Nano- and submicrocrystalline steels processed by severe plastic deformation

The aim of this paper is to consider the features of structure evolution during severe plastic deformation (SPD) of steels and its influence on mechanical properties. The investigations have been carried out mainly on low-carbon steels as well as on austenitic stainless steels after SPD by torsion under high pressure (HPT) and equal-channel angular pressing (ECAP). Structure formation dependences on temperature deformation conditions, strain degree, chemical composition, initial state and pressure are considered. The role of phase transformations for additional grain refinement, namely, martensitic transformation, precipitation of carbide particles during SPD and heating is underlined

Structure and properties of severely deformed Ti-Ni-based shape memory alloys

Structure formation and functional properties of Ti-50.0, Ti-50.7 at. % Ni and Ti-47%Ni-3%Fe shape memory alloys were studied after severe plastic deformation by torsion under pressure (TUP) at RT and equalchannel angular pressing (ECAP) at 400–500 $^{\circ}$C. Nanocrystalline or submicrocrystalline structures were obtained using TUP as a result of deformation ($\epsilon=5.75$), directly or during post-deformation heating. In alloys having initial martensitic structure, amorphized structure having atomic coordination on the base of B2-austenite lattice forms as a result of the deformation. During further heating at 400–450 $^{\circ}$C, amorphized structure crystallizes in a nanocrystalline austenite structure. In alloys having initial austenitic structure, nanocrystalline austenite structure forms as a result of deformation. During further heating it coarsens and transforms to a submicrocrystalline structure at 450 $^{\circ}$C. As a result of ECAP of Ti – 50.0%Ni alloy in 12 passes at 500 $^{\circ}$C and 8 passes at 400 $^{\circ}$C, a submicrocrystalline structure forms. It provides shape recovery properties comparable to the ones obtained by polygonizing annealing after cold deformation

Stability of ultrafine-grained microstructure in fcc metals processed by severe plastic deformation

The thermal stability of ultrafine-grained (UFG) microstructure in face centered cubic metals processed by severe plastic deformation (SPD) was studied. The influence of the SPD procedure on the stability was investigated for Cu samples processed by Equal-Channel Angular Pressing (ECAP), High-Pressure Torsion (HPT), Multi-Directional Forging and Twist Extrusion at room temperature (RT). It is found that HPT results in the lowest thermal stability due to the very high dislocation density. Furthermore, the effect of the low stacking fault energy of Ag on the stability is also investigated. It is revealed that the UFG microstructure produced in Ag by ECAP is recovered and recrystallized during storage at room temperature. The driving force for this unusual recovery and recrystallization is the high dislocation density developed during ECAP due to the high degree of dislocation dissociation caused by the very low stacking fault energy of Ag.<br/

Influence of high pressure torsion-induced grain refinement and subsequent aging on tribological properties of Cu-Cr-Zr alloy

Effects of ultrafine grain formation via high pressure torsion (HPT) and precipitation during aging on the microstructure, mechanical and tribological properties of a Cu-Cr-Zr alloy have been investigated systematically. HPT results in the formation of ultrafine-grained (UFG) structure in the alloy with an average grain/subgrain size of 155 nm which leads to remarkable improvement in its hardness and strength along with a reduction in elongation to failure. Aging of UFG alloy brings about further strengthening due to the precipitation. UFG formation by HPT increases substantially the wear resistance of Cu-Cr-Zr alloy and reduces the friction coefficient. The highest wear resistance and the lowest friction coefficient are obtained on the sample processed by HPT and subsequent aging. The dominant wear mechanism of the alloy varies depending on the applied processes. Adhesion with smearing is the predominant wear mechanism for the initial (warm extruded) samples having coarse-grained (CG) structure. UFG samples show less adhesional effect with less smearing, and a higher tendency to the formation of cracks, abrasion and delamination seem to be dominant in those samples. Oxidative wear mechanism is also operative in both CG and UFG alloy samples. It may be concluded from this study that a combined process including UFG formation by HPT and subsequent precipitation by artificial aging provides a simple and effective processing procedure for improving the strength, hardness and wear resistance of Cu–Cr–Zr alloys without modification of the chemical composition. © 2018 Elsevier B.V

Optimization of strength, ductility and electrical conductivity of Cu-Cr-Zr alloy by combining multi-route ECAP and aging

Properties of Cu-Cr-Zr alloy with ultrafine-grained (UFG) structure produced by equal-channel angular pressing (ECAP) via different routes have been investigated. Special attention was paid to the optimization of multi-functional structural, thermal, electrical and mechanical properties of the alloy by aging of UFG one. Multi-pass ECAP via different routes gives rise to the formation of a deformation-induced submicrocrystalline structure with the grain (subgrain) sizes in the range of 200-300. nm depending on applied routes which leads to high hardness and strength in the Cu-Cr-Zr alloy with reduced ductility. Amongst the applied routes, route-Bc was found to be the best processing path for achieving the lowest grain size, the highest hardness and strength. Aging of 8Bc-processed UFG samples increases the hardness and strength of Cu-Cr-Zr alloy while retaining an electrical conductivity comparable to that of aged coarse-grained (CG) one. A satisfactory electrical conductivity of 71%IACS without considerable loss of peak hardness was achieved after aging of 8Bc-processed UFG alloy at 425. °C for 240. min. The precipitation strengthened UFG alloy remains its stable behavior at elevated temperatures up to 450. °C. © 2015 Elsevier B.V

Structural changes in ferrite-austenite steel 03Kh26N6 during hot torsion

Translated from Russian (Izv. Vyssh. Uchebn. Zaved., Chern. Metall. 1985 (3) p. 153-154)SIGLEAvailable from British Library Document Supply Centre- DSC:5828.4(M--36451)T / BLDSC - British Library Document Supply CentreGBUnited Kingdo