Prediction of necking in HCP sheet metals using a two-surface plasticity model

Jedidi, Mohamed Yassine; Bettaieb, Mohamed Ben; Abed‐Meraim, Farid; Khabou, Mohamed Taoufik; Bouguecha, Anas; Haddar, Mohamed

doi:10.1016/j.ijplas.2019.102641

Cited by 10 publications

(1 citation statement)

References 58 publications

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“…[9][10][11][12][13][14] In fact, three types of macroscopic plastic deformation heterogeneities, namely, Lüders bands, 15 Portevin-Le Chatelier band, 16,17 and necking 18 are usually considered in the ductile metallic materials. The necking phenomenon has received much attention in the literature [19][20][21] and is the obvious manifestation of strain localization at the macroscopic scale that happens when the load reaches its peak. 22 In ductile materials, this phenomenon is mainly resulted from the plastic tension.…”

Section: Introductionmentioning

confidence: 99%

Correction of the stress–strain curve for 2024 aluminum alloy after necking using the new surface strain method

Shahrjerdi

Mohammadi

2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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Nowadays, many studies concerning plasticity and numerical simulations indicate that the true stress–strain curve plays a prominent role in the analysis of metal deformation. Hence, a new method is considered to correct the stress–strain curve based on image processing. Since the axial stress mainly becomes triaxial in the neck zone, the relationship obtained from the engineering stress–strain curve is not reliable in terms of authenticity and accuracy. Accordingly, correcting this relationship is highly advantageous and necessary. Due to the triaxial state of stress in the plastic area, longitudinal and surface strains are calculated through image processing and the correction coefficient of the stress–strain curve is obtained based on them. The equation of the stress–strain curve is based on the Hollowman relation until the onset of necking and then becomes almost linear. The finite element method (FEM) is employed for validating the obtained results. Since the corrected stress and strain equation is linear, the objective function of optimization is considered. This optimization is based on minimizing the difference between the three diameters values of the specimen, which are observed through experiment and FEM. Besides, a statistical method with the help of the genetic algorithm is employed to minimize this difference. As a result, an optimal equation is predicted for the 2024 aluminum based on the stress–strain curve of the error rate. Finally, a comparison is made between the results obtained from the surface strain method and the results obtained from the classical methods of Bridgman and Davidenkov, and a good agreement is observed between them.

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Section: Introductionmentioning

confidence: 99%

Correction of the stress–strain curve for 2024 aluminum alloy after necking using the new surface strain method

Shahrjerdi

Mohammadi

2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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An Anisotropic Model with Linear Perturbation Technique to Predict HCP Sheet Metal Ductility Limit

Jedidi

Bettaieb

Abed‐Meraim

et al. 2021

Lecture Notes in Mechanical Engineering

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In this paper, hexagonal closed packed (HCP) sheet metal ductility for a viscoplastic material is analyzed by using a linear perturbation technique. It can be used for the analysis of localized necking. This technique is used to perturbate the material behavior in a rate dependent formulation by superimposing a perturbation to the basic flow which its stability or instability is characterized by the increasing or decreasing of the perturbation. Hardening and initial anisotropic parameters are fitted by experimental results from the literature. In this investigation, Cazacu yield function is used to predict the forming limit diagrams (FLDs) of HCP sheet metals. The coupling between analytic perturbation method and the behavior modelling is provided by an efficient implicit algorithm to solve the constitutive equations. After verifications and validations of the numerical simulations from the literature, the ductility limit of a particular HCP magnesium alloy is numerically predicted. A parametric study is presented to analyze the effect of instability and mechanical parameters, viscosity and distortion on the FLDs. Moreover, a comparative study between Marciniak and Kuckzynski ductility approach and linear perturbation technique is done in this contribution.

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Investigation of the effect of morphological and crystallographic textures on the ductility limits of thin metal sheets using a CPFEM-based approach

Zhou,

Ben Bettaieb,

Abed-Meraim

2024

European Journal of Mechanics - A/Solids

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Prediction of necking in HCP sheet metals using a two-surface plasticity model

Cited by 10 publications

References 58 publications

Correction of the stress–strain curve for 2024 aluminum alloy after necking using the new surface strain method

Correction of the stress–strain curve for 2024 aluminum alloy after necking using the new surface strain method

An Anisotropic Model with Linear Perturbation Technique to Predict HCP Sheet Metal Ductility Limit

Investigation of the effect of morphological and crystallographic textures on the ductility limits of thin metal sheets using a CPFEM-based approach

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