Browse > Article
http://dx.doi.org/10.12989/gae.2017.12.4.639

Analysis of the thresholds of granular mixtures using the discrete element method  

Jian, Gong (State Key Laboratory of Coastal and Offshore Engineering, Dalian University of Technology)
Jun, Liu (State Key Laboratory of Coastal and Offshore Engineering, Dalian University of Technology)
Publication Information
Geomechanics and Engineering / v.12, no.4, 2017 , pp. 639-655 More about this Journal
Abstract
The binary mixture consists of two types of granular media with different physical attributes and sizes, which can be characterized by the percentage of large granules by weight (P) and the particle size ratio (${\alpha}$). Researchers determine that two thresholds ($P_S$ and $P_L$) exist for the peak shear strength of binary mixtures, i.e., at $P{\leq}P_S$, the peak shear strength is controlled by the small granules; at $P{\leq}P_L$, the peak shear strength is controlled by the large granules; at $P_S{\leq}P{\leq}P_L$, the peak shear strength is governed by both the large and small granules. However, the thresholds of binary mixtures with different ${\alpha}$ values, and the explanation related to the inner details of binary mixtures to account for why these thresholds exist, require further confirmation. This paper considers the mechanical behavior of binary mixtures with DEM analysis. The thresholds of binary mixtures are found to be strongly related to their coordination numbers $Z_L$ for all values of ${\alpha}$, where $Z_L$ denotes the partial coordination number only between the large particles. The arrangement structure of the large particles is examined when P approaches the thresholds, and a similar arrangement structure of large particles is formed in both 2D and 3D particle systems.
Keywords
thresholds; granular mixtures; partial coordination number; porosity; direct shear test; DEM;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Biazzo, I., Caltagirone, F., Parisi, G. and Zamponi, F. (2009), "Theory of amorphous packings of binary mixtures of hard spheres", Phys. Rev. Lett., 102(19), 195701.   DOI
2 Cundall, P.A. and Strack, O.D.L. (1979), "A discrete numerical model for granular assemblies", Géotechnique, 29(1), 47-65.   DOI
3 Fragaszy, R., Su, J., Siddiqi, F. and Ho, C. (1992), "Modeling strength of sandy gravel", J. Geotech. Eng.-ASCE, 118(6), 920-935.   DOI
4 Garga, V.K. and Mdreira, C.J. (1985), "Compaction characteristics of river terrace gravel", J. Geotech. Eng.-ASCE, 111(8), 987-1007.   DOI
5 Gong, J. and Liu, J. (2015), "Analysis on the mechanical behaviors of soil-rock mixtures using discrete element method", Procedia Eng., 102, 1783-1792.   DOI
6 Hamidi, A., Azini, E. and Masoudi, B. (2012), "Impact of gradation on the shear strength-dilation behavior of well graded sand-gravel mixtures", Sci. Iran, 19(3), 393-402.   DOI
7 Hassanpour, A., Ding, Y. and Ghadiri, M. (2004), "Shear deformation of binary mixtures of dry particulate solids", Adv. Powder Technol., 15(6), 687-697.   DOI
8 Jamiolkowski, M., Kongsukprasert, L. and Lo Presti, D. (2004), "Characterization of gravelly geomaterials", Proceedings of the 5th International Geotechnical Conference, Bangkok, Thailand, November.
9 Khalili, A. (2009), "Mechanical response of highly gap-graded mixtures of waste rock and tailings (paste rock)", Ph.D. Dissertation; University of British Columbia, Vancouver, Canada.
10 Kuenza, K., Towhata, I., Orense, R.P. and Wassan, T.H. (2004), "Undrained torsional shear tests on gravelly soils", Landslides, 1(3), 185-194.   DOI
11 Lade, P.V., Liggio, C.D. and Yamamuro, J.A. (1998), "Effects of non-plastic fines on minimum and maximum void ratios of sand", Geotech. Test J., 21(4), 336-347.   DOI
12 Mcgeary, R.K. (1961), "Mechanical packing of spherical particles", J. Am. Ceram. Soc., 44(10), 513-522.   DOI
13 Mota, M., Teixeira, J.A., Bowen, W.R. and Yelshin, A. (2001), "Binary spherical particle mixed beds : porosity and permeability relationship measurement", Trans. Filt. Soc., 4(1), 101-106.
14 Ogarko, V. and Luding, S. (2012), "Equation of state and jamming density for equivalent bi- and polydisperse, smooth, hard sphere systems", J. Chem. Phys., 136(12), 124508.   DOI
15 Oger, L., Ippolito, I. and Vidales, A.M. (2007), "How disorder can diminish avalanche risks: effect of size distribution - Precursor of avalanches", Granul. Matter., 9(3-4), 267-278.   DOI
16 Pinson, D., Zou, R.P., Yu, A.B., Zulli, P. and McCarthy, M.J. (1998), "Coordination number of binary mixtures of spheres", J. Phys. D Appl. Phys., 31(4), 457-462.   DOI
17 Roux, J.N. (2000), "Geometric origin of mechanical properties of granular materials", Phys. Rev. E, 61(6), 6802-6836.   DOI
18 Saowapark, T., Sombatsompop, N. and Sirisinha, C. (2009), "Viscoelastic properties of fly ash-filled natural rubber compounds: Effect of fly ash loading", J. Appl. Polym. Sci., 112(4), 2552-2558.   DOI
19 Shelley, T.L. and Daniel, D.E. (1993), "Effect of gravel on hydraulic conductivity of compacted soil liners", J. Geotech. Eng.-ASCE, 119(1), 54-68.   DOI
20 Shin, H. and Santamarina, J.C. (2013), "Role of particle angularity on the mechanical behavior of granular mixtures", J. Geotech. Geoenviron., 139(2), 353-355.   DOI
21 Simoni, A. and Houlsby, G.T. (2006), "The direct shear strength and dilatancy of sand-gravel mixtures", Geotech. Geol. Eng., 3(24), 523-549.
22 Wang, Z., Ruiken, A., Jacobs, F. and Ziegler, M. (2014), "A new suggestion for determining 2D porosities in DEM studies", Geomech. Eng., Int. J., 7(6), 665-678.   DOI
23 Ueda, T., Matsushima, T. and Yamada, Y. (2011), "Effect of particle size ratio and volume fraction on shear strength of binary granular mixture", Granul. Matter., 13(6), 731-742.   DOI
24 Vallejo, L.E. (2001), "Interpretation of the limits in shear strength in binary granular mixtures", Can. Geotech. J., 38(5), 1097-1104.   DOI
25 Wang, J., Zhang, H., Deng, D. and Liu, M. (2013), "Effects of mudstone particle content on compaction behavior and particle crushing of a crushed sandstone-mudstone particle mixture", Eng. Geol., 167, 1-5.   DOI
26 Xu, W.J., Xu, Q. and Hu, R.L. (2011), "Study on the shear strength of soil-rock mixture by large scale direct shear test", Int. J. Rock Mech. Min., 48(8), 1235-1247.   DOI
27 Yerazunis, S., Bartoett, J.W. and Nissan, A.H. (1962), "Packing of binary mixtures of spheres and irregular particles", Nature, 195, 33-35.   DOI
28 Yu, A.B. and Standish, N. (1987), "Porosity calculations of multi-component mixtures of spherical particles", Powder Technol., 52(3), 233-241.   DOI
29 Zhang, L. and Thornton, C. (2007), "A numerical examination of the direct shear test", Geotechnique, 57(4), 343-354.   DOI
30 Zhang, Z.F., Ward, A.L. and Keller, J.M. (2011), "Determining the porosity and saturated hydraulic conductivity of binary mixtures", Vadose Zone J., 10(1), 313-321.   DOI