A 3D multi-scratch test model for characterizing material removal regimes in 5083-Al alloy

Elwasli, Fatma; Zemzemi, F.; Mkaddem, Ali; Mzali, Slah; Mezlini, Salah

doi:10.1016/j.matdes.2015.07.121

Cited by 33 publications

(12 citation statements)

References 25 publications

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“…It was also observed that the friction coefficient was reduced, and circumferential cracks developed around the particles. The failure modes are in accordance with simulations made by several researchers [ 14 , 15 , 16 ]. However, the models are focused on continuous and homogeneous materials free of defects, whereby the stress field in front of the tool has not been reported, nor the interaction with weaker particles, such as graphite.…”

Section: Introductionsupporting

confidence: 87%

Proposal of Characterization Procedure of Metal–Graphite Interface Strength in Compacted Graphite Iron

et al. 2018

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Compacted graphite iron is the material of choice for engine cylinder heads of heavy-duty trucks. Compacted graphite iron provides the best possible compromise between optimum mechanical properties, compared to flake graphite iron, and optimum thermal conductivity, compared to spheroidal graphite iron. The vermicular-shaped graphite particles, however, act as stress concentrators, and, as a result of delamination from the metal matrix, they are responsible for crack initiation during the thermomechanical fatigue cycles occurring through engine startup and shutdown cycles. Scratch tests driven over the matrix and into the graphite particles were performed in order to characterize the strength of the metal–graphite interface. Samples extracted from a cylinder head in as-cast condition were compared to samples subjected to a heat-treatment at 700 °C for 60 h. The former samples were composed of a primarily pearlitic matrix and graphite particles (~11.5 vol %), whereas, after annealing, a certain pearlite fraction decomposed into Fe and C, producing a microstructure with graphite–ferrite interfaces, exhibiting a partially spiky morphology. The scratch test revealed that the ferrite–graphite interfaces with spiky nature exhibited a stronger resistance to delamination compared to the ferrite–graphite interfaces with smooth morphology. One reason for the high interface strength is the mechanical interlocking between graphite spikes and ferrite, increasing the contact area between the two phases.

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Section: Introductionsupporting

confidence: 87%

Proposal of Characterization Procedure of Metal–Graphite Interface Strength in Compacted Graphite Iron

et al. 2018

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“…The properties of Al 5083 used here were adopted from Refs. [29,30] for the dynamic response of Al 5083 and are listed in Table 1. To enhance the accuracy of the model as well as facilitate obtaining a converged plastic strain distribution, a finer mesh was used in and around the pulse area where elements of 0.05 mm × 0.05 mm × 0.03 mm were chosen (Figure 1).…”

Section: D Simulation Of the Laser Peening Processmentioning

confidence: 99%

Laser Peening Analysis of Aluminum 5083: A Finite Element Study

Tajyar

Holtham

Brooks

et al. 2021

QuBS

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In this research, a finite element (FE) technique was used to predict the residual stresses in laser-peened aluminum 5083 at different power densities. A dynamic pressure profile was used to create the pressure wave in an explicit model, and the stress results were extracted once the solution was stabilized. It is shown that as power density increases from 0.5 to 4 GW/cm2, the induced residual stresses develop monotonically deeper from 0.42 to 1.40 mm. However, with an increase in the power density, the maximum magnitude of the sub-surface stresses increases only up to a certain threshold (1 GW/cm2 for aluminum 5083). Above this threshold, a complex interaction of the elastic and plastic waves occurring at peak pressures above ≈2.5 Hugoniot Elastic Limit (HEL) results in decreased surface stresses. The FE results are corroborated with physical experiments and observations.

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“…Traditionally, mesh-based finite element methods (FEM) have been preferred to model single asperity sliding in scratch tests. In modelling a highly dynamic and large scale deformation problem such as scratching, the selected explicit FE packages have used adaptive remeshing, element deletion and differential meshing to deal with problems of element distortion and high computational cost [10][11][12][13]. Ploughing models in the commercial FE packages have mostly used time-independent bilinear elastic-linearly hardening and Johnson-Cook material models and Columbic frictional contact at the interface [14,15].…”

Section: Introductionmentioning

confidence: 99%

Modelling of ploughing in a single-asperity sliding contact using material point method

Mishra

Ganzenmüller

Rooij

et al. 2019

Wear

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A 3D multi-scratch test model for characterizing material removal regimes in 5083-Al alloy

Cited by 33 publications

References 25 publications

Proposal of Characterization Procedure of Metal–Graphite Interface Strength in Compacted Graphite Iron

Proposal of Characterization Procedure of Metal–Graphite Interface Strength in Compacted Graphite Iron

Laser Peening Analysis of Aluminum 5083: A Finite Element Study

Modelling of ploughing in a single-asperity sliding contact using material point method

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