Constitutive model and microstructure evolution finite element simulation of multidirectional forging for gh4169 superalloy

Abstract

This study investigates three processes of multidirectional forging (MDF), namely, closed MDF (CMDF), single-open MDF, and double-open MDF, by using a constitutive equation and a dynamic recrystallization model of hot deformation of the GH4169 superalloy. The microstructure evolution of the three processes is simulated and compared. Among the three processes, the double-open MDF obtains the highest recrystallization degree, followed by the CMDF and the single-open MDF under the same reduction. The recrystallization degree of CMDF reaches 99.5% at 1000◦C and 9 passes, and the average recrystallized grain size is small, which is approximately 8.1 µm. The double-open MDF can obtain a fine grain size of forgings at 9 passes and 1000◦C, and it is easy to obtain forgings with the single-open MDF with uniform performance. The temperature is 850◦C–1000◦C, the compression rate is 0.15–0.2, and the pass is 5–9, which are the suitable parameter selection ranges for the CMDF. The temperature is 950◦C–1000◦C, the compression rate is 0.1–0.2, and the pass is 7–9, which are the suitable parameter selection ranges for single-open MDF. The temperature is 850◦C–1000◦C, the compression rate is 0.1–0.2, and the pass is 6–9, which are the suitable parameter selection ranges for the double-open MDF.