Abstract
The relationships between hot deformation parameters and flow behaviour have attracted many researchers’ attention for the past few decades, whilst precise constitutive modelling of GH4169 remained a problem, which seriously affected the process and microstructure control of alloys. In this work, a modified Arrhenius type model was introduced to describe the flow stresses of various compression conditions. The model showed high precision in flow stress prediction. In order to facilitate workability evaluation for engineering applications, the hot processing maps were established at the strain of 0.4~0.6. The processing maps revealed an instability domain at 900~950 °C and 0.1~1 s−1, a high dissipation efficiency domain at 1060~1100 °C and 0.001~0.01 s−1, and a stable deformation domain for the rest of processing parameters. Microstructures of each domain were observed via optical microscope (OM) and electron backscattered diffraction (EBSD). The intriguing finding was that the microstructures morphology agreed well with the descriptions in “discontinuous mechanism”, and incompletely recrystallized microstructures were found in the instability domain. Fully recrystallized microstructures were found in the stable deformation domain, and grain coarsen in the high dissipation efficiency domain. Optimal hot working conditions were suggested based on the microstructure analysis. This investigation contributed to a comprehensive understanding of the workability of GH4169.
Highlights
The GH4169 is a nickel-based high temperature alloy, and it has been widely used in structural parts in petroleum, aerospace, and nuclear industry due to its excellent high temperature mechanical properties
The constitutive relationship of GH4169, it has been investigated by some researchers [1,2,3,4], has not been precisely established, and the hot processing maps have not been constructed systematically based on microstructure examinations of different domains, which has caused difficulty in microstructure control in hot forgings
The stress–strain relationship of GH4169 in compressions are shown in Figure 1 by plotting the flow stress versus the true stain curve
Summary
The GH4169 is a nickel-based high temperature alloy, and it has been widely used in structural parts in petroleum, aerospace, and nuclear industry due to its excellent high temperature mechanical properties. The constitutive relationship of GH4169, it has been investigated by some researchers [1,2,3,4], has not been precisely established, and the hot processing maps have not been constructed systematically based on microstructure examinations of different domains, which has caused difficulty in microstructure control in hot forgings. The processing maps of GH4169, they have been investigated by some researchers [13,14], have not been systematically constructed by microstructure examinations, and the microstructure evolutions of different domains were unclear, which has caused difficulty in microstructure optimization in hot forging This investigation aims to accurately establish the constitutive relationships which describe the flow behaviour under high temperature compressions, and to analyze the workability of GH4169 via microstructure observations. Optimized hot working parameters will be proposed based on microstructure observations
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