A stabilised Petrov–Galerkin formulation for linear tetrahedral elements in compressible, nearly incompressible and truly incompressible fast dynamics

Gil, Antonio J.; Lee, Chun Hean; Bonet, Javier; Aguirre, Miquel

doi:10.1016/j.cma.2014.04.006

Cited by 70 publications

(202 citation statements)

References 78 publications

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“…More recently, the p-F formulation was improved in [5] for the case of nearly incompressible materials, by means of an additional conservation law for the Jacobian of the deformation J (widely known as volume map conservation law [42,[54][55][56][57]), providing extra flexibility for the calculation of the volumetric stress. This innovative idea extended the range of use of the formulation to nearly and fully incompressible media.…”

Section: Introductionmentioning

confidence: 99%

An upwind vertex centred Finite Volume solver for Lagrangian solid dynamics

Aguirre

Gil

Bonet

et al. 2015

Journal of Computational Physics

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152

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A vertex centred Jameson-Schmidt-Turkel (JST) finite volume algorithm was recently introduced by the authors (Aguirre et al., 2014 [1]) in the context of fast solid isothermal dynamics. The spatial discretisation scheme was constructed upon a Lagrangian two-field mixed (linear momentum and the deformation gradient) formulation presented as a system of conservation laws [2][3][4]. In this paper, the formulation is further enhanced by introducing a novel upwind vertex centred finite volume algorithm with three key novelties. First, a conservation law for the volume map is incorporated into the existing two-field system to extend the range of applications towards the incompressibility limit (Gil et al., 2014 [5]). Second, the use of a linearised Riemann solver and reconstruction limiters is derived for the stabilisation of the scheme together with an efficient edge-based implementation. Third, the treatment of thermo-mechanical processes through a Mie-Grüneisen equation of state is incorporated in the proposed formulation. For completeness, the study of the eigenvalue structure of the resulting system of conservation laws is carried out to demonstrate hyperbolicity and obtain the correct time step bounds for non-isothermal processes. A series of numerical examples are presented in order to assess the robustness of the proposed methodology. The overall scheme shows excellent behaviour in shock and bending dominated nearly incompressible scenarios without spurious pressure oscillations, yielding second order of convergence for both velocities and stresses.

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Section: Introductionmentioning

confidence: 99%

An upwind vertex centred Finite Volume solver for Lagrangian solid dynamics

Aguirre

Gil

Bonet

et al. 2015

Journal of Computational Physics

Self Cite

152

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“…We also observe that this approach is not appealing for the implicit case since it results in a non-symmetric matrix. Let us consider the one-dimensional problem in figure (2). This corresponds to a bar with unit cross section, discretized using two elements of length h. Constant material properties Young's modulus E and density ρ are assumed.…”

Section: Mixed Formulation In Explicit Dynamicsmentioning

confidence: 99%

“…A vast literature exists proposing cures for such problems, with early proposals based on reduced integration techniques or on the use of corrected assumed-strains, see for instance, the F-bar method [1]. Mixed displacement-pressure approaches started to be employed in the 90s for the solution of truly incompressible problems [1,2,3,4,5]. Such techniques were also shown to provide an accuracy advantage when used in application to compressible problems (see e.g.…”

Section: Introductionmentioning

confidence: 99%

Explicit mixed strain-displacement finite element for dynamic geometrically non-linear solid mechanics

et al. 2015

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Aquesta és una còpia de la versió author's final draft d'un article publicat a la revista Computational mechanics. Although appealing for their simplicity, low-order finite elements face inherent limitations related to their poor convergence properties. Such difficulties typically manifest as mesh-dependent or excessively stiff behaviour when dealing with complex problems. A recent proposal to address such limitations is the adoption of mixed displacement-strain technologies which were shown to satisfactorily address both problems. Unfortunately, although appealing, the use of such element technology puts a large burden on the linear algebra, as the solution of larger linear systems is needed. In this paper, the use of an explicit time integration scheme for the solution of the mixed strain-displacement problem is explored as an alternative. An algorithm is devised to allow the effective time integration of the mixed problem. The developed method retains second order accuracy in time and is competitive in terms of computational cost with the standard irreducible formulation.

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“…All these mixed schemes are stabilized via the Variational Multi-Scale method (VMS) [21,31,32,33,41], and, specifically, the Orthogonal Subgrid Scales method, in order to gain control of all the variables while circumventing the restrictiveness of the inf-sup compatibility conditions on the choice of the interpolation spaces. Similar mixed approaches have been proposed using alternative stabilization techniques, like SUPG [4,5,29,36] or FIC [41].…”

Section: Introductionmentioning

confidence: 99%

“…Using displacements u as primary variables, the first proposals were based on reduced integration [30,38,39], and extended to the use of assumed deformations [47] and the B-bar method [31]. Mixed pressuredisplacement u − p approaches were introduced in the 90's and used thenceforth to address the incompressible limit [18,29,40,49]. The reason for using the pressure as independent variable is to gain control on it and ensure stability; this results in an overall satisfactory behavior of strains and stresses in quasi-incompressible situations.…”

Section: Introductionmentioning

confidence: 99%

Explicit mixed strain–displacement finite elements for compressible and quasi-incompressible elasticity and plasticity

et al. 2016

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K: explicit mixed finite elements, stabilization, incompressibility, plasticity, strain softening, strain localization, mesh independence. AbstractThis paper presents an explicit mixed finite element formulation to address compressible and quasi-incompressible problems in elasticity and plasticity. This implies that the numerical solution only involves diagonal systems of equations. The formulation uses independent and equal interpolation of displacements and strains, stabilized by variational subscales (VMS). A displacement sub-scale is introduced in order to stabilize the mean-stress field. Compared to the standard irreducible formulation, the proposed mixed formulation yields improved strain and stress fields. The paper investigates the effect of this enhancement on the accuracy in problems involving strain softening and localization leading to failure, using low order finite elements with linear continuous strain and displacement fields (P 1P 1 triangles in 2D and tetrahedra in 3D) in conjunction with associative frictional Mohr-Coulomb and Drucker-Prager plastic models. The performance of the strain/displacement formulation under compressible and nearly incompressible deformation patterns is assessed and compared to analytical solutions for plane stress and plane strain situations. Benchmark numerical examples show the capacity of the mixed formulation to predict correctly failure mechanisms with localized patterns of strain, virtually free from any dependence of the mesh directional bias. No auxiliary crack tracking technique is necessary.

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A stabilised Petrov–Galerkin formulation for linear tetrahedral elements in compressible, nearly incompressible and truly incompressible fast dynamics

Cited by 70 publications

References 78 publications

An upwind vertex centred Finite Volume solver for Lagrangian solid dynamics

An upwind vertex centred Finite Volume solver for Lagrangian solid dynamics

Explicit mixed strain-displacement finite element for dynamic geometrically non-linear solid mechanics

Explicit mixed strain–displacement finite elements for compressible and quasi-incompressible elasticity and plasticity

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