Abstract
The paper investigated the residual strain and stress distribution, microstructure, and macro-texture along the transverse direction of commercially pure titanium grade 2 samples prepared by the CONFORM ECAP technique. This method belongs to the severe plastic deformation methods; hence, it could be assumed that residual stress fields would be present in the work-pieces. Residual stresses cannot be directly measured; thus, neutron diffraction measurements, Electron back-scatter diffraction (EBSD) investigations, and local X-ray macro-texture measurements were performed in different regions of the sample to determine the data for the residual stress calculation. The calculation was based on the modified Kröner model. Neutron diffraction strain scans and residual stress calculations revealed that symmetrical residual strain and stress gradients with compression character were present in the axial and hoop direction after one and two passes. Asymmetric distribution of the residual strains and stresses remained after the third pass of the CONFORM ECAP. EBSD investigations showed that after the first pass, significant grain refinement occurred; however, further passes did not cause any dramatic grain refinement. X-ray texture measurements revealed that local macro-texture was dependent on the number of passes of the CONFORM ECAP and on the investigated area in the samples.
Highlights
Titanium and its alloys have a wide range of applications due to possessing high strength, low density, excellent corrosion resistivity, and nontoxicity [1]
The objective of the present paper was the investigation of the residual strain using neutron diffraction in commercially pure (CP) Ti grade 2 samples processed by the C-equal-channel angular pressing (ECAP) method
B0 ), because the 3 in the axial direction of the initial sample were taken as the stress-free reference
Summary
Titanium and its alloys have a wide range of applications due to possessing high strength, low density, excellent corrosion resistivity, and nontoxicity [1]. The desired mechanical properties are usually achieved through alloying. Metals 2018, 8, 1000 for new approaches, which can lead to the enhancement of the mechanical properties without harmful additives. One of the possible approaches is the processing of the material using severe plastic deformation (SPD). It has been shown that SPD processes can significantly improve the mechanical properties of materials through grain refinement and the introduction of many lattice defects [2]. The equal-channel angular pressing (ECAP) method, where the billet is pressed through two intersecting channels, belongs to the most popular method. In the last two decades, many studies have appeared on the topic of ECAP processed titanium alloys. All investigations agreed that the ECAP method led to an ultra-fine grained (UFG)
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