3D DEM simulations of basic geotechnical tests with early detection of shear localization

Aleksander Grabowski; Michał Nitka

doi:10.2478/sgem-2020-0010

Abstract

This paper deals with elementary geotechnical tests: triaxial and direct shear of cohesionless sand using the discrete element method (DEM). The capabilities of the numerical DEM code are shown, with a special focus on the early phenomena appearance in localization zones. The numerical tests were performed in 3D conditions with spherical grains. Contact moments law was introduced due to simulate not perfectly round sand grains. The influence of different physical parameters was studied, e.g. initial density or confining pressure. The sieve curve corresponded to the Karlsruhe sand [1]; however, in some tests, it was linearly scaled. Special attention was laid on the behaviour of the sand grains inside localization, e.g. rotation, porosity, fluctuations, etc. and forces redistribution. Emphasis was given on the pre-failure regime and early localization predictors.

References

Wu W., 1992, Hypoplastizität als mathematisches Modell zum mechanischen Verhalten granularer Stoffe, Heft 129, Institute for Soil- and Rock-Mechanics, University of Karlsruhe.
Search in Google Scholar Back to article
de Borst R., Műhlhaus H.B., 1992, Gradient dependent plasticity: formulation and algorithmic aspects, Int. J. Numer. Methods Eng. 35, 521–539.
Search in Google Scholar Back to article
Tejchman J., Wu W., 1993, Numerical study on shear band patterning in a Cosserat continuum, Acta Mech. 99, 61–74.
Search in Google Scholar Back to article
Brinkgreve R., 1994, Geomaterial models and numerical analysis of softening, Dissertation, Delft University, 1–153.
Search in Google Scholar Back to article
Tejchman J., Herle I., Wehr J., 1999, FE-studies on the influence of initial density, pressure level and mean grain diameter on shear localisation, Int. J. Numer. Anal. Methods Geomech 23(15), 2045–2074.
Search in Google Scholar Back to article
Tejchman J., 2004, Influence of a characteristic length on shear zone formation in hypoplasticity with different enhancements, Comput. Geotech. 31(8), 595–611.
Search in Google Scholar Back to article
Tejchman J., Wu W., 2009, Non-coaxiality and stress-dilatancy rule in granular materials: FE investigation within micro-polar hypoplasticity, Int. J. Numer. Anal. Methods Geomech 33(1), 117–142.
Search in Google Scholar Back to article
Tejchman J., Górski J., 2010, FE study of patterns of shear zones in granular bodies during plane strain compression, Acta Geotechnica 5(2), 95–112.
Search in Google Scholar Back to article
Regueiro R.A., Borja R.I., 2001, Plane strain finite element analysis of pressure sensitive plasticity with strong discontinuity, Int. J. Solids Struct. 38(21), 3647–3672.
Search in Google Scholar Back to article
Bobinski J., Tejchman J., 2014, Simulations of shear zones and cracks in engineering materials using eXtended Finite Element Method, I. J. Num. Anal. Meth. Geom., 1–6.
Search in Google Scholar Back to article
Oda M., Kazama H., 1998, Microstructure of shear bands and its relation to the mechanisms of dilatancy and failure of dense granular soils, Geotechnique 48, 465–481.
Search in Google Scholar Back to article
Ord A., Hobbs B., Regenauer-Lieb K., 2007, Shear band emergence in granular materials- a numerical study, Int. J. Numer. Anal. Methods Geomech. 31, 373–393.
Search in Google Scholar Back to article
Pena A.A., Garcia-Rojo R., Herrmann H.J., 2007, Influence of particle shape on sheared dense granular media, Granular Matter 3(4), 279–292.
Search in Google Scholar Back to article
Bi Z., Sun Q., Jin F., Zhang M., 2011, Numerical study on energy transformation in granular matter under biaxial compression, Granular Matter 13, 503–510.
Search in Google Scholar Back to article
Pardoen B., Collin F., 2017, Modelling the influence of strain localisation and viscosity on the behaviour of underground drifts drilled in claystone, Computers and Geotechnics 85,351–367.
Search in Google Scholar Back to article
Conte E., Donato A., Troncone A., 2013, Progressive failure analysis of shallow foundations on soils with strain-softening behaviour, Computers and Geotechnics 54, 117–124.
Search in Google Scholar Back to article
Kozicki J., Niedostatkiewicz M., Tejchman J., Mühlhaus H.-B., 2013, Discrete modelling results of a direct shear test for granular materials versus FE results, Granular Matter 15(5), 607–627.
Search in Google Scholar Back to article
Zhang N., Evans T.M., 2018, Three dimensional discrete element method simulations of interface shear, Soils and Foundations 58(4), 941–956.
Search in Google Scholar Back to article
Xue-Ying J., Wan-Huan Z., Yangmin L., 2017, Interface direct shearing behavior between soil and saw-tooth surfaces by DEM simulation, Procedia Engineering 175, 36–42.
Search in Google Scholar Back to article
Cui L., O’Sullivan C., 2006, Exploring the macro- and micro-scale response of an idealised granular material in the direct shear apparatus, Géotechnique 56.
Search in Google Scholar Back to article
Salazar A., Sáez E., Pardo G., 2015, Modeling the direct shear test of a coarse sand using the 3D Discrete Element Method with a rolling friction model, Computers and Geotechnics 67, 83–93.
Search in Google Scholar Back to article
Bernhardt M. L., Biscontin G., O’Sullivan C., 2016, Experimental validation study of 3D direct simple shear DEM simulations, Soils and Foundations 56, 336–347.
Search in Google Scholar Back to article
Rojek J., 2007, Discrete element modelling of rock cutting, Computer Methods in Materials Science 7(2), 224–230.
Search in Google Scholar Back to article
Nitka M., Combe G., Dascalu C., Desrues J., 2011, Two-scale modeling of granular materials: a DEM-FEM approach, Granular Matter 13, 277–281.
Search in Google Scholar Back to article
Utter B., Behringer R.P., 2004, Self-diffusion in dense granular shear flows, Phys. Rev. E. 69(3), 031308-1–031308-12.
Search in Google Scholar Back to article
Abedi S., Rechenmacher A.L., Orlando A.D., 2012, Vortex formation and dissolution in sheared sands. Granular Matter 14, 695–705.
Search in Google Scholar Back to article
Richefeu V., Combe G., Viggiani G., 2012, An experimental assessment of displacement fluctuations in a 2D granular material subjected to shear, Geotechnique Letters 2, 113–118.
Search in Google Scholar Back to article
Radjai F., Roux S., 2002, Turbulent-like fluctuation in quasi-static flow of granular media. Phys. Rev. Lett. 89, 064302.
Search in Google Scholar Back to article
Williams J.R., Rege N., 1997, Coherent vortex structures in deforming granular materials. Mechanics of Cohesive-frictional Materials 2, 223–236.
Search in Google Scholar Back to article
Kuhn M.R., 1999 Structured deformation in granular materials, Mechanics of Materials 31, 407–442.
Search in Google Scholar Back to article
Alonso-Marroquin F., Vardoulakis I., Herrmann H., Weatherley D., Mora P., 2006, Effect of rolling on dissipation in fault gouges, Physical Review E., 74 031306.
Search in Google Scholar Back to article
Tordesillas A., Muthuswamy M., Walsh S.D.C., 2008, Mesoscale measures of nonaffine deformation in dense granular assemblies, Journal of Engineering Mechanics 134(12), 1095–1113.
Search in Google Scholar Back to article
Liu X., Papon A., Mühlhaus H.B., 2012, Numerical study of structural evolution in shear band, Philosophical Magazine 92(28–30), 3501–3519.
Search in Google Scholar Back to article
Peters J.F., Walizer L.E., 2013, Patterned nonaffine motion in granular media, Journal of Engineering Mechanics 139(10), 1479–1490.
Search in Google Scholar Back to article
Ahuja R. K., Magnanti T. L., Orlin J. B., 1993, Network flows : theory, algorithms, and applications, Englewood Cliffs, N.J. Prentice Hall.
Search in Google Scholar Back to article
Tordesillas, A., Kahagalage, S., Ras, C., Nitka, M., Tejchman, J., 2018, Interdependent evolution of robustness, force transmission and damage in a heterogeneous quasi-brittle granular material: from suppressed to cascading failure, arXiv preprint arXiv:1809.01491.
Search in Google Scholar Back to article
Thornton C., Yin K. K., Adams M. J., 1996, Numerical simulation of the impact fracture and fragmentation of agglomerates, J. Phys., 29, 424–435.
Search in Google Scholar Back to article
Herrmann H. J., Luding S., 1998, Modeling granular media on the computer, Continuum Mech. Therm. 4 (10), 189–231.
Search in Google Scholar Back to article
Jiang M. J., Yu H.-S., Harris D., 2005, A novel discrete model for granular material incorporating rolling resistance, Computers and Geotechnics 32, 340–357.
Search in Google Scholar Back to article
Kruyt N. P., Rothenburg L., 2006, Shear strength, dilatancy, energy and dissipation in quasi-static deformation of granular materials, JSTAT/2006/P07021.
Search in Google Scholar Back to article
Zhu H. P., Zhou Z. Y., Yang R. Y., Yu A. B., 2007,Discrete particle simulation of particulate systems: Theoretical developments, Chem. Eng. Sci. 62, 3378–3396.
Search in Google Scholar Back to article
Ketterhagen W. R., Amende M. T., Hancock B. C., 2008, Process modeling in the pharmaceutical industry using the discrete element method, Pharmaceutical Research and Development, DOI 10.1002/jps.21466.
Open DOI Search in Google Scholar Back to article
Nitka M., Tejchman J., Kozicki J., Leśniewska D., 2015, DEM analysis of micro-structural events within granular shear zones under passive earth pressure conditions, Granular Matter 3, 325–343.
Search in Google Scholar Back to article
Cundall P. A., Hart R., 1992, Numerical modeling of discontinua, J. Eng. Comp. 9, 101–113.
Search in Google Scholar Back to article
Danesh A., Asghar Mirghasemi A., Palassi M., 2020, Evaluation of particle shape on direct shear mechanical behavior of ballast assembly using discrete element method (DEM), Transportation Geotechnics 23.
Search in Google Scholar Back to article
Szarf K., Combe G.,Villard P., 2009, Influence of the grains shape on the mechanical behavior of granular materials, AIP Conference Proceedings 1145(1), 357–360
Search in Google Scholar Back to article
Zhao S., Zhao J., 2019, A poly-superellipsoid-based approach on particle morphology for DEM modeling of granular media, Int J Numer Anal Methods Geomech, 1–13.
Search in Google Scholar Back to article
Kozicki J., Donze, F.V., 2008, A new open-source software developed for numerical simulations using discrete modelling methods, Computer Methods in Applied Mechanics and Engineering 197, 4429–4443.
Search in Google Scholar Back to article
Šmilauer V., Chareyre B., 2011, Yade DEM Formulation, Manual.
Search in Google Scholar Back to article
Zhao S., Evans T.M., Zhou X., 2018, Effects of curvature-related DEM contact model on the macro- and micro-mechanical behaviours of granular soils, Géotechnique 68 (12), 1085–1098.
Search in Google Scholar Back to article
Zhao S., Evans T.M., Zhou X., 2018, Shear-induced anisotropy of granular materials with rolling resistance and particle shape effects, International Journal of Solids and Structures 150 (1), 268–281.
Search in Google Scholar Back to article
Zhao, S., Evans, T. M., Zhou, X., 2018b., Three-dimensional voronoi analysis of monodisperse ellipsoids during triaxial shear, Powder Technology 323, 323–336.
Search in Google Scholar Back to article
Cundall P.A., Strack, O.D.L., 1979, A discrete numerical model for granular assemblies, Geotechnique 29, 47–65.
Search in Google Scholar Back to article
Widuliński L, Kozicki J, Tejchman J., 2009, Numerical simulations of triaxial test with sand using DEM, Archives of Hydro-Engineering and Environmental Mechanics 56, 3–26.
Search in Google Scholar Back to article
Skarżyński Ł., Kozicki J., Tejchman J., 2013, Application of DIC technique to concrete - study on objectivity of measured surface displacements, Experimental Mechanics, 53(9), 1545–1559.
Search in Google Scholar Back to article
Leśniewska D., Nitka M., Tejchman J., Pietrzak M., 2020, Contact force network evolution in active earth pressure state of granular materials: photo-elastic tests and DEM, Granular Matter, 22–71.
Search in Google Scholar Back to article

3D DEM simulations of basic geotechnical tests with early detection of shear localization

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