A Parabolic Failure Criterion for Transversely Isotropic Rock: Modification and Verification

Wang, Dingjian; Tang, Huiming; Shen, Ping; Cai, Yongchang

doi:10.1155/2019/8052560

Cited by 4 publications

(2 citation statements)

References 38 publications

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“…9), where the best fit function is a parabola. This recovers the parabolic failure criterion, recently suggested and experimentally verified (see Yuan et al (2020), Wang et al (2019), Singh and Rao (2005)). This also captures the transition from a linear behavior at low confining pressures to a pressure-insensitive behavior for high confinement (Yuan et al (2020)).…”

Section: Dependence Of the Strength On The Confinementsupporting

confidence: 85%

Morphometric description of strength and degradation in porous media

Alexandre¹,

Rattez²,

Veveakis³

2021

Preprint

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The influence of the microstructural geometry on the behavior of porous media is widely recognized, particularly in geomaterials, but also in biomaterials and engineered materials. Recent advances in imaging techniques, such as X-ray microcomputed tomography, and in modeling make it possible to capture the exact morphometry of the microstructure with high precision. However, most existing continuum theories only partially account for the morphometry. We propose here a unifying approach to link the strength of porous materials with the necessary and sufficient microstructural information, using Minkowski functionals, as per Hadwiger's theorem. A morphometric strength law is inferred from synthetic microstructures with a wide range of porosities and heterogeneities, through qualitative 2D phase-field simulations. Namely, the damage is modeled at the microstructural level by tracking the solid-pore interfaces under mechanical loading. The strength is found to be best described by an exponential function of the morphometers, thus generalizing early works on metals and ceramics. We then show that the predictiveness of this relationship extends to real porous media, including rocks and bones.

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Section: Dependence Of the Strength On The Confinementsupporting

confidence: 85%

Morphometric description of strength and degradation in porous media

Alexandre¹,

Rattez²,

Veveakis³

2021

Preprint

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“…Mechanical properties of the rocks that make up the geological section were taken in accordance with the laboratory test results [27,28]. Determination of the stress-strain state of rocks was based on the model of an ideal elastic-plastic medium, which, in the area of compressive stresses, was implemented in the variant of the parabolic Coulomb -Mohr criterion [29]:…”

mentioning

confidence: 99%

Mathematical modelling of displacement during the potash ores mining by longwall faces

Baryakh

Devyatkov

Denkevich³

2023

PMI

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In favourable mining conditions, in particular at the Starobinskoye potash deposit (Belarus), longwall mining systems are used. They cause a high human-induced load on the subsoil, including intense deformation of the ground surface. The presented investigations are aimed at studying the dynamics of the ground surface displacement during the longwall face advance. Mathematical modelling was carried out in an elastic-plastic formulation with numerical implementation by the finite element method. The condition for the roof rocks collapse was opening of the contact between the seams when its boundaries were reached by shear fractures or formation of the tensile stresses area at the outcrop. With the working front advance, an increase in subsidence is observed, followed by its stabilization to a value determined by the process parameters of mining operations and the physical and mechanical properties of collapsed rocks. In this case, each point of the ground surface experiences sign-alternating horizontal deformations: when the front approaches, it causes tension, and when it moves away, compression. The obtained results of mathematical modelling are in good agreement with the data of instrumental measurements of the ground surface displacements, which indicates the adequate description of the rock mass deformation during the slice excavation of sylvinite seams by longwall faces.

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