A Study of the Metallurgical and Mechanical Properties of Friction-Stir-Processed Cu

Michael Regev,Stefano Spigarelli

doi:10.3390/met11040656

Michael Regev, Stefano Spigarelli

Open Access

https://doi.org/10.3390/met11040656

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Journal: Metals	Publication Date: Apr 17, 2021
Citations: 10	License type: CC BY 4.0

Affiliation: ORT Braude College, Marche Polytechnic University

Abstract

Friction stir processing (FSP), a severe plastic deformation process, was applied on pure Cu to obtain a stir zone with a very fine grain size. Yet, when FSP is used, the stir zone is as wide as the diameter of the shoulder at the upper surface of the weld and markedly narrower near its opposite surface. This property, as well as the differences between the advancing side and the retreating side, makes it impossible to obtain a uniform cross-section as far as the microstructure and mechanical properties are concerned. For these reasons, a new approach is proposed in which the material was processed on both sides, thus yielding a wider, rectangular and more homogenous stir zone from which all the specimens were machined out. Processing the material from both sides eliminated any microstructural difference between the upper and the lower side, at least within the gauge length’s cross-section of the creep specimens. Although grain refinement was detected, the mechanical properties of the friction-stir-processed (FSP’ed) material are inferior relative to those of the parent material. The TEM study reported in the current paper revealed the existence of nanosized grains in the FSP’ed material due to dynamic recrystallization (DRX) occurring during the processing stage. Because both X-ray inspection and fractography showed that the FSP’ed material was free of defects, the material may not comply with the Hall–Petch relation due to lower dislocation density caused by XRD occurring during FSP. The inverse Hall–Petch effect may also be considered as an assistive mechanism in mechanical property deterioration.

Highlights

Twinned grains having an average grain size of about 10–20 μm are discernible in the parent metal, while the processed material consists of nonuniform equiaxed grains whose size varies from about 1 μm up to about 20 μm
All the measurements were taken across the stir zone, perpendicular to its longitudinal axis while maintaining a distance of 0.5 mm from one indentation to another
Keeping in mind that the gauge length of the tensile specimens was machined out from a ±1.5 mm wide strip with respect to the center of the stir zone, one can see that the hardness of the stir zone varies markedly with the location

Summary

Introduction

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Friction stir processing (FSP) was derived from friction stir welding (FSW) in 2000 and was first reported by Mishra et al [1]. FSP is identical to FSW except that, in FSP, the rotating tool does not weld the parts to one another. Because it is a severe plastic deformation process, FSP aims to attain a stir zone with a very fine grain size and improve the mechanical properties of the material being processed

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