Simulation of the cone penetration test: Discrete and continuum approaches

Antonio Gens; Marcos Arroyo; Joanna Butlanska; Josep Maria Carbonell; Matteo Ciantia; Lluís Monforte; Catherine O'Sullivan

Simulation of the cone penetration test: Discrete and continuum approaches

Antonio Gens, Marcos Arroyo, Joanna Butlanska, Josep Maria Carbonell, Matteo Ciantia, Lluís Monforte, Catherine O'Sullivan

Civil Engineering

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

The paper presents the modelling of the cone penetration test using two procedures: a discrete approach and a continuum approach. The discrete approach is based on the Discrete Element Method where a granular material is represented by an assembly of separate particles. Cone penetration has been simulated for both uncrushable and crushable sands. For the continuum approach, the Particle Finite Element Method has been adapted in order to overcome the difficulties posed by the occurrence of large displacements as well as by the geometrical, material and contact nonlinearities of the problem. Both single phase and two-phase (coupled hydromechanical) formulations have been developed and applied. Although not exempt from problems, both approaches yield realistic results leading to the possibility of a closer examination and an enhanced understanding of the mechanisms underlying cone penetration.

Original language	English
Pages (from-to)	169-182
Number of pages	14
Journal	Australian Geomechanics
Volume	51
Issue number	4
Publication status	Published - Dec 2016

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title = "Simulation of the cone penetration test: Discrete and continuum approaches",

abstract = "The paper presents the modelling of the cone penetration test using two procedures: a discrete approach and a continuum approach. The discrete approach is based on the Discrete Element Method where a granular material is represented by an assembly of separate particles. Cone penetration has been simulated for both uncrushable and crushable sands. For the continuum approach, the Particle Finite Element Method has been adapted in order to overcome the difficulties posed by the occurrence of large displacements as well as by the geometrical, material and contact nonlinearities of the problem. Both single phase and two-phase (coupled hydromechanical) formulations have been developed and applied. Although not exempt from problems, both approaches yield realistic results leading to the possibility of a closer examination and an enhanced understanding of the mechanisms underlying cone penetration.",

author = "Antonio Gens and Marcos Arroyo and Joanna Butlanska and Carbonell, {Josep Maria} and Matteo Ciantia and Llu{\'i}s Monforte and Catherine O'Sullivan",

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T2 - Discrete and continuum approaches

AU - Gens, Antonio

AU - Arroyo, Marcos

AU - Butlanska, Joanna

AU - Carbonell, Josep Maria

AU - Ciantia, Matteo

AU - Monforte, Lluís

AU - O'Sullivan, Catherine

PY - 2016/12

Y1 - 2016/12

N2 - The paper presents the modelling of the cone penetration test using two procedures: a discrete approach and a continuum approach. The discrete approach is based on the Discrete Element Method where a granular material is represented by an assembly of separate particles. Cone penetration has been simulated for both uncrushable and crushable sands. For the continuum approach, the Particle Finite Element Method has been adapted in order to overcome the difficulties posed by the occurrence of large displacements as well as by the geometrical, material and contact nonlinearities of the problem. Both single phase and two-phase (coupled hydromechanical) formulations have been developed and applied. Although not exempt from problems, both approaches yield realistic results leading to the possibility of a closer examination and an enhanced understanding of the mechanisms underlying cone penetration.

AB - The paper presents the modelling of the cone penetration test using two procedures: a discrete approach and a continuum approach. The discrete approach is based on the Discrete Element Method where a granular material is represented by an assembly of separate particles. Cone penetration has been simulated for both uncrushable and crushable sands. For the continuum approach, the Particle Finite Element Method has been adapted in order to overcome the difficulties posed by the occurrence of large displacements as well as by the geometrical, material and contact nonlinearities of the problem. Both single phase and two-phase (coupled hydromechanical) formulations have been developed and applied. Although not exempt from problems, both approaches yield realistic results leading to the possibility of a closer examination and an enhanced understanding of the mechanisms underlying cone penetration.

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