A reduced integration finite element technology based on a thermomechanically consistent stabilisation for 3D problems
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Publication:658810
DOI10.1016/J.CMA.2010.03.004zbMath1231.74421OpenAlexW2027353908MaRDI QIDQ658810
Publication date: 8 February 2012
Published in: Computer Methods in Applied Mechanics and Engineering (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.cma.2010.03.004
stabilityreduced integrationfinite strainsthermomechanical processeslocking-freefinite element technology
Finite element methods applied to problems in solid mechanics (74S05) Thermal effects in solid mechanics (74F05)
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Cites Work
- Hourglass control in linear and nonlinear problems
- Efficient implementation of quadrilaterals with high coarse-mesh accuracy
- Associative coupled thermoplasticity at finite strains: Formulation, numerical analysis and implementation
- Mixed finite element methods - reduced and selective integration techniques: a unification of concepts
- A theory of finite viscoelasticity and numerical aspects
- A multiple-quadrature eight-mode hexahedral finite element for large deformation elastoplastic analysis
- On the theoretical and numerical modelling of Armstrong-Frederick kinematic hardening in the finite strain regime.
- Improved versions of assumed enhanced strain tri-linear elements for 3D finite deformation problems
- An improved one-point integration method for large strain elastoplastic analysis
- Entropic thermoelasticity at finite strains. Aspects of the formulation and numerical implementation
- Assumed strain stabilization of the eight node hexahedral element
- On a physically stabilized one point finite element formulation for three-dimensional finite elasto-plasticity
- Thermomechanical modeling of metals at finite strains: first and mixed order finite elements
- Geometrically non-linear enhanced strain mixed methods and the method of incompatible modes
- Finite deformation coupled thermomechanical problems and ‘generalized standard materials’
- On a consistent hourglass stabilization technique to treat large inelastic deformations and thermo-mechanical coupling in plane strain problems
- A uniform deformation gradient hexahedron element with artificial hourglass control
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