A continuum mechanics based four‐node shell element for general non‐linear analysis

Dvorkin, Eduardo N.; Bathe, Klaus‐Jürgen

doi:10.1108/eb023562

Cited by 1,110 publications

(579 citation statements)

References 15 publications

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“…The web was modelled with an elastic, orthotropic, moisture-dependent material and 4-node fully integrated shell elements (ANSYS, 2005). The elements used the assumed shear strain formulation to alleviate shear locking (Dvorkin and Bathe, 1984). In addition, the method of incompatible modes was employed in formulation, in order to enhance the accuracy in bending-dominated states (Simo and Armero, 1992).…”

Section: Numerical Analysis Of Paper With Micro Scale Strain Variationsmentioning

confidence: 99%

Basic mechanisms of fluting formation and retention in paper

Kulachenko

Gradin

Uesaka

2007

Mechanics of Materials

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Out-of-plane deformations of paper, such as fluting, significantly deteriorate the quality of a printed product. There are several explanations of fluting presented in the literature but there is no unanimously accepted theory regarding fluting formation and retention which is consistent with all field observations. This paper first reviews the existing theories and proposes a mechanism that might give an answer to most of the questions regarding fluting. The fluting formation has been considered as a post-buckling phenomenon which has been analysed with the help of the finite element method. Fluting retention has been modelled by introducing an ink layer over the paper surface with the ink stiffness estimated from experimental results. The impact of fast drying on fluting has been assessed numerically and experimentally. The result of the study suggests that fluting occurs due to small-scale hygro-strain variations, which in turn are caused by the moisture variations created during fast convection (through-air) drying. The result also showed that ink stiffening alone cannot explain the fluting amplitudes observed in practice, but that high drying temperatures promote inelastic (irreversible) deformations in paper and this may itself preserve fluting.

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Section: Numerical Analysis Of Paper With Micro Scale Strain Variationsmentioning

confidence: 99%

Basic mechanisms of fluting formation and retention in paper

Kulachenko

Gradin

Uesaka

2007

Mechanics of Materials

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“…Most of the earlier developed methods were based on enhanced assumed strain fields and consisted of either the use of a conventional integration with appropriate control of all locking phenomena, or the application of a reduced integration technique with hourglass control. Both approaches have been extensively investigated and evaluated on various structural applications as reported in the work of (Dvorkin et al, 1984;Belytschko et al, 1993;Zhu et al, 1996;Wriggers et al, 1996;Klinkel et al, 1997Klinkel et al, , 1999Wall et al, 2000;Reese et al, 2000;Puso et al, 2000).…”

Section: Introductionmentioning

confidence: 99%

A physically stabilized and locking-free formulation of the (SHB8PS) solid-shell element

Abed‐Meraim

Combescure

2007

European Journal of Computational Mechanics

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“…Thereafter, the calculated components are evaluated at the Gauss points using bilinear or linear interpolation functions (depending on the number of sampling points) from their values at the sampling points. This method was originally applied for four shell elements by Dvorkin and Bathe [4] ant it has proven to be efficient, very robust and to give very good results for four node plate bending theory based on Mindlin/Reissner plate theory in [30] (applied on the transverse shear strain components E 13 , E 23 ). This method was later extended to overcome the curvature thickness locking by modifying the interpolation of the transverse normal strain component E 33 for four-node shell elements, as proposed by Betsch and Stein [29] and also Bischoff and Ramm [31].…”

Section: Introductionmentioning

confidence: 99%

“…These solid-shell elements possess eight nodes with only displacement nodal degrees of freedom (DOF). In order to overcome various locking pathologies, the SSH3D formulation employs the well known Enhanced Assumed Strain (EAS) concept originally introduced by Simo and Rifai [3] and based on the Hu-Veubeke-Washizu variational principle combined with the Assumed Natural Strain (ANS) technique based on the work of Dvorkin and Bathe [4]. For the RESS solid-shell element, on the other hand, only the EAS technique is used with a Reduced Integration (RI) Scheme.…”

mentioning

confidence: 99%

On the comparison of two solid-shell formulations based on in-plane reduced and full integration schemes in linear and non-linear applications

Bettaieb

Sena

Sousa

et al. 2015

Finite Elements in Analysis and Design

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In the present paper, a detailed description of the formulation of the new SSH3D solid-shell element is presented. This formulation is compared with the previously proposed RESS solid-shell element [1,2]. Both elements were recently implemented within the LAGAMINE in-house research finite element code. These solid-shell elements possess eight nodes with only displacement nodal degrees of freedom (DOF). In order to overcome various locking pathologies, the SSH3D formulation employs the well known Enhanced Assumed Strain (EAS) concept originally introduced by Simo and Rifai [3] and based on the Hu-Veubeke-Washizu variational principle combined with the Assumed Natural Strain (ANS) technique based on the work of Dvorkin and Bathe [4]. For the RESS solid-shell element, on the other hand, only the EAS technique is used with a Reduced Integration (RI) Scheme. A particular characteristic of these elements is their special integration schemes, with an arbitrary number of integration points along the thickness direction, dedicated to analyze problems involving non-linear through-thickness distribution (i.e. metal forming applications) without requiring many element layers. The formulation of the SSH3D element is also particular, with regard to the solid-shell elements proposed in the literature, in the sense that it is characterized by an in-plane full integration and a large variety in terms of (i) enhancing parameters, (ii) the ANS version choice and (iii) the number of integration points through the thickness direction. The choice for these three parameters should be adapted to each problem so as to obtain accurate results and to keep the calculation time low. Numerous numerical examples are performed to investigate the performance of these elements. These examples illustrate the reliability and the efficiency of the proposed formulations in various cases including linear and non-linear problems. SSH3D element is more robust thanks to the various options proposed and its full in-plane integration scheme, while RESS element in more efficient from a computational point of view.

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A continuum mechanics based four‐node shell element for general non‐linear analysis

Cited by 1,110 publications

References 15 publications

Basic mechanisms of fluting formation and retention in paper

Basic mechanisms of fluting formation and retention in paper

A physically stabilized and locking-free formulation of the (SHB8PS) solid-shell element

On the comparison of two solid-shell formulations based on in-plane reduced and full integration schemes in linear and non-linear applications

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