Abstract
Selective laser melting (SLM) in situ alloying is an effective way to design and fabricate novel materials in which the elemental powder is adopted as the raw material and micro-areas of elemental powder blend are alloyed synchronously in the forming process of selective laser melting (SLM). The pre-alloying process of preparation of raw material powder can be left out, and a batch of bulk samples can be prepared via the technology combined with quantitative powder mixing and feeding. The technique can be applied to high-throughput sample preparation to efficiently obtain a microstructure and performance data for material design. In the present work, bulk equiatomic FeCoCrNi high-entropy alloys with different processing parameters were fabricated via laser in situ alloying. Finite element simulation and CALPHAD calculation were used to determine the appropriate SLM and post-heating parameters. SEM (scanning electron microscope), EDS (energy dispersive spectroscopy), XRD (X-ray diffraction), and mechanical testing were used to characterize the composition, microstructure, and mechanical properties of as-printed and post-heat-treated samples. The experimental results show that the composition deviation of laser in situ alloying samples could be controlled within 20 wt %. The crystal structure of as-printed samples is a single-phase face-centered cubic (FCC), which is the same as those prepared by the traditional method. The mechanical properties of the samples prepared by laser in situ alloying with elemental powder blend are comparable to those prepared by pre-alloying powder and much higher than those prepared by the traditional method (arc melting). As-printed samples can get a homogeneous microstructure under the optimal laser in situ alloying process combined with post-heat treatment at 1200 °C for 20 h.
Highlights
Most structural metallic materials are based on a primary element to improve the overall performance by mixing the primary element with other elements
The preparation process of high-entropy alloys (HEAs) by additive manufacturing (AM) can be divided into two categories, one is the laser cladding deposition based on powder feeding or wire feeding, and the other one is the selected laser melting (SLM) based on powder paving [12,13]
There were three main factors affecting the composition deviation of elemental powder samples: (1) composition deviations caused by uneven powder mixing, powder fluidity, and powder size difference during the powder laying process of SLM; (2) element segregation caused by the rapid solidification process; and (3) incomplete alloying of high melting point elements caused by insufficient laser energy density
Summary
Most structural metallic materials are based on a primary element to improve the overall performance by mixing the primary element with other elements. The pioneering work of Cantor and Yeh et al [1,2] on mixing multiple high concentration elements has opened up a new field in material science called high-entropy alloys (HEAs). Traditional HEAs with an FCC structure usually have high plasticity, while the one with a BCC structure usually has high strength [4]. Torbati-Sarraf et al [9] proved that the corrosion resistance of FeCoCrNi samples prepared by vacuum induction melting were better than that of FeCoCrNiMn alloy. The preparation methods of bulk HEAs mainly include vacuum melting, powder metallurgy, and additive manufacturing (AM). Additive manufacturing of HEAs has many advantages that traditional methods do not have [11], such as precision forming of a complex structure, grain refinement of microstructure, and performance regulation of multiple process parameters.
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