Powders of X6CrNiTi18-10 stainless steel were fabricated from original workpieces of different grade by gas atomization method. It was found that it is necessary to use argon as a gas for gas atomization of X6CrNiTi18-10 steel, since the use of nitrogen leads to the formation of its compounds, namely, titanium nitride. It is shown that all used workpieces – electric arc, electric slag and vacuum arc refinement – allow one to obtain powders suitable for further utilization in selective laser melting technology of 3D printing. The main physicochemical and technological properties of the obtained powders have been investigated. Changes in the chemical composition and quality of the powders are not significant within the X6CrNiTi18-10 grade. The 0...20 μm fraction of powders does not have fluidity, and thus cannot be used for additive technologies. The fraction 20...63 μm have suitable rheological properties for additive technologies and may be used in selective laser melting (SLM) process. The yield of target fraction 20 ... 63 microns was ≈45%. The fraction 63...120 μm may be used for the direct metal deposition (DMD) additive technology. Considering the economic aspect of the technology, it is preferable to use original workpieces of X6CrNiTi18-10 steel produced by electric arc or electroslag process, since the market price of vacuum arc steel is significantly higher. The fraction of ferrite phase in the powder increases with a decrease of particle size of the resulting powder and is lower comparing to the original workpiece. In the future, for a detailed study of the technological properties, it is planned to grow samples from each type of the obtained powders on installation for selective laser melting and direct laser deposition to determine the physical and mechanical properties of fabricated samples (tensile and impact bending tests) and carry out metallographic studies.
Synthesis of the Nb-Si in-situ composite was attempted by binder jetting additive manufacturing technology, using Nb powder and liquid Si during infiltration in furnace. The microstructures were examined with scanning electronic microscope, and the phase constituent were analyzed by X-ray diffraction. Furthermore, the effect of using prepared Nb-16Si (at.%) powder mixture as building powder for binder jetting and subsequent melting of internal silicon in furnace on synthesis of the in-situ composite also investigated. After infiltration, the sample mainly consisted of NbSi2 and Si phases. With using of prepared Nb-16Si (at.%) powder and subsequent melting of internal silicon in furnace, microstructure consist of Nbss, Nb3Si, NbSi2 phases.
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