The effect of the parameters of the powder bed fusion process on the microstructure and mechanical properties of CrFeCoNi medium-entropy alloys

“…The CrFeCoNi alloy was performed using the widely used laser powder bed fusion (L-PBF) additive manufacturing technique. TruPrint 1000 metal 3D printer (TRUMPF) was used in the current work to manufacture the samples with the selected printing process parameters according to the results from the previous study [18]. A full list of the applied parameters is shown in Table 2.…”

“…In previous works, the precipitates observed in a CrFeCoNi microstructure after annealing at 750 ℃ and 800 ℃ are considered as the σ-phase [18,23]. In order to examine detailed structure of the secondary phase in the alloy heated at different temperatures and treatment time, TEM diffraction analysis was performed for the alloy after annealing for 24 h. Fig.…”

“…HEAs are actively constructed through the application of the modern manufacturing techniques such as Additive Manufacturing (AM) [15,16]. For the AM process, post-printing heat treatment of the as-built materials is often applied to remove residual stresses, but it leads to structural changes including recrystallization and secondary phase formations [17][18][19]. Synthesis of CoCrFeMnNi alloys is common by the AM process due to their nature with a ductile fcc structure as matrix, which provides stable printability [19][20][21].…”

Phase and structural changes during heat treatment of additive manufactured CrFeCoNi high-entropy alloy

“…The CrFeCoNi alloy was performed using the widely used laser powder bed fusion (L-PBF) additive manufacturing technique. TruPrint 1000 metal 3D printer (TRUMPF) was used in the current work to manufacture the samples with the selected printing process parameters according to the results from the previous study [18]. A full list of the applied parameters is shown in Table 2.…”

“…In previous works, the precipitates observed in a CrFeCoNi microstructure after annealing at 750 ℃ and 800 ℃ are considered as the σ-phase [18,23]. In order to examine detailed structure of the secondary phase in the alloy heated at different temperatures and treatment time, TEM diffraction analysis was performed for the alloy after annealing for 24 h. Fig.…”

“…HEAs are actively constructed through the application of the modern manufacturing techniques such as Additive Manufacturing (AM) [15,16]. For the AM process, post-printing heat treatment of the as-built materials is often applied to remove residual stresses, but it leads to structural changes including recrystallization and secondary phase formations [17][18][19]. Synthesis of CoCrFeMnNi alloys is common by the AM process due to their nature with a ductile fcc structure as matrix, which provides stable printability [19][20][21].…”

Phase and structural changes during heat treatment of additive manufactured CrFeCoNi high-entropy alloy

“…The properties of the final part highly depend on certain process parameters, such as the laser velocity and power density, scanning strategy, hatch spacing, and thickness of the printed layers [10,11]. The combination of these parameters can be used to fabricate structures with typical defects present in AM metallic parts, such as a lack of fusion, voids, and microcracks induced by residual stresses [12].…”

Very High Cycle Fatigue Behavior of Additively Manufactured 316L Stainless Steel

“…HEAs fabricated using SLM exhibited outstanding strength and ductility superior to their conventionally fabricated and post-processed counterpart and comparable to the conventional materials such as stainless steel [351,356,[369][370][371][372]. The tensile and compressive strength of CoCrFeMnNi HEA has been investigated by many researchers [356,[372][373][374][375].…”

Review of Powder Bed Fusion Additive Manufacturing for Metals