Flow deformation and cyclic resistance of saturated loose sand considering initial static shear effect

Sand elements in the natural or manmade field have often undergone initial static shear stresses before suffering cyclic loading. To explore the effect of static shear stress, a series of undrained cyclic triaxial tests were performed on dense and loose calcareous sand under different initial and cyclic shear stresses. The triaxial test results are used to describe the effect of static shear stress on the cyclic response of the calcareous sand with different relative density. Cyclic mobility, flow deformation, and residual deformation accumulation are the three main failure modes under varying static and cyclic shear stress levels. The cyclic resistance of dense sand is greater than that of loose sand, but the initial static stress has different effects on the cyclic resistance of the two kinds of sand. The dense sand owns a higher cyclic resistance with SSR increasing, while for the loose sand, 0.12 is the critical SSR corresponding to the lowest value of the cyclic resistance. The dense sand has more fast accumulation of dissipated energy, compared with loose sand. Additionally, an exponential relationship is established between static shear stress, relative density, and normalized energy density.

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Effect of Static Shear Stress on Cyclic Resistance of a Uniform Gravel

Geo-Congress 2020 ◽

10.1061/9780784482810.012 ◽

2020 ◽

Author(s):

Michelle R. Basham ◽

Adda Athanasopoulos-Zekkos

Keyword(s):

Shear Stress ◽

Cyclic Resistance ◽

Static Shear

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Confining stress and static shear effects in cyclic liquefaction

Canadian Geotechnical Journal ◽

10.1139/t00-120 ◽

2001 ◽

Vol 38 (3) ◽

pp. 580-591 ◽

Cited By ~ 76

Author(s):

Y P Vaid ◽

J D Stedman ◽

S Sivathayalan

Keyword(s):

Initial Density ◽

Confining Pressure ◽

Empirical Method ◽

Shear Stresses ◽

Confining Stress ◽

Liquefaction Resistance ◽

Sand Liquefaction ◽

Cyclic Resistance ◽

Cyclic Resistance Ratio ◽

Static Shear

Liquefaction resistance of a sand under cyclic loading is assessed and the effects of the levels of confining pressure and static shear on resistance to liquefaction are investigated. Site-specific values of the resistance under specified levels of confining and static shear stresses are measured in the laboratory. The measured values are compared with those which would be predicted by the application of empirical multiplying factors Kσ and Kα to the reference resistance at 100 kPa effective confining stress with no static shear. It is shown that Kσ and Kα are not independent, as assumed in current practice. The combined factor Kσ × Kα resulting from the empirical method is shown to underestimate the cyclic resistance ratio regardless of the initial density and confining and static shear levels. The degree of conservatism is most dramatic at looser density states.Key words: sand, liquefaction, static, cyclic, static shear, confining stress.

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Flow liquefaction potential of loose sand: stress path envelope and energy–based evaluation

Canadian Geotechnical Journal ◽

10.1139/cgj-2019-0366 ◽

2020 ◽

Author(s):

Kun Pan ◽

Zhongxuan Yang ◽

Yuanqiang Cai

Keyword(s):

Axial Strain ◽

Stress Path ◽

Dissipated Energy ◽

Loose Sand ◽

Liquefaction Potential ◽

Cyclic Shear ◽

Cyclic Resistance ◽

Potential Applicability ◽

Potential Evaluation ◽

Flow Liquefaction

Flow liquefaction, which is characterized by sudden collapse following the unstable behavior of saturated loose sand, may lead to the most catastrophic consequence of all liquefaction–related phenomena. This note presents a systematic experimental investigation into the flow liquefaction potential of sand under various initial and cyclic shear conditions. The cyclic flow liquefaction responses are compared to the monotonic shear results under an identical initial testing condition. It is found that the effective stress path of a monotonic test appears to envelop that of its corresponding cyclic test. The energy–based liquefaction potential evaluation indicates that the accumulative dissipated energy is uniquely correlated not only with the pore pressure and axial strain induced in sand, but also with the degraded stiffness during cyclic loading. Furthermore, the energy capacity for triggering the flow liquefaction appears to be intimately related to the cyclic resistance of sand; this signifies the potential applicability of energy–based liquefaction potential evaluation using strength data available in conventional analysis.

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