Macro-micro investigation of granular materials in torsional shear test

Bo Li; Lin Guo; Feng-shou Zhang

doi:10.1007/s11771-014-2262-3

Journal of Central South University ›› 2014, Vol. 21 ›› Issue (7) : 2950 -2961. DOI: 10.1007/s11771-014-2262-3

Article

Macro-micro investigation of granular materials in torsional shear test

Bo Li ¹^,²
, Lin Guo ¹
, Feng-shou Zhang ³^,^c

Author information +

History +

PDF

Abstract

A three-dimensional numerical torsion shear test is presented on hollow cylinder specimen which is performed on a spherical assemblage with fixed principal stress axes using the discrete element code PFC^3D. Stack wall technique boundary conditions are employed and optimized to reasonably capture the microstructure evolution. Parametric studies are conducted in terms of the ratio κ, normal and shear stiffness of particles, wall stiffness and friction coefficients. Afterwards, in comparison with physical test, numerical results for a fixed principal stress angle (α=45°) are presented. The results show that the numerical test could capture the macro-micro mechanical behavior of the spherical particle assembly. The evolution of the coordination number demonstrates that particles in shear banding undergo remarkable decrease. The effects of localization on specimens illustrate that global stress and strain recorded from a hollow cylinder apparatus could not represent the localized response. The shearing band initiation and evolution from porosity and shear rate are visualized by contour lines in different shear strains.

Keywords

hollow cylinder apparatus / numerical modeling / principal stress rotation / strain localization

Cite this article

Download citation ▾

Bo Li, Lin Guo, Feng-shou Zhang. Macro-micro investigation of granular materials in torsional shear test. Journal of Central South University, 2014, 21(7): 2950-2961 DOI:10.1007/s11771-014-2262-3

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	WangL B, FrostJ D, LaiJ S. Three-dimensional digital representation of granular material microstructure from X-ray tomography imaging [J]. Journal of Computing in Civil Engineering, ASCE, 2004, 18(1): 28-35

[2]	SaadaS A, LiangL, FigueroaJ L, CopeC T. The use of digital processing in monitoring shear band development [J]. Geotechnical Testing Journal, ASTM, 1996, 20(3): 324-339

[3]	CundallP A, StrackO D L. A discrete numerical model for granular assemblies [J]. Geotechnique, 1979, 29(1): 47-65

[4]	WangJ, GutierrezM. Discrete element simulations of the direct shear specimen scale effects [J]. Geotechnique, 2010, 60(5): 395-409

[5]	ThorntonC, ZhangL. Numerical simulations of the direct shear test [J]. Chem Eng Technol, 2003, 26(2): 153-156

[6]	NgT T. Fabric evolution of ellipsoidal arrays with different particle shapes [J]. J Eng Mech, 2001, 127(10): 994-999

[7]	YanW M. Fabric evolution in a numerical direct shear test [J]. Computer and Geotechnics, 2009, 36: 597-603

[8]	YimsiriS, SogaK. DEM analysis of soil fabric effects on behavior of sand [J]. Geotechnique, 2010, 60(6): 483-495

[9]	SaadaA S, BianchiniG F, LiangL. Crack, bifurcation and shear bands propagation in saturated clays [J]. Geotechnique, 1994, 44(1): 35-64

[10]	SaadaA S, LiangL, FigueroaJ L, CopeC T. Bifurcation and shear band propagation in sands [J]. Geotechnique, 1999, 49(3): 367-385

[11]	IwashitaK, OdaM. Rolling resistance at contacts in simulation of shear band development by DEM [J]. Journal of Engineering Mecahnics, ASCE, 1998, 124(3): 285-292

[12]	ThorntonC, ZhangL A. Numerical examination of shear banding and simple shear non-coaxial flow rules [J]. Philosophical Magazine, 2006, 86: 3425-3452

[13]	SaadaA S, TownsendF C. State of the art: laboratory strength testing of soils [J]. ASTM Special Publication, 1981, 740: 7-77

[14]	HightD W, GensA, SymesM J. The development of a new hollow cylinder apparatus for investigating the effects of principal rotation in soils [J]. Geotechnique, 1983, 33(4): 355-383

[15]	SymesM J, GensA, HightD H. Drained principal stress rotation in saturated sand [J]. Geotechnique, 1988, 38(1): 59-81

[16]	YangZ X, LiX S, YangJ. Undrained anisotropy and rotational shear in granular soil [J]. Geotechnique, 2007, 57(4): 371-384

[17]	TongZ, ZhangJ, YuY, ZhangG. Drained deformation behavior of anisotropic sands during cyclic rotation of principal stress axes [J]. Journal of Geotechnical and Geoenviromental Engineering, ASCE, 2010, 136(11): 1509-1518

[18]	WangY H, LeungS C. A particulate scale investigation of cemented sand behavior [J]. Canadian Geotechnical Journal, 2008, 45: 29-44

[19]	NiQ, PowrieW, ZhangX. Effect of particle properties on soil behavior: 3D numerical modeling of shearbox tests [J]. Numerical Methods in Geotechnical Engineering, ASCE, 200058-70

[20]	OdaM, KonishiJ. Microscopic deformation mechanism of granular material in simple shear [J]. Soils and Foundations, 1974, 14(4): 25-38

[21]	KuhnM R. Structured deformation in granular materials [J]. Mechanics of Materials, 1999, 31(6): 407-429

[22]	CorriveauD, SavageS B, OgerL. Internal friction angles: Characterisation using biaxial test simulations [J]. In IUTAM Symposium, 1997, 53: 313-324

[23]	ZhaoX, EvansT M. Discrete simulations of laboratory loading conditions [J]. International Journal of Geomechanics, ASCE, 2009, 9(4): 169-178

[24]	RoscoeK H. The influence of strains in soil mechanics [J]. 10th Rankine lecture, Geotechnique, 1970, 20(2): 129-170

[25]	VardoulakisI, GrafB. Calibration of constitutive models for granular materials using data from biaxial experiments [J]. Geotechnique, 1985, 35: 299-317

[26]	LI B, ZHANG F, GUTIERREZ M. A numerical examination of the hollow cylindrical torsional shear test using DEM [J]. Acta Geotechnica, DOI 10.1007/s11440-014-0329-9.

[27]	LuYReconstruction, characterization, modelling and visualizatioin of inherent and induced digital sand microstructure [D], 2010, Atalanta, Georgia Institute of Technology

[28]	ZhangL, ThorntonC. A numerical examination of the direct shear test [J]. Geotechnique, 2007, 57(4): 343-354

[29]	CoopM R, CuccovilloT. The measurement of local axial strains in triaxial test using LVDT. Geotechnique, 1997, 47(1): 167-171

[30]	BrendanC O, PatrickJ N. Local measurements of the polar deformation response in a hollow cylinder apparatus [J]. Geomechanics and Geoengineering, 2008, 3(4): 217-229

[31]	OdaM. Coordination number and its relation to shear strength of granular material [J]. Soils and Foundations, 1977, 17(2): 29-42

[32]	MuhlhausH B, VardoulakisI. The thickness of shear bands in granular materials [J]. Geotechnique, 1987, 37(3): 271-283

[33]	FinnoR J, HarrisW W, MooneyM A, ViggianiG. Shear bands in plain strain compression of loose sand [J]. Geotechnique, 1997, 47: 149-165

[34]	LadeP V, NamJ, HongW P. Shear banding and cross anisotropic behavior observed in laboratory sand tests with stress rotation [J]. Canadian Geotechnical Journal, 2008, 45: 74-84