Post-liquefaction reconsolidation of sand

Adamidis, Orestis; Madabhushi, Spg

doi:10.1098/rspa.2015.0745

Cited by 21 publications

(12 citation statements)

References 32 publications

(72 reference statements)

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“…Thus, the use of Eq. (3) is in contrast with the authors' initial argument that sand layers in free-field condition are not likely to experience a fully undrained condition and that partial drainage is likely to occur (i.e., Adamidis and Madabhushi 2016).…”

mentioning

confidence: 67%

Discussion of “Simplified Procedure for Prediction of Earthquake-Induced Settlements in Partially Saturated Soils” by Abdülhakim Zeybek and Santana Phani Gopal Madabhushi

Mousavi

Ghayoomi

McCartney

2021

J. Geotech. Geoenviron. Eng.

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mentioning

confidence: 67%

Discussion of “Simplified Procedure for Prediction of Earthquake-Induced Settlements in Partially Saturated Soils” by Abdülhakim Zeybek and Santana Phani Gopal Madabhushi

Mousavi

Ghayoomi

McCartney

2021

J. Geotech. Geoenviron. Eng.

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“…The soil properties outlined in Table 1 were used in these analyses. The variation of co-efficient of consolidation and permeability at very low effective stresses for the Hostun sand were adopted from Haigh et al [29] and Adamidis and Madabhushi [32].…”

Section: Finite Element Discretisationmentioning

confidence: 99%

Sustainable Measures for Protection of Structures Against Earthquake Induced Liquefaction

Madabhushi

García-Torres

2021

Indian Geotech J

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Soil 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.

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“…While the bulk of Terzaghi's theory was held valid, some changes were motivated by the highly non-linear behaviour of sand at very low . Indeed, a number of experimental studies show that, during re-consolidation, both hydraulic conductivity and 1D oedometer stiffness (= 1/ , oedometer compressibility) depend strongly on the current effective stress level and void ratio (Brennan and Madabhushi, 2011;Haigh et al, 2012;Adamidis and Madabhushi, 2016).…”

Section: Pore Pressure Dissipation During Re-consolidationmentioning

confidence: 99%

“…The empirical relationship proposed by Adamidis and Madabhushi (2016) was adopted for the hydraulic conductivity:…”

Section: Pore Pressure Dissipation During Re-consolidationmentioning

confidence: 99%

“…The above pore pressure dissipation model was further tested against the measurements recorded by Adamidis and Madabhushi (2016) during re-consolidation centrifuge tests on Hostun sand -experiment OA2-EQ2. Selected parameters for this case are given in Table 2 -set 2, most of which taken from published values.…”

Section: Appendix I Further Validation Of the Pore Pressure Dissipationmentioning

confidence: 99%

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CFD-Based Framework for Analysis of Soil–Pipeline Interaction in Reconsolidating Liquefied Sand

et al. 2020

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Submarine buried pipelines interact with shallow soil layers that are often loose and prone to fluidization/liquefaction. Such occurrence is possible consequence of pore pressure build-up induced by hydrodynamic loading, earthquakes and/or structural vibrations. When liquefaction is triggered in sand, the soil tends to behave as a viscous solid-fluid mixture of negligible shear strength, possibly 1 Pisanò et al., May 4, 2020 unable to constrain pipeline movements. Therefore, pipelines may experience excessive displacement, for instance in the form of vertical flotation or sinking. To date, there are no well-established methods to predict pipe displacement in the event of liquefaction. To fill such a gap, this work proposes a computational fluid dynamics (CFD) framework enriched with soil mechanics principles. It is shown that the interaction between pipe and liquefied sand can be successfully analysed via one-phase Bingham fluid modelling of the soil. Post-liquefaction enhancement of rheological properties, viscosity and yield stress, can also be accounted for by linking soil-pipe CFD simulations to separate analysis of pore pressure dissipation. The proposed approach is thoroughly validated against the results of small-scale pipe flotation and pipe dragging tests from the literature.

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Post-liquefaction reconsolidation of sand

Cited by 21 publications

References 32 publications

Discussion of “Simplified Procedure for Prediction of Earthquake-Induced Settlements in Partially Saturated Soils” by Abdülhakim Zeybek and Santana Phani Gopal Madabhushi

Discussion of “Simplified Procedure for Prediction of Earthquake-Induced Settlements in Partially Saturated Soils” by Abdülhakim Zeybek and Santana Phani Gopal Madabhushi

Sustainable Measures for Protection of Structures Against Earthquake Induced Liquefaction

CFD-Based Framework for Analysis of Soil–Pipeline Interaction in Reconsolidating Liquefied Sand

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