Abstract
Mechanical properties and microstructure are investigated for a martensitic stainless steel (AISI 420) fabricated by selective laser melting (SLM) in three build directions. The tensile specimens built by SLM are classified into three groups. Group A is horizontally built in the thickness direction, Group B is horizontally built in the width direction, and Group C is vertically built in the length direction. The loading direction in tensile test is parallel to the build direction of Group C, but perpendicular to that of Groups A and B. Experimental results indicate build direction has significant effects on the residual stress, hardness, and tensile properties of SLM builds. Microstructural analyses indicate the as-fabricated SLM AISI 420 builds exhibit elongated cells and acicular structures which are composed of martensite and retained austenite phases growing along the build direction. Such anisotropy in the microstructure leads to anisotropic mechanical properties as Group C specimens (length direction) exhibit greater yield stress, ultimate tensile stress, and elongation than the specimens of Groups A (thickness direction) and B (width direction). The residual compressive stress in the gauge section also contributes to the superior tensile properties of Group C (length direction), as compared to Groups A (thickness direction) and B (width direction), which exhibit residual tensile stress in the gauge section.
Highlights
Additive manufacturing (AM) has recently been applied for direct fabrication of near net shape components
Several AM techniques have been developed for building metallic parts, including selective laser melting (SLM), electron beam melting (EBM), laser engineered net shaping (LENS), and binder jetting (BJG) [3]
As the material’s multiaxial mechanical properties are needed for design of mechanical components fabricated by the SLM technique, the aim of this study is to investigate the relationship between build direction and mechanical properties of SLM built AISI 420 parts
Summary
Additive manufacturing (AM) has recently been applied for direct fabrication of near net shape components. For a 316L stainless steel produced through SLM, horizontally built specimens exhibit the highest fatigue resistance followed by vertically built ones, while diagonally built specimens possess the lowest fatigue strength, as presented by Shrestha et al [18] Such anisotropy in the fatigue behavior of SLM 316L stainless steel is induced by the variation in layer orientation and directionality of process defects with respect to the loading direction [18]. The build direction effect on the mechanical properties of metallic AM parts differs from one material to another This is attributed to the variations in microstructure, type and directionality of process defect, and loading direction [4]. It is hoped that the results in this study can provide useful information on improving the quality of SLM built AISI 420 parts for employment in the plastic injection mold [23] and other applications
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