首页|Texture dependence on the mechanical properties of 18Ni300 maraging steel fabricated by laser powder bed fusion
Texture dependence on the mechanical properties of 18Ni300 maraging steel fabricated by laser powder bed fusion
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NSTL
Elsevier
? 2022 Elsevier Inc.The crystallographic heterostructure of additive manufactured metals has complicated effects on mechanical properties due to the unique thermal history. Therefore, the texture configuration and deformation behavior of powder bed fusion-laser beam (PBF-LB) 18Ni300 maraging steel after different building orientations (BOs) were investigated by electron backscattered diffraction (EBSD), tensile tests and crystal plasticity finite element simulation. The results showed that the yield strength of 90° samples was 2013.8 MPa, higher than that of 0° (1940.5 MPa) and 45° (1847.1 MPa). The higher strength was attributed to the strong 〈110〉 ‖ BO textures on the 90° building samples. Meanwhile, the elongation was in the order of 3.5% (90° building) < 5.6% (45° building) < 7.6% (0° building) by strain rate of 2.5 × 10?4 s?1, which was attributed to the dynamic recovery process of PBF-LB 18Ni300 maraging steel in strain hardening stage I for different crystallographic orientations. The single crystallographic orientation couldn't coordinate the plastic deformation of the 90° building specimen, which resulted in fracturing under a small strain. In contrast, the diversified crystal textures contributed to the sufficient coordinated plastic deformation of the specimens fabricated along 0° building and thus increased the overall elongation to fracture.
18Ni300 steelBuilding orientationPowder bed fusion-laser beamTexture
Zhao Z.、Wang L.、Kong D.、He X.、Dong C.、Liu P.、Ni X.、Zhang L.
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Beijing Advanced Innovation Center for Materials Genome Engineering Institute for Advanced Materials and Technology University of Science and Technology Beijing
School of Mathematics and Physics University of Science and Technology Beijing
Shanghai Engineering Research Center of 3D Printing Materials Shanghai Research Institute of Materials
NSTL
Elsevier
