Theoretical breakage mechanics and experimental assessment of stresses surrounding piles penetrating into dense silica sand

Zhang, C.; Yang, Z. X.; Nguyen, Giang D.; Jardine, Richard J.; Einav, Itai

doi:10.1680/geolett.13.00075

Cited by 50 publications

(13 citation statements)

References 19 publications

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“…It remains highly challenging to undertake analyses of installation in sand that explore the generated in-situ stress fields quantitatively. However, Yang et al (2014) and Zhang et al (2014) show that an arching stress field can be expected to develop in sands around even monotonically penetrating piles. The SS and GS micro-pile experiments confirm postulate that radial stress redistribution does not contribute significantly to micro-pile ageing.…”

Section: Radial Stress Redistributionmentioning

confidence: 99%

Field experiments at three sites to investigate the effects of age on steel piles driven in sand

et al. 2020

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This paper investigates the influences that steel type, in-situ soil properties, water table depth, pile diameter, roughness and driving procedures have on the ageing behaviour of piles driven in sand. Tension tests have been performed on fifty-one, 48 to 60mm, outside diameter open-ended steel micro-piles driven at well-established research sites at Larvik in Norway, Dunkirk in France and Blessington in Ireland to better understand the processes that control axial capacity set-up trends in the field. Mild steel, stainless and galvanised steel micropiles were driven and left to age undisturbed for periods of between 2 hours and 696 days before being subjected to first-time axial tension load tests. In addition to reporting and interpreting these experiments, further investigations of the sites' geotechnical profiles are reported, including new piezocone and seismic cone penetration soundings as well as laboratory tests. Integration with earlier ageing studies at the same sites with larger (340 to 508mm outside diameter) open-ended steel piles driven to 7 to 20m embedment's and experiments that varied the piles' initial surface roughness shows that corrosion, pile-scale, roughness, the bonding of soil particles and the driving process can all be highly significant. New insights are gained into the mechanisms that control the axial capacity of piles driven in sand.

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Section: Radial Stress Redistributionmentioning

confidence: 99%

Field experiments at three sites to investigate the effects of age on steel piles driven in sand

et al. 2020

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“…The stress and strain paths developed around the pile tip are most relevant to the pile-end bearing capacity. In some recent studies, several attempts have been made to clarify the subsoil behavior adjacent to the pile tip, such as evaluation of stress development around the pile tip (Jardine et al, 2013;Yang et al, 2014), soil crushability and the corresponding pile bearing mechanism (Kuwajima et al, 2009;Zhang et al, 2014). It is generally found that the stress around a pile is radially developed and the high stress zone is restrained near to the pile shaft.…”

Section: Introductionmentioning

confidence: 99%

Acoustic emission characteristics of subsoil subjected to vertical pile loading in sand

Mao

Aoyama

Goto

et al. 2015

Journal of Applied Geophysics

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“…Besides of the conventional design methods employing the model test or in-situ test, numerical methods are more and more adopted in order to reduce the economic and time costs. Among numerous approaches, the finite element method (FEM) is considered a beneficial tool in engineering design (e.g., Kouretzis et al [1], Sheng et al [2], Zhang et al [3,4], Shen and Xu [5]; Wu et al [6]), when compared with meshfree methods [7], discrete element method (DEM) [8,9]. Accordingly, a numerical platform based on FEM adopting an appropriate constitutive model would be helpful for analyzing the pile penetration considering large deformation and further estimating the pile resistance.…”

Section: Introductionmentioning

confidence: 99%

“…The importance of this grain breakage in silica sand during pile penetration has been highlighted from a practical standpoint [3,4,[12][13][14][15][16][17][18]. Numerous studies have shown that the pile resistance in crushable sand is overestimated in comparison with that expected by a conventional simulation platform without considering grain breakage [1,3,[19][20][21]. Accordingly, the degrading effect of grain breakage on pile resistance should be considered for practical design, which poses a requirement that the constitutive model accounting for grain breakage should be employed in the numerical platform.…”

Section: Introductionmentioning

confidence: 99%

Numerical modeling of pile penetration in silica sands considering the effect of grain breakage

Jin

Yin

et al. 2018

Finite Elements in Analysis and Design

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Current numerical platforms rarely consider the effect of grain breakage in the design of sandy soil foundations. This paper presents an enhanced platform for large deformation analyses which considers the effect of grain breakage during pile penetration in silica sand. For this purpose, a model based on critical state theory has been developed within the framework of multisurface plasticity to account in the same constitutive platform the effect of stress dilatancy and particle fragmentation. Furthermore, to implement the underlying constitutive equations into a finite element code, a stress integration scheme has been adopted by extending a cutting plane algorithm to the model with multiple yielding mechanisms. A laboratory model test and a series of centrifuge tests of pile penetration are simulated to verify the performance of the selected constitutive approach in terms of pile resistance and grain breakage distribution, with the parameters of sand calibrated through a set of drained triaxial compression tests from low to very high confining pressure. Some extra features of the enhanced platform are also discussed, such as: i) the effect of sand crushability on pile resistance and ii) the nonlinear relation of pile resistance to sand density. The proposed findings demonstrate the capability of this numerical platform to proper design of pile foundation in sandy soils and highlight the interplay between stress dilatancy and grain breakage mechanisms during pile penetration processes.

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Theoretical breakage mechanics and experimental assessment of stresses surrounding piles penetrating into dense silica sand

Cited by 50 publications

References 19 publications

Field experiments at three sites to investigate the effects of age on steel piles driven in sand

Field experiments at three sites to investigate the effects of age on steel piles driven in sand

Acoustic emission characteristics of subsoil subjected to vertical pile loading in sand

Numerical modeling of pile penetration in silica sands considering the effect of grain breakage

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