This paper builds on recent work developed by the authors for the numerical analysis of large strain solid dynamics, by introducing an upwind cell centred hexahedral finite volume framework implemented within the open source code OpenFOAM [http://www.openfoam.com/]. In Lee, Gil and Bonet (2013), a first‐order hyperbolic system of conservation laws was introduced in terms of the linear momentum and the deformation gradient tensor of the system, leading to excellent behaviour in two‐dimensional bending dominated nearly incompressible scenarios. The main aim of this paper is the extension of this algorithm into three dimensions, its tailor‐made implementation into OpenFOAM and the enhancement of the formulation with three key novelties. First,...
In Part I of this series, Bonet et al. (2015) introduced a new computational framework for the analy...
This paper presents a new Smooth Particle Hydrodynamics (SPH) computational framework for large stra...
Cotutela Universitat Politècnica de Catalunya i Swansea UniversityIn practical engineering applicati...
This paper builds on recent work developed by the authors for the numerical analysis of large strain...
This paper builds on recent work developed by the authors for the numerical analysis of large strain...
The paper presents a new computational framework for the numerical simulation of fast large strain s...
This paper presents an explicit vertex centred finite volume method for the solution of fast transie...
In previous work (Lee et al., 2016, 2017), Lee et al. introduced a new Smooth Particle Hydrodynamics...
Over the past few decades, dynamic solid mechanics has become a major field of interest in industria...
This paper introduces a new computational framework for the analysis of large strain fast solid dyna...
This paper introduces a new computational framework for the analysis of large strain fast solid dyna...
In Part I of this series, Bonet et al. [1] introduced a new computational framework for the analysis...
A vertex centred Jameson–Schmidt–Turkel (JST) finite volume algorithm was recently introduced by the...
This paper presents a new Smooth Particle Hydrodynamics (SPH) computational framework for large stra...
In Part I of this series, Bonet et al. (2015) introduced a new computational framework for the analy...
This paper presents a new Smooth Particle Hydrodynamics (SPH) computational framework for large stra...
Cotutela Universitat Politècnica de Catalunya i Swansea UniversityIn practical engineering applicati...
This paper builds on recent work developed by the authors for the numerical analysis of large strain...
This paper builds on recent work developed by the authors for the numerical analysis of large strain...
The paper presents a new computational framework for the numerical simulation of fast large strain s...
This paper presents an explicit vertex centred finite volume method for the solution of fast transie...
In previous work (Lee et al., 2016, 2017), Lee et al. introduced a new Smooth Particle Hydrodynamics...
Over the past few decades, dynamic solid mechanics has become a major field of interest in industria...
This paper introduces a new computational framework for the analysis of large strain fast solid dyna...
This paper introduces a new computational framework for the analysis of large strain fast solid dyna...
In Part I of this series, Bonet et al. [1] introduced a new computational framework for the analysis...
A vertex centred Jameson–Schmidt–Turkel (JST) finite volume algorithm was recently introduced by the...
This paper presents a new Smooth Particle Hydrodynamics (SPH) computational framework for large stra...
In Part I of this series, Bonet et al. (2015) introduced a new computational framework for the analy...
This paper presents a new Smooth Particle Hydrodynamics (SPH) computational framework for large stra...
Cotutela Universitat Politècnica de Catalunya i Swansea UniversityIn practical engineering applicati...