Recovery of Ductility in Ultrafine-Grained Low-Carbon Steel Processed Through Equal-Channel Angular Pressing Followed by Cold Rolling and Flash Annealing

摘要

The low-carbon steel workpieces are deformed by equal-channel angular pressing at 293 K (20 A degrees C) up to an equivalent strain of similar to 12 using route B (c), which results in the bulk ultrafine-grained (UFG) structure with high dislocation density and partial dissolution of cementite. The yield strength (YS) is enhanced from 208 (as-received) to 872 MPa and the tensile strength is increased from 362 to 996 MPa, but the material loses total elongation (TE) from 36.2 to 2.9 pct. Cold rolling of equal-channel angular pressed steel produces the refined structure of grain size 0.11 mu m. The YS increases further to 924 MPa with a marginal gain in ductility due to the reappearance of the gamma fiber component. Flash annealing the samples, which were equal-channel angular pressed followed by cold rolling, at 873 K (600 A degrees C) results in 27 pct of micron-sized (9 A mu m) ferrite grains in submicron-sized (< 1 A mu m) matrix with a reduced defect density and small amount of precipitation of cementite. TE increases from 2.9 to 23.3 pct. The material retains a YS of 484 MPa and tensile strength of 517 MPa, which are higher than those of the as-received material. The UFG grains are failed by cleavage, but the micron-sized grains display ductile fracture. The ductility of the flash-annealed material is recovered significantly due to bimodal grain size distribution in ferrite and the development of a good amount of gamma fiber texture components. The major contribution toward recovery of ductility comes from the bimodal grain size distribution in ferrite rather the precipitation of cementite.