Authors: M. Kakavand, S. A. Naeini

Abstract:

Dynamic properties of soil in small strains, especially for geotechnical engineers, are important for describing the behavior of soil and estimation of the earth structure deformations and structures, especially significant structures. This paper presents the effect of density on the shear modulus and damping ratio of saturated clean sand at various isotropic confining pressures. For this purpose, the specimens were compared with two different relative densities, loose Dr = 30% and dense Dr = 70%. Dynamic parameters were attained from a series of consolidated undrained fixed – free type torsional resonant column tests in small strain. Sand No. 161 is selected for this paper. The experiments show that by increasing sand density and confining pressure, the shear modulus increases and the damping ratio decreases.

Keywords: Dynamic properties, shear modulus, damping ratio, clean sand, density, confining pressure, resonant column/torsional simple shear.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.3593244

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References:

[1] Iida, K., The Velocity of Elastic Waves in Sand. Bulletin of Earthquake Research Institute, 1963. 16: p. 131–145.
[2] Hardin, B.O. and F. Richart Jr, Elastic wave velocities in granular soils. Journal of Soil Mechanics & Foundations Div, 1963. 89(Proc. Paper 3407).
[3] Hardin, B.O. and W.L. Black, Sand stiffness under various triaxial stresses. Journal of Soil Mechanics & Foundations Div, 1966. 92(ASCE# 4712 Proceeding).
[4] Hardin, B.O., Dynamic versus static shear modulus for dry sand. Materials research and standards, 1965. 5(5): p. 232-235.
[5] Seed, H.B., Soil moduli and damping factors for dynamic response analysis. EERC, 1970.
[6] Hardin, B.O. and V.P. Drnevich, Shear modulus and damping in soils: design equations and curves. Journal of Soil Mechanics & Foundations Div, 1972. 98(sm7).
[7] Iwasaki, T. and F. Tatsuoka, Effects of grain size and grading on dynamic shear moduli of sands. Soils and foundations, 1977. 17(3): p. 19-35.
[8] Chung, R.M., F.Y. Yokel, and V. Drnevich, Evaluation of dynamic properties of sands by resonant column testing. Geotechnical Testing Journal, 1984. 7(2): p. 60-69.
[9] Menq, F.-Y. and K. Stokoe, Linear dynamic properties of sandy and gravelly soils from large-scale resonant tests. Deformation characteristics of geomaterials, 2003: p. 63-71.
[10] Payan, M., et al., Effect of particle shape and validity of Gmax models for sand: A critical review and a new expression. Computers and Geotechnics, 2016. 72: p. 28-41.
[11] SAxENA, S.K. and K.R. Reddy, Dynamic moduli and damping ratios for Monterey No. 0 sand by resonant column tests. Soils and Foundations, 1989. 29(2): p. 37-51.
[12] Senetakis, K., A. Anastasiadis, and K. Pitilakis, The small-strain shear modulus and damping ratio of quartz and volcanic sands. Geotechnical Testing Journal, 2012. 35(6): p. 964-980.
[13] Wichtmann, T. and T. Triantafyllidis, Influence of the grain-size distribution curve of quartz sand on the small strain shear modulus G max. Journal of geotechnical and geoenvironmental engineering, 2009. 135(10): p. 1404-1418.
[14] Payan, M., et al., Characterization of the small-strain dynamic behaviour of silty sands; contribution of silica non-plastic fines content. Soil Dynamics and Earthquake Engineering, 2017. 102: p. 232-240.
[15] Morsy, A.M., M.A. Salem, and H.H. Elmamlouk, Evaluation of dynamic properties of calcareous sands in Egypt at small and medium shear strain ranges. Soil Dynamics and Earthquake Engineering, 2019. 116: p. 692-708.
[16] Payan, M. and R.J. Chenari, Small strain shear modulus of anisotropically loaded sands. Soil Dynamics and Earthquake Engineering, 2019. 125: p. 105726.
[17] Sadeghzadegan, R., S.A. Naeini, and A. Mirzaii, Effect of clay content on the small and mid to large strain shear modulus of an unsaturated sand. European Journal of Environmental and Civil Engineering, 2018: p. 1-19.
[18] ASTM, ASTM D422-63: Standard Test Method for Particle-Size Analysis of Soils. 2007, ASTM International West Conshohocken^ ePA PA.
[19] ASTM, ASTM D854-14: Standard test methods for specific gravity of soil solid by water pycnommeter. 2002, ASTM International West Conshohocken.
[20] ASTM, ASTM D4254-00: Standard test methods for minimum index density and unit weight of soils and calculation of relative density. ASTM International.
[21] ASTM, ASTM D4253-00: Standard test methods for maximum index density and unit weight of soils using a vibratory table. 2006, ASTM International West Conshohocken.
[22] ASTM, ASTM D4015-15: Standard Test Methods for Modulus and Damping of Soils by Fixed-Base Resonant Column Devices. ASTM international.
[23] Ladd, R., Preparing test specimens using undercompaction. Geotechnical Testing Journal, 1978. 1(1): p. 16-23.