Abstract
Selective laser melting (SLM) and direct energy deposition (DED) are two widely used technologies in additive manufacturing (AM). However, there are few studies on the combination of the two technologies, which can synthetically combine the advantages of the two technologies for more flexible material design. This paper systematically studies the Al-Mg-Sc-Zr alloy by combination of SLM and DED with emphasis on its bonding properties, microstructure, and metallurgical defects. It is found that the aluminum alloy prepared by the two methods achieves a good metallurgical combination. The microstructure of aluminum alloy prepared by DED is composed of equiaxed crystals, and there are a large number of Al3(Sc, Zr) precipitated phase particles rich in Sc and Zr. The microstructure of SLM aluminum alloy is composed of equiaxed crystals and columnar crystals, and there is a fine-grained area at the boundary of the molten pool. With the decrease of laser volumetric energy density (VED), the width and depth of the molten pool at the interface junction gradually decrease. The porosity gradually increases with the decrease of VED, and the microhardness shows a downward trend. Tensile strength and elongation at fracture of the SLM printed sample at 133.3 J/mm3 are about 400 MPa and 9.4%, while the direct energy depositioned sample are about 280 MPa and 5.9%. Due to the excellent bonding performance, this research has certain guiding significance for SLM–DED composite aluminum alloy.
Highlights
Aluminum alloy is a metal structural material that is widely used after steel
The energy input which is known as an important factor in regulating the formation of metallurgical defects affects the degree of melting, the dynamics of the molten pool, and the solidification characteristics [27,28]
It can be seen from the figure that compared with the Selective laser melting (SLM) specimens, the direct energy deposition (DED) aluminum alloy specimens have more pores, and the pore size is larger than that of the samples prepared by the SLM
Summary
Aluminum alloy is a metal structural material that is widely used after steel. It has low density, high specific strength, good processing performance, high corrosion resistance, and excellent electrical as well as thermal conductivity [1,2,3,4]. At present, aluminum alloy components are mainly prepared by traditional methods such as forging and casting, which presents problems like being prone to produce metallurgical defects, resulting in low mechanical properties and a long production cycle of high-performance parts [8,9,10]. The development of the additively manufactured aluminum alloy is limited due to the disadvantages of high laser reflectivity, high thermal conductivity as well as metallurgical defects like cracks. The influence of different printing parameters (VED) on interface bonding strength, structure evolution, and defect analysis were studied
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
