Experimental and FEM Analysis of Wear Behaviour in AA5083 Ultrafine-Grained Cams

C J Luis Pérez,I Puertas Arbizu,R Luri Irigoyen,J León Iriarte,J P Fuertes Bonel,D Salcedo Pérez

doi:10.3390/met10040479

C J Luis Pérez, I Puertas Arbizu + Show 4 more

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https://doi.org/10.3390/met10040479

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Journal: Metals	Publication Date: Apr 4, 2020
Citations: 6	License type: CC BY 4.0

Affiliation: Universidad Publica de Navarra

Abstract

Severe plastic deformation (SPD) processes have attracted a great deal of both scientific and technological interest over the last few years as a consequence of the improvements that are possible to obtain in the microstructure and mechanical properties of the materials manufactured through the use of these kind of processes. However, the practical applications of such materials to obtain mechanical components are significantly fewer. As a direct consequence, the same thing has been observed in the development of studies that show the in-service behaviour of the mechanical components developed in this way. Since one of the industrial objectives of these SPD processes is to obtain functional parts, it is necessary to carry out studies to fill this gap. Therefore, in this study, an analysis of the wear that cams undergo when manufactured from an AA5083 aluminium-magnesium alloy is carried out. The cams were isothermally-forged from materials with and without previous SPD processing by equal channel angular pressing (ECAP). Subsequently, the wear behaviour of these cams was analysed by using specific equipment, which may have been considered to have a block-on-ring configuration, developed for testing in-service wear behaviour of mechanical parts. From this comparative wear study with cams, it is shown that previously-processed materials by ECAP have a better wear performance. Moreover, finite element modelling (FEM) simulations were also included to predict wear in the cams processed in this way. A good agreement between FEM and experimental results was obtained. It is this aspect of performing the wear tests on functional and real mechanical components, and not on laboratory samples, which makes this present research work novel.

Highlights

Over the last few years, there has been a growing interest in the development of ultrafine-grained materials (UFG) as a consequence of the improvement in their mechanical properties, compared to those obtained in a non-nanostructured state [1]
Several finite element modelling (FEM) simulations were carried out with different K values until the values were obtained that predicted wear with an accuracy of less than 1% by comparing the loss in volume provided by FEM with that obtained from experimental results
The cams obtained by previous severe plastic deformation (SPD) using equal channel angular pressing (ECAP) and isothermal forging exhibited better in-service wear behaviour than those that were isothermally-forged from annealed materials at the experimental values under consideration in this study and for the AA5083 aluminium alloy, where this beneficial effect may be explained by the improvement in the microhardness that these ECAP-processed cams underwent

Summary

Introduction

Over the last few years, there has been a growing interest in the development of ultrafine-grained materials (UFG) as a consequence of the improvement in their mechanical properties, compared to those obtained in a non-nanostructured state [1]. One of the main ways to obtain bulk ultrafine-grained materials is by means of severe plastic deformation (SPD) processes, where equal channel angular pressing (ECAP) is one of the main processes used to obtain these materials. This process has several innovative technological characteristics compared to traditional metal-working processes [3]. It is possible to obtain bulk ultrafine-grained materials

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