Effect of the third invariant on the formation of necking instabilities in ductile plates subjected to plane strain tension

Rodríguez-Martínez, J.A.; Cazacu, Oana; Chandola, Nitin; N'souglo, Komi Espoir

doi:10.1007/s11012-021-01330-6

Cited by 5 publications

(6 citation statements)

References 51 publications

(123 reference statements)

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“…This technique is based on the superposition of a small perturbation on the homogeneous solution of the problem, so that if the perturbation grows faster than the background solution, the plastic flow is unstable and a non-homogeneous, neck-like deformation field can develop. We have used the same 2D approach employed in [43,51,63] so that the stress multiaxiality effects that develop inside the necked section have been approximated using Bridgman [11] correction. The fundamental solution of the problem is composed of 16 equations which are nondimensionalized, perturbed using the frozen coefficients method and linearized (note that in the case of N'souglo et al [42] the number of equations was 17 because the energy balance was taken into account).…”

Section: Linear Stability Analysismentioning

confidence: 99%

Theoretical predictions of dynamic necking formability of ductile metallic sheets with evolving plastic anisotropy and tension-compression asymmetry

et al. 2022

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In this paper, we have investigated necking formability of anisotropic and tension-compression asymmetric metallic sheets subjected to in-plane loading paths ranging from plane strain tension to near equibiaxial tension. For that purpose, we have used three different approaches: a linear stability analysis, a nonlinear two-zone model and unit-cell finite element calculations. We have considered three materials –AZ31-Mg alloy, high purity α-titanium and OFHC copper– whose mechanical behavior is described with an elastic-plastic constitutive model with yielding defined by the CPB06 criterion (15) which includes specific features to account for the evolution of plastic orthotropy and strength differential effect with accumulated plastic deformation (48). From a methodological standpoint, the main novelty of this paper with respect to the recent work of N’souglo et al. (42) –which investigated materials with yielding described by the orthotropic criterion of Hill (24)– is the extension of both stability analysis and nonlinear two-zone model to consider anisotropic and tension-compression asymmetric materials with distortional hardening. The results obtained with the stability analysis and the nonlinear two-zone model show reasonable qualitative and quantitative agreement with forming limit diagrams calculated with the finite element simulations, for the three materials considered, and for a wide range of loading rates varying from quasi-static loading up to 40000 s− 1, which makes apparent the capacity of the theoretical models to capture the mechanisms which control necking formability of metallic materials with complex plastic behavior. Special mention deserves the nonlinear two-zone model, as it does not need prior calibration –unlike the stability analysis– and it yields accurate predictions that rarely deviate more than 10% from the results obtained with the unit-cell calculations.

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Section: Linear Stability Analysismentioning

confidence: 99%

Theoretical predictions of dynamic necking formability of ductile metallic sheets with evolving plastic anisotropy and tension-compression asymmetry

et al. 2022

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“…Linear stability analysis: this technique is based on the superposition of a small perturbation on the homogeneous solution of the problem, so that if the perturbation grows faster than the background solution, the plastic flow is unstable and a non-homogeneous, neck-like deformation field can develop. We have used the same 2D approach employed in [51,33,39] so that the stress multiaxiality effects that develop inside the necked section have been approximated using Bridgman [8] correction. The fundamental solution of the problem is composed of 16 equations which are nondimensionalized, perturbed using the frozen coefficients method and linearized (note that in the case of N'souglo et al [32] the number of equations was 17 because the energy balance was taken into account).…”

Section: Problem Statementmentioning

confidence: 99%

Theoretical predictions of dynamic necking formability of ductile metallic sheets with evolving plastic anisotropy and tension-compression asymmetry

Kumar¹,

N'souglo²,

Hosseini³

et al. 2021

Preprint

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In this paper, we have investigated necking formability of anisotropic and tension-compression asymmetric metallic sheets subjected to in-plane loading paths ranging from plane strain tension to equibiaxial tension. For that purpose, we have used three different approaches: a linear stability analysis, a nonlinear two-zone model and unit-cell finite element calculations. We have considered three materials –AZ31-Mg alloy, high purity α-titanium and OFHC copper– whose mechanical behavior is described with an elastic-plastic constitutive model with yielding defined by the CPB06 criterion [10] which includes specific features to account for the evolution of plastic orthotropy and strength differential effect with accumulated plastic deformation [37]. From a methodological standpoint, the main novelty of this paper with respect to the recent work of N’souglo et al. [32] –which investigated materials with yielding described by the orthotropic criterion of Hill [19]– is the extension of both stability analysis and nonlinear two-zone model to consider anisotropic and tension-compression asymmetric materials with distortional hardening. The results obtained with the stability analysis and the nonlinear two-zone model show reasonable qualitative and quantitative agreement with forming limit diagrams calculated with the finite element simulations, for the three materials considered, and for a wide range of loading rates varying from quasi-static loading up to 40000 s−1, which makes apparent the capacity of the theoretical models to capture the mechanisms which control necking formability of metallic materials with complex plastic behavior. Special mention deserves the nonlinear two-zone model, as it does not need prior calibration –unlike the stability analysis– and it yields accurate predictions that rarely deviate more than 10% from the results obtained with the unit-cell calculations

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“…Very recently, Rodríguez-Martínez et al (2021) developed a linear stability analysis for plates subjected to plane strain tension modelled with the isotropic Drucker (1949) yield criterion, which depends on both the second and third invariant of the stress deviator. The analysis was performed for effective strain rates ranging from 10 −4 s −1 to 8 • 10 4 s −1 , and the theoretical results were compared with uni-cell finite element calculations, as in N'souglo et al (2020, 2021).…”

Section: Introductionmentioning

confidence: 99%

“…'souglo et al (2020, 2021)). Note that the normalized perturbation wavelength is usually referred to as necking wavelength(N'souglo et al, 2020;Rodríguez-Martínez et al, 2021). The root of the polynomial with physical meaning is the one with the greatest positive real part(Dudzinski and Molinari, 1991), hereinafter denoted by η+ .…”

mentioning

confidence: 99%

“…The root of the polynomial with physical meaning is the one with the greatest positive real part(Dudzinski and Molinari, 1991), hereinafter denoted by η+ . According to the notation used by ElMaï et al (2014) andRodríguez-Martínez et al (2021), among others, η+ will be referred to as instantaneous instability index, and it will be used to compute the so-called cumulative instability index I = t 0 η+ ε1 dτ , which tracks the history of the instantaneous grow rate of all the growing modes.The cumulative instability index generally provides better predictions than the instantaneous instability index for the critical strain leading to necking formation at high strain rates (see the recent paper of Rodríguez-Martínez et al (2021)). Assuming that a perturbation mode turns into a necking mode when the cumulative instability index reaches a critical value which depends on the loading path and the strain rate, see Section 3.1, the linear stability analysis is used in Section 3 to construct forming limit diagrams which are compared with unit-cell finite element simulations performed in ABAQUS/Explicit (2019) to demonstrate the ability of the analytical model to capture the effect of porosity on necking localization (this is same methodology used byN'souglo et al (2021) to assess the ability of the linear stability analysis to capture the effect of anisotropy on necking localization in materials described withHill (1948) yield criterion).…”

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confidence: 99%

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A new analytical model to predict the formation of necking instabilities in porous plates subjected to dynamic biaxial loading

2021

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Effect of the third invariant on the formation of necking instabilities in ductile plates subjected to plane strain tension

Cited by 5 publications

References 51 publications

Theoretical predictions of dynamic necking formability of ductile metallic sheets with evolving plastic anisotropy and tension-compression asymmetry

Theoretical predictions of dynamic necking formability of ductile metallic sheets with evolving plastic anisotropy and tension-compression asymmetry

Theoretical predictions of dynamic necking formability of ductile metallic sheets with evolving plastic anisotropy and tension-compression asymmetry

A new analytical model to predict the formation of necking instabilities in porous plates subjected to dynamic biaxial loading

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