansion mismatch strengthening and Orowan strengthening. Exposure of TiC to moisture in air during metal screw extrusion increased the internal hydrogen content significantly, and a highly porous structure was seen after WAAM deposition.
Highlights
Research and development related to additive manufacturing (AM) of metals has seen a great rise in recent years
Reported results related to grain refinement and chemical stability of TiC are in opposition to the results presented in this work
This study examined the applicability of metal screw extrusion to manufacture nanoparticle reinforced aluminium feedstock for wire arc additive manufacturing (WAAM)
Summary
Research and development related to additive manufacturing (AM) of metals has seen a great rise in recent years. Attractive characteristics like shorter time-to-market, increased material utilisation, novel designs, and improved performance are major driving forces for introduction of AM to industrial applications. The welding-based AM method wire arc additive manufacturing (WAAM) is among. WAAM is relevant for manufacturing of components and structures with larger volumes and with intermediate design complexity [1]. The WAAM system utilises fusion of feedstock wires by an electric arc to create stand-alone products. WAAM is considered a lowcost AM method with high material and energy utilisation. Investment and material costs are orders of magnitude lower than powder-and-laser based techniques, and nearly 100% of the input material is used to create the component [2]. Deposition rates can reach several kg/h for aluminium, dependent on selected input parameters [2, 3]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
