Kreitcberg Alena, Brailovski Vladimir
Department of Mechanical Engineering, École de technologie supérieure, Montreal, QC H3C 1K3, Canada.
Materials (Basel). 2022 Sep 23;15(19):6606. doi: 10.3390/ma15196606.
Two alloys with different Fe and C contents were studied to assess the influence of their compositions on the microstructure and mechanical properties of Ni-based Inconel 625 superalloy processed by laser powder bed fusion and subjected to stress relief annealing (870 °C) and a solution treatment (1120 °C). It was concluded that the alloy with a higher Fe content (4 wt.% as compared to ~1 wt.%) manifests a greater propensity to segregate Nb and Mo elements during printing and form δ phase particles during the stress relief annealing. On the other hand, the alloy with a higher C content (0.04 wt.% compared to ~0.02 wt.%) exhibits a greater tendency to form MC carbides during the solution treatment. No effects of the Fe and C content variations on the room temperature mechanical properties were observed. On the contrary, an increase in the C content resulted in a 40% lower high-temperature (760 °C) ductility of the laser powder bed fused and post-processed IN625 alloy, without affecting its strength characteristics.
研究了两种具有不同铁和碳含量的合金,以评估其成分对通过激光粉末床熔融加工并进行应力消除退火(870°C)和固溶处理(1120°C)的镍基Inconel 625高温合金的微观结构和力学性能的影响。得出的结论是,铁含量较高的合金(4 wt.%,相比之下约为1 wt.%)在打印过程中表现出更大的Nb和Mo元素偏析倾向,并且在应力消除退火过程中形成δ相颗粒。另一方面,碳含量较高的合金(0.04 wt.%,相比之下约为0.02 wt.%)在固溶处理过程中表现出更大的形成MC碳化物的倾向。未观察到铁和碳含量变化对室温力学性能的影响。相反,碳含量的增加导致激光粉末床熔融和后处理的IN625合金的高温(760°C)延展性降低40%,而不影响其强度特性。