Changes in sand mesostructure under repeated seismic liquefaction events during centrifuge tests

This paper presents a series of centrifuge tests studying the performance of colloidal silica grouted soil layers during permanent lateral ground deformations due to earthquake induced lateral spreading. Two centrifuge tests were conducted to study liquefaction resistance of liquefiable soil deposits stabilized with colloidal silica, and then the results were compared with the tests conducted on similar soil deposits without any soil remediation. The testing results on remediated soils showed excellent resistance against the liquefaction and associated lateral and vertical ground deformations.

Download Full-text

Development of Experimental P-Y Curves from Centrifuge Tests for Piles Subjected to Static Loading and Liquefaction-Induced Lateral Spreading

DFI Journal The Journal of the Deep Foundations Institute ◽

10.37308/dfijnl.20191120.212 ◽

2020 ◽

Vol 14 (1) ◽

Author(s):

Milad Souri

Keyword(s):

Static Loading ◽

Pore Water Pressure ◽

Water Pressure ◽

Pressure Ratio ◽

Lateral Spreading ◽

American Petroleum Institute ◽

Unique Contribution ◽

Pile Groups ◽

Centrifuge Tests ◽

Centrifuge Models

The results of five centrifuge models were used to evaluate the response of pile-supported wharves subjected to inertial and liquefaction-induced lateral spreading loads. The centrifuge models contained pile groups that were embedded in rockfill dikes over layers of loose to dense sand and were shaken by a series of ground motions. The p-y curves were back-calculated for both dynamic and static loading from centrifuge data and were compared against commonly used American Petroleum Institute p-y relationships. It was found that liquefaction in loose sand resulted in a significant reduction in ultimate soil resistance. It was also found that incorporating p-multipliers that are proportional to the pore water pressure ratio in granular materials is adequate for estimating pile demands in pseudo-static analysis. The unique contribution of this study is that the piles in these tests were subjected to combined effects of inertial loads from the superstructure and kinematic loads from liquefaction-induced lateral spreading.

Download Full-text

Effect of boundary friction on revere fault rupture propagation in centrifuge tests

Soil Dynamics and Earthquake Engineering ◽

10.1016/j.soildyn.2021.106811 ◽

2021 ◽

Vol 147 ◽

pp. 106811

Author(s):

Chaofan Yao ◽

Jiro Takemura ◽

Gaoyu Ma ◽

Cong Dai ◽

Zheli An

Keyword(s):

Boundary Friction ◽

Rupture Propagation ◽

Fault Rupture ◽

Centrifuge Tests ◽

Fault Rupture Propagation

Download Full-text

Sustainable Measures for Protection of Structures Against Earthquake Induced Liquefaction

Indian Geotechnical Journal ◽

10.1007/s40098-021-00535-6 ◽

2021 ◽

Author(s):

Gopal S. P. Madabhushi ◽

Samy Garcia-Torres

Keyword(s):

Soil Liquefaction ◽

Excess Pore Pressure ◽

Economic Losses ◽

Element Analysis ◽

Centrifuge Testing ◽

Centrifuge Tests ◽

Liquefiable Soil ◽

Recent Earthquakes ◽

Excess Pore Pressures ◽

Excess Pore

AbstractSoil liquefaction can cause excessive damage to structures as witnessed in many recent earthquakes. The damage to small/medium-sized buildings can lead to excessive death toll and economic losses due to the sheer number of such buildings. Economic and sustainable methods to mitigate liquefaction damage to such buildings are therefore required. In this paper, the use of rubble brick as a material to construct earthquake drains is proposed. The efficacy of these drains to mitigate liquefaction effects was investigated, for the first time to include the effects of the foundations of a structure by using dynamic centrifuge testing. It will be shown that performance of the foundation in terms of its settlement was improved by the rubble brick drains by directly comparing them to the foundation on unimproved, liquefiable ground. The dynamic response in terms of horizontal accelerations and rotations will be compared. The dynamic centrifuge tests also yielded valuable information with regard to the excess pore pressure variation below the foundations both spatially and temporally. Differences of excess pore pressures between the improved and unimproved ground will be compared. Finally, a simplified 3D finite element analysis will be introduced that will be shown to satisfactorily capture the settlement characteristics of the foundation located on liquefiable soil with earthquake drains.

Download Full-text

CHARACTERIZATION OF LIQUEFACTION RESISTANCE OF SAND: EFFECT OF INITIAL FABRIC

Journal of Earthquake and Tsunami ◽

10.1142/s1793431114500018 ◽

2014 ◽

Vol 08 (01) ◽

pp. 1450001 ◽

Cited By ~ 1

Author(s):

BO LI ◽

XIANGWU ZENG ◽

HAO YU

Keyword(s):

Depositional Environment ◽

Design Method ◽

Free Field ◽

Recent Experience ◽

Permeability Test ◽

Fabric Anisotropy ◽

Liquefaction Resistance ◽

Liquefaction Potential ◽

Centrifuge Tests

The micro-fabric of deposition reflects the imprints of its geologic and stress history, its depositional environment, and its weathering history. Recent experience shows that the fabric anisotropy does influence the static and dynamic behavior of granular materials. In this study, a series of centrifuge tests are conducted to investigate the effects of fabric anisotropy on the dynamic response in the free field. The results show the acceleration, pore pressure, and residual settlement is significantly affected by the fabric anisotropy of the ground, which shows the liquefaction resistance of the ground. Meanwhile, the response of acceleration is analyzed in frequency domain, which shows that the model prepared by 90° absorbs more energy than that of 0°. To verify the effects induced by the initial fabric, permeability test are conducted and related to the liquefaction potential. The results indicate the fabric anisotropy should be incorporated into the design method.

Download Full-text

Static Pushover Analyses of Pile Groups in Liquefied and Laterally Spreading Ground in Centrifuge Tests

Journal of Geotechnical and Geoenvironmental Engineering ◽

10.1061/(asce)1090-0241(2007)133:9(1055) ◽

2007 ◽

Vol 133 (9) ◽

pp. 1055-1066 ◽

Cited By ~ 50

Author(s):

Scott J. Brandenberg ◽

Ross W. Boulanger ◽

Bruce L. Kutter ◽

Dongdong Chang

Keyword(s):

Pile Groups ◽

Centrifuge Tests

Download Full-text

Advanced Approaches for Coupled Deformation-Seepage-Analyses of Suction Caisson Installation

Volume 9: Offshore Geotechnics; Torgeir Moan Honoring Symposium ◽

10.1115/omae2017-61378 ◽

2017 ◽

Author(s):

Marc Stapelfeldt ◽

Britta Bienen ◽

Jürgen Grabe

Keyword(s):

Deformation Analysis ◽

Numerical Techniques ◽

Suction Caisson ◽

Large Deformation Analysis ◽

Centrifuge Tests ◽

Calculation Results ◽

Modelling Techniques ◽

Explicit Solver ◽

Excess Pore Pressures ◽

Numerical Approaches

In this paper the installation procedure of suction caissons is investigated by means of coupled seepage large deformation analysis performed with finite element methods. The modelling techniques employed to enable simulations of the penetration of a caisson into the soil under offshore conditions, i. e. several tens of meters below the water level. The numerical model includes a u-p-formulation, which is used to calculate the excess pore pressures and effective stresses from the total stresses. The Coupled-Eulerian-Lagrangian (CEL) approach available in conjunction with the Abaqus/Explicit solver is used. The calculation results are compared to centrifuge tests that were carried out recently at the Centre for Offshore Foundation Systems (COFS). This sheds light on the potential and the limitations of the presented numerical techniques. This paper concludes with a brief discussion of alternative numerical approaches that could be capable of the simulation of caisson installation.

Download Full-text

Influence of Pile Diameter and Aspect Ratio on the Lateral Response of Monopiles in Sand with Different Relative Densties

Journal of Marine Science and Engineering ◽

10.3390/jmse9060618 ◽

2021 ◽

Vol 9 (6) ◽

pp. 618

Author(s):

Huan Wang ◽

Lizhong Wang ◽

Yi Hong ◽

Amin Askarinejad ◽

Ben He ◽

...

Keyword(s):

Aspect Ratio ◽

Large Diameter ◽

Pressure Coefficient ◽

Offshore Wind ◽

Fe Model ◽

Soil Pressure ◽

Pile Diameter ◽

Centrifuge Tests ◽

Aspect Ratios ◽

Wide Range

The large-diameter monopiles are the most preferred foundation used in offshore wind farms. However, the influence of pile diameter and aspect ratio on the lateral bearing behavior of monopiles in sand with different relative densities has not been systematically studied. This study presents a series of well-calibrated finite-element (FE) analyses using an advanced state dependent constitutive model. The FE model was first validated against the centrifuge tests on the large-diameter monopiles. Parametric studies were performed on rigid piles with different diameters (D = 4–10 m) and aspect ratios (L/D = 3–7.5) under a wide range of loading heights (e = 5–100 m) in sands with different relative densities (Dr = 40%, 65%, 80%). The API and PISA p-y models were systematically compared and evaluated against the FE simulation results. The numerical results revealed a rigid rotation failure mechanism of the rigid pile, which is independent of pile diameter and aspect ratio. The computed soil pressure coefficient (K = p/Dσ′v) of different diameter piles at same rotation is a function of z/L (z is depth) rather than z/D. The force–moment diagrams at different deflections were quantified in sands of different relative density. Based on the observed pile–soil interaction mechanism, a simple design model was proposed to calculate the combined capacity of rigid piles.

Download Full-text

Seismic response and failure mechanism of underground frame structures based on dynamic centrifuge tests

Earthquake Engineering & Structural Dynamics ◽

10.1002/eqe.3434 ◽

2021 ◽

Author(s):

Chengshun Xu ◽

Zihong Zhang ◽

Yang Li ◽

Xiuli Du

Keyword(s):

Seismic Response ◽

Failure Mechanism ◽

Frame Structures ◽

Centrifuge Tests

Download Full-text

Centrifuge study of seismic response of soil-nailed walls supporting a footing on the ground surface

Géotechnique ◽

10.1680/jgeot.21.00157 ◽

2021 ◽

pp. 1-41

Author(s):

Mohammad Hassan Baziar ◽

Alireza Ghadamgahi ◽

Andrew John Brennan

Keyword(s):

Ground Surface ◽

Soil Surface ◽

Seismic Stability ◽

Soil Nails ◽

Model Soil ◽

Centrifuge Tests ◽

Axial Tensile ◽

Tensile Forces ◽

Surcharge Load ◽

Seismic Loadings

Seismic design of soil-nailed walls requires demonstrations of tolerable ranges of wall movements, especially when a surcharge load exists near the wall. In this study, the effect of surcharge location on seismically induced wall movements was investigated using four centrifuge tests. The axial tensile forces, developed along the soil nails during the seismic loadings, were also measured during the tests. At 50g centrifugal acceleration, model tests represented a 12-m-high prototype wall reinforced with five rows of soil nails. To apply a surcharge stress of 30 kPa at the specified location relative to the wall for each model test, a rigid footing was placed on the soil surface. The model soil-nailed walls were subjected to three successive earthquake motions. Surprisingly, it was found that the model wall with the footing located behind the soil-nailed region experienced the largest seismic movements, even more than when the footing was directly behind the wall. Further, the tests showed that the lower soil nails played a key role in the wall stability during earthquake shaking, acting as a pivot for the pre-collapse cases tested, whereas the upper soil nails needed to be sufficiently extended to properly contribute to the seismic stability of the wall.

Download Full-text