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The deposited billet of a new type powder metallurgy(PM) superalloy FGH4095 M for use in turbine disk manufacturing has been fabricated using spray forming technology. The metallurgical quality of the deposited billet was analyzed in terms of density, texture, and grain size. Comparative research was done on the microstructure and mechanical properties between the flat disk preform prepared with hot isostatic pressing(HIP) and the same alloy forgings prepared with HIP followed by isothermal forging(IF). The results show that the density of the spray-formed and nitrogen-atomized deposit billet is above 99% of the theoretical density, indicating a compact structure. The grains are uniform and fine. The billet has weak texture with a random distribution in the spray deposition direction and perpendicular to the direction of deposition.A part of atomizing nitrogen exists in the preform in the form of carbonitride. Nitrogen-induced microporosity causes the density reduction of the preform. Compared with the process of HIP+IF, the superalloy FGH4095 M after HIP has better mechanical properties at both room temperature and high temperature. The sizes of the γphase are finer in microstructure of the preform after HIP in comparison with the forgings after HIP+IF. This work shows that SF+HIP is a viable processing route for FGH4095 M as a turbine-disk material.
The deposited billet of a new type powder metallurgy (PM) superalloy FGH4095 M for use in turbine disk manufacturing has been fabricated using spray forming technology. The metallurgical quality of the deposited billet was analyzed in terms of density, texture, and grain size. research was done on the microstructure and mechanical properties between the flat disk preform prepared with hot isostatic pressing (HIP) and the same alloy forgings prepared with HIP followed by isothermal forging (IF). The results show that the density of the spray-formed and The billet has a weak texture with a random distribution in the spray deposition direction and perpendicular to the direction of deposition. A part of atomizing nitrogen exists in the preform in the form of carbonitride. Nitrogen-induced microporosity causes the density reduction of the preform. Compared with the process of HIP + IF, the superalloy FGH4095 M after HIP has better mechanical properties at both room temperature and high temperature. The sizes of the γphase are finer in microstructure of the preform after HIP in comparison with the forgings after HIP + IF . This work shows that SF + HIP is a viable routing for FGH4095 M as a turbine-disk material.