Abstract
The mechanical deformation of cellular structures in the selective laser melting (SLM) of aluminum was investigated by performing a series of molecular dynamics (MD) simulations of uniaxial tension tests. The effects of crystalline form, temperature, and grain orientation of columnar grains on the mechanical properties of SLM aluminum were examined. The MD results showed that the tensile strength of SLM aluminum with columnar grains at different temperatures was lower than that of single-crystal aluminum, but greater than that of aluminum with equiaxed grains. The tensile strength and Young’s modulus both decreased approximately linearly upon increasing the temperature. The deformation mechanisms of equiaxed and columnar grains included dislocation slip, grain boundary migration, and torsion, while the deformation mechanisms of single crystals included stacking fault formation and amorphization. Finally, the influence of the columnar grain orientation on the mechanical properties was studied, and it was found that the Young’s modulus was almost independent of the grain orientation. The tensile strength was greatly affected by the columnar grain orientation. Reasonable control of the grain orientation can improve the tensile strength of SLM aluminum.
Highlights
Additive manufacturing (AM) is a rapidly developing technology based on computer assistance and material accumulation that can reduce manufacturing costs of low-volume products and processing times compared with conventional manufacturing techniques [1]
In this7astudy, the deformation mechanisms of the cellular structures in the of selective orientation, whereas tensile strength was dependent on the orientation of simulacolumnar laser melting (SLM) the of aluminum were investigated by performing a series of molecular dynamics (MD)
7b, temperature, when the grain changed from Group tions.ItThe of crystalline form, andorientation columnar grain orientation on the (e) mechanical properties of Selective laser melting (SLM)
Summary
Selective laser melting (SLM) is a laser-based AM technology that has been widely used to manufacture key components in the automotive, medical equipment, aerospace, and mold manufacturing fields [2,3]. Traditional preparation methods of aluminum components with complex shapes require long preparation cycles and produce material waste. Selective laser melting can reduce material usage, shorten the forming cycle, and prepare complex-shaped parts; the application of aluminum in SLM has increased, and some scholars have conducted related experimental research on the mechanical properties of SLM-processed aluminum [4,5,6,7,8,9,10,11]. Li et al [6]
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