The recrystallization and texture evolution of cold-rolled FeCrAl-0.65 Nb and FeCrAl-1.2 Nb alloys thin-wall tubes annealed at 600−900℃ for 1−600 min were investigated.The microstructures were characterized by electr...The recrystallization and texture evolution of cold-rolled FeCrAl-0.65 Nb and FeCrAl-1.2 Nb alloys thin-wall tubes annealed at 600−900℃ for 1−600 min were investigated.The microstructures were characterized by electron back scattering diffraction,electron probe micro-analyzer and transmission electron microscopy.The Vickers hardness and room temperature tensile properties were tested.The results showed that the hardness of fully recrystallized FeCrAl-1.2 Nb alloy was higher and more likely to recrystallize than FeCrAl-0.65 Nb alloy.The weak texture strength of annealing sample was obtained and the proportion of<111>//ND texture increased.The fine Laves phase distributed uniformly in FeCrAl-0.65 Nb alloy had good pinning effect and inhibited recrystallization.Higher Nb content had little effects on tensile properties of thin-wall tube,and induced the formation of larger Laves phase.There was less fine Laves phase pinning in the large area adjacent to the blocky Laves phase,which resulted in easy recrystallization in FeCrAl-1.2 Nb alloy.展开更多
The microstructures and interracial characteristics of matrices at the inwalls and the out-walls of the cold-rolled tube with different amounts of deformation were investigated by the scanning electronic microscope (...The microstructures and interracial characteristics of matrices at the inwalls and the out-walls of the cold-rolled tube with different amounts of deformation were investigated by the scanning electronic microscope (SEM), the optical microscope (OM), and the transmission electronic microscope (TEM) techniques. It was observed that as the amount of deformation increases, the flaws nucleate at the out-walls of the cold rolled tube, the stress-induced martensites change from (111 ) type Ⅰ twins to (011) type Ⅱ twins and then to (100) compound twins, nanocrystals and bulk amorphisation happen, the high density dislocation causes stress concentration at the out-walls of the Ti50Ni50 cold-rolled tube, and then precipitates its fracture, and the Ti2Ni particles strengthen the grain boundaries and curb the dislocation movements during plastic deformation. The inhomogeneity level of the grains in the Ti50Ni50 alloy plays an important role on the fracture of the Ti50Ni50 cold rolled tube.展开更多
Based on the deformation characteristics of Y-type mill,a finite element model for simulating the formation process of shaped steel tube for driving shaft is proposed.The distributions of stress and strain were obtain...Based on the deformation characteristics of Y-type mill,a finite element model for simulating the formation process of shaped steel tube for driving shaft is proposed.The distributions of stress and strain were obtained from the simulation.The outer diameter and transverse wall thickness were also analyzed quantitatively.Experiment was done on Y-type mill.A comparison between simulation results and experiment results shows that the simulated results of shaped steel tube are in good agreement with the on-site data.The model could provide the basis for theoretical research and engineering applications of shaped steel tube rolling process.展开更多
基金Project(2019YFB1901002)supported by the Key Project of Nuclear Safety and Advanced Nuclear Technology,ChinaProject supported by State Key Laboratory of Powder Metallurgy,China。
文摘The recrystallization and texture evolution of cold-rolled FeCrAl-0.65 Nb and FeCrAl-1.2 Nb alloys thin-wall tubes annealed at 600−900℃ for 1−600 min were investigated.The microstructures were characterized by electron back scattering diffraction,electron probe micro-analyzer and transmission electron microscopy.The Vickers hardness and room temperature tensile properties were tested.The results showed that the hardness of fully recrystallized FeCrAl-1.2 Nb alloy was higher and more likely to recrystallize than FeCrAl-0.65 Nb alloy.The weak texture strength of annealing sample was obtained and the proportion of<111>//ND texture increased.The fine Laves phase distributed uniformly in FeCrAl-0.65 Nb alloy had good pinning effect and inhibited recrystallization.Higher Nb content had little effects on tensile properties of thin-wall tube,and induced the formation of larger Laves phase.There was less fine Laves phase pinning in the large area adjacent to the blocky Laves phase,which resulted in easy recrystallization in FeCrAl-1.2 Nb alloy.
文摘The microstructures and interracial characteristics of matrices at the inwalls and the out-walls of the cold-rolled tube with different amounts of deformation were investigated by the scanning electronic microscope (SEM), the optical microscope (OM), and the transmission electronic microscope (TEM) techniques. It was observed that as the amount of deformation increases, the flaws nucleate at the out-walls of the cold rolled tube, the stress-induced martensites change from (111 ) type Ⅰ twins to (011) type Ⅱ twins and then to (100) compound twins, nanocrystals and bulk amorphisation happen, the high density dislocation causes stress concentration at the out-walls of the Ti50Ni50 cold-rolled tube, and then precipitates its fracture, and the Ti2Ni particles strengthen the grain boundaries and curb the dislocation movements during plastic deformation. The inhomogeneity level of the grains in the Ti50Ni50 alloy plays an important role on the fracture of the Ti50Ni50 cold rolled tube.
文摘Based on the deformation characteristics of Y-type mill,a finite element model for simulating the formation process of shaped steel tube for driving shaft is proposed.The distributions of stress and strain were obtained from the simulation.The outer diameter and transverse wall thickness were also analyzed quantitatively.Experiment was done on Y-type mill.A comparison between simulation results and experiment results shows that the simulated results of shaped steel tube are in good agreement with the on-site data.The model could provide the basis for theoretical research and engineering applications of shaped steel tube rolling process.
