Influence of Cold Plastic Deformation on the Structure and Physicomechanical Properties of the Biocompatible Low-Modulus Zr51Ti31Nb18 Alloy

The influence of the degree of compression in the range of 46–84% upon cold rolling of rods of a biocompatible low-modulus Zr 51 Ti 31 Nb 18 (IMP BAZALM) alloy preliminarily quenched from the β field on the formation of its structure, phase composition, and physicomechanical properties (hardness, el...

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Bibliographic Details
Published inPhysics of metals and metallography Vol. 120; no. 8; pp. 790 - 795
Main Authors Grib, S. V., Ivasishin, O. M., Illarionov, A. G., Popov, A. A.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.08.2019
Springer Nature B.V
Subjects
Biocompatibility
Chemistry and Materials Science
Cold rolling
Diffusion
Elastic deformation
Elastic properties
Electron diffraction
Elongation
Materials Science
Metallic Materials
Microhardness
Microscopy
Modulus of elasticity
Optical microscopy
Phase composition
Phase Transformations
Plastic deformation
Rods
Structure
Zirconium base alloys
Zr–Ti–Nb system
quenching
texture
elastic modulus
cold deformation
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Summary:The influence of the degree of compression in the range of 46–84% upon cold rolling of rods of a biocompatible low-modulus Zr 51 Ti 31 Nb 18 (IMP BAZALM) alloy preliminarily quenched from the β field on the formation of its structure, phase composition, and physicomechanical properties (hardness, elastic modulus) has been studied by the methods of optical microscopy, transmission electron microscopy, X-ray diffraction analysis, back-scattering electron diffraction, and microindentation. It has been established that with an increase in the degree of compression, a reorientation and elongation of the initially equilibrium β grains occur along the direction of rolling with the formation of a perfect filamentary structure in the rods with a minimum cross-section. The values of microhardness are stabilized in the range of 320–325 HV due to the development of dynamic recovery processes in the deformed structure, and the elastic modulus decreases from 68 to 55 GPa in the rolling plane of rods owing to the improvement of the {001}RP〈110〉RD-type texture, which leads to the appearance of the predominantly “low-modulus” 〈110〉 orientation in the direction of measurement.
ISSN:0031-918X
1555-6190
DOI:10.1134/S0031918X19080040