期刊
MATERIALS TODAY COMMUNICATIONS
卷 26, 期 -, 页码 -出版社
ELSEVIER
DOI: 10.1016/j.mtcomm.2020.101769
关键词
High-temperature alloys; Powder metallurgy; Sintering; Microstructure; Calorimetry; Thermal analysis
资金
- Natural Sciences and Engineering Research Council of Canada (NSERC)
- Pratt and Whitney Canada (PWC)
Advanced sintering practices for MIM nickel superalloys lead to fine-grain microstructures, but the formation of carbides restricts grain growth. The study evaluates the ability to activate grain growth in MIM NiSA during SLPS using DSC, finding that time above the solidus temperature can dissolve carbides and promote grain growth. This research highlights the challenges of accessing grain growth in MIM and demonstrates the potential of SLPS to increase grain size in MIM NiSA.
State-of-the-art sintering practices for metal injection molded (MIM) nickel superalloys (NiSAs) lead to fine-grain microstructures, reducing creep resistance compared to cast microstructures. MIM uses fine pre-alloyed powders which can increase prior particle boundary (PPB) carbide and oxide formation, restricting grain growth efforts. In the present work, the ability to activate grain growth in a MIM NiSA during supersolidus liquid phase sintering (SLPS) is evaluated using differential scanning calorimetry (DSC). A comparative DSC analysis technique was developed to quantify the SLPS liquid fraction with time and temperature and the grain growth behaviour of the MIM NiSA during SLPS was determined from optical microscopy. SEM-EDS of the sample microstructures revealed that the formation of refractory metal (RM)-Ta mixed MC carbides at the PPB restricts grain growth in the MIM NiSA. Time above the solidus temperature was found to dissolve the RM-Ta mixed MC carbides, enacting grain growth after a short incubation period. The results underscore the difficulty of accessing grain growth under the challenging conditions of MIM while demonstrating that SLPS can increase the grain size in the MIM NiSA.
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