Liquefaction flow characteristics of saturated coral sand subjected to various patterns of cyclic loading

QIN You; YANG Zhengtao; WU Qi; ZHAO Kai; CHEN Guoxing

doi:10.11779/CJGE20220798

Volume 45 Issue 8

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Chinese Journal of Geotechnical Engineering > 2023 > 45(8): 1625-1634. > DOI: 10.11779/CJGE20220798

QIN You, YANG Zhengtao, WU Qi, ZHAO Kai, CHEN Guoxing. Liquefaction flow characteristics of saturated coral sand subjected to various patterns of cyclic loading[J]. Chinese Journal of Geotechnical Engineering, 2023, 45(8): 1625-1634. DOI: 10.11779/CJGE20220798

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Liquefaction flow characteristics of saturated coral sand subjected to various patterns of cyclic loading

QIN You^1,,
YANG Zhengtao¹,
WU Qi¹,
ZHAO Kai¹,
CHEN Guoxing^{1, 2, ,}

1.
Institute of Geotechnical Engineering, Nanjing Tech University, Nanjing 211816, China
2.
Civil Engineering and Earthquake Disaster Prevention Center of Jiangsu Province, Nanjing 211816, China

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Received Date: June 23, 2022
Available Online: February 26, 2023

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Abstract

The accumulation of the excess pore water pressure of saturated sand under various cyclic loadings is the cause of soil liquefaction, and it is a relatively new research idea to treat the liquefiable sand as a fluid. A comprehensive experimental investigation of the liquefaction flow characteristics is performed for the saturated coral sand subjected to the jump of 90° and the continuous rotation of the principal stresses with cyclic loading frequency (f) at isotropic consolidations. The test results show that the relationship between the normalized apparent viscosity (η/η₀) and the excess pore water pressure ratio (r_u) is significantly affected by the cyclic stress paths, the degradation of η/η₀ with r_u is a progressive process, and a positive exponential correlation exists between the average flow coefficient ( $\bar \kappa$ ) and r_u. The correlations between η/η₀ and r_u and between $\bar \kappa$ and r_u seem to be independent on the cyclic stress ratio (CSR = 0.25~0.40) and f (= 0.1~1 Hz). Another significant finding is that the apparent viscosity gradient and the average flow coefficient gradient both increase first and then decrease with the increase of r_u regardless of the jump of 90° and the continuous rotation of the principal stresses, and r_u approximately equal to 0.9 at the reversal point can be regarded as the threshold value of the excess pore water pressure ratio (r_uth) at the phase transformation state from the solid state to the liquid one, by denoting the corresponding $\bar \kappa$ as ${\bar \kappa _{{\text{th}}}}$ . The data points of $\bar \kappa /{\bar \kappa _{{\text{th}}}}$ -r_u for all testing conditions are distributed in a narrow band, and a virtually positive exponential relationship exists between $\bar \kappa /{\bar \kappa _{{\text{th}}}}$ and r_u.

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