Please use this identifier to cite or link to this item: http://ir.futminna.edu.ng:8080/jspui/handle/123456789/12581
Title: An Experimental-DEM Hybrid Approach for Characterizing Micromechanical Strength of Ughelli sandstone
Authors: Olugbenga, A. G.
Antony, S. J.
Nasir, A.
Garba, M.U.
Yahya, M. D.
Keywords: sandstone, simulation, tri-axial stress, cracknumber, macro-fracture
Issue Date: 9-Jul-2021
Publisher: Springer
Citation: 10 Olugbenga, A.G., S. J. Antony, A. Nasir, Garba, M. U. and Yahya, M.D. ‘An Experimental-DEM Hybrid Approach for Characterizing Micromechanical Strength of Ughelli sandstone. World Congress on Engineering (WCE) 5th -9th July 2021. paper number: ICME_21 London, UK http://www.iaeng.org/publication/WCE2021/ http://www.iaeng.org/publication/WCE2021/WCE2021_pp235-240.pdf
Series/Report no.: ICME_21 London;ICME_21
Abstract: Landslide has occurred in Nigeria recently, this has necessitated the simulation of crack number associated with tensile failures in sandstone subjected to tri-axial compressions. The aim is to relate the crack number to microscopic deformation which is the extent of isotropic and deviatoric components of the simulated seismic crack number to the microscopic failure mechanisms. Within the rock matrix, the cataclastic collapse occurs as the granular arrangement interferes with the applied forces which initiate a strong spatial anisotropic stress field depending on the level of applied force. The onset of the micro-cracking initiates the occurrence of the rock failure. The crack number was recorded simultaneously as the grain-to grain contacts breaks the montmorillonite mineral bond between the quartz grains. Experimental data were plotted as the contact strength reduces by tri-axial stresses induced on the rock, so that within the invisible cracks, a significant fraction of isotropic percentage in all directions were captured. The stress induced on the sample by axial and radial compression affect the waveforms and the recorded crack number are simultaneous. This micro-crack numbering provided microscopic deterioration between 5MPa to 25MPa, at this stress level no visible fracture occurring in the macroscopic feature was seen. This was achieved by representing the physical sandstone grain with an assembly of clump particle during procedural simulation of the sandstone. Thus, the interactions between clumps were governed by the defined micro-properties of spheres making the clumps. The strain in the sandstone was represented by a stiffness ratio of 1 which is in agreement with experimentally determined stiffness ratio obtained from the natural sandstone.
Description: Regardless of geometry in the Ughelli water boreholes, mechanical stress in the vicinity of the hole display complex deformation mechanisms because of the complex stress field. Core samples of natural rock were obtained from water boreholes. By using the same dimensions of the natural core sample, a mathematical sample was simulated. A top pattern was run for the load applications which induced strain into the rock. This causes the clumped assembly of particles to form a spatial and dependent anisotropic strain distribution in the rock matrix initiating the micro-cracks exhibited as tensile before the shear failures. Every crack between particle-to-particle contacts was numbered for spatio-temporary evolution of acoustic until visible crack was noticed. The cracking event were related to macroscopic axial-stress. The plots of confined stress were obtained as sigma 1, sigma 2 and sigma 3 to study the behaviour of the sandstone. Full profile of microcracks were segmented to indicate damage mechanisms similar to the seismic moment tensors which proved to be a useful tool for quantitative strength characterization of rocks
URI: http://www.iaeng.org/publication/WCE2021/WCE2021_pp235-240.pdf
http://repository.futminna.edu.ng:8080/jspui/handle/123456789/12581
Appears in Collections:Chemical Engineering

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