Modelling vibrated stone columns in soft clay

McKelvey, David; Sivakumar, V.; Bell, A. L.; Graham, J.

doi:10.1680/geng.2004.157.3.137

Cited by 134 publications

(26 citation statements)

References 4 publications

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“…The bearing capacity of those groups of stone columns has predominantly been the focus of previous studies [5][6][7][8]. However, stone columns are installed in soft soils that can undergo large displacements at relatively low loads and the serviceability limit state may be critical for their design.…”

Section: Introductionmentioning

confidence: 99%

Numerical modelling of stone columns beneath a rigid footing

Castro

2014

Computers and Geotechnics

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Section: Introductionmentioning

confidence: 99%

Numerical modelling of stone columns beneath a rigid footing

Castro

2014

Computers and Geotechnics

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“…Laboratory-based research, together with analytical modelling, numerical modelling and field observations, is well documented, and has contributed to improvements in efficiency and quality control (Hughes & Withers, 1974;Hughes et al, 1975;Aboshi et al, 1979;Balaam & Booker, 1981;Barksdale & Bachus, 1983;Charles & Watts, 1983;Alamgir et al, 1994;Hu, 1995;Balaam et al, 1977;Raju, 1997;Slocombe et al, 2000;Watts & Serridge, 2000;McKelvey, 2002;McKelvey et al, 2004;Pulko & Majes, 2005;Black, 2007;Black et al, 2007aBlack et al, , 2007bMcCabe et al, 2009). Stone columns are typically employed to support large raft foundations at relatively low or moderate loading conditions.…”

Section: Introductionmentioning

confidence: 99%

The settlement performance of stone column foundations

2011

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Vibrated stone columns are frequently used as a method of reinforcing soft ground as they provide increased bearing capacity and reduce foundation settlements. Their performance in relation to bearing capacity is well documented, but there is also a need for enhanced understanding of their settlement characteristics, particularly in relation to small-group configurations. This paper presents results obtained from physical model tests on triaxial specimens 300 mm in diameter and 400 mm high. Parameters investigated include column length to diameter ratio, area replacement ratio and single/group configuration. The findings of the work are as follows. The design is flexible: settlement can equally be controlled using short columns at relatively high area replacement ratios, or longer columns at smaller area replacement ratios. An optimum area replacement ratio of 30-40% exists for the control of settlement. The settlement performance of a small column group is highly influenced by inter-column and footing interaction effects.

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“…The transparent soil used in this investigation consisted of 6% fumed amorphous silica aggregates (Lehane and Gill, 2004;McKelvey et al, 2004) and 94% pore fluid. This fluid was a blend of paraffinic solvent (N-paraffin C10-13 supplied by Aztec Oils, Chesterfield, UK) and white oil (Baylube WOM 15 supplied by Bayford Oils, Leeds, UK) mixed to volumetric proportions of 77:23 and giving a refractive index matched to the silica aggregates at 208C.…”

Section: Transparent Soilmentioning

confidence: 99%

“…A significant drawback with these two investigations was that model size was limited by imperfect transparency of the soil, introducing boundary effects. Hird and Stanier (2010) reported that using fumed rather than precipitated silica (following McKelvey et al, 2004) in conjunction with the laser-aided PIV technique allowed larger models to be used, thereby reducing boundary effects. Later Stanier et al (2012) proposed a photogrammetric correction framework to improve the reliability of the PIV measurements made in their transparent soil, alongside an example analysis of the failure mechanism of a doublehelix screw pile loaded in tension.…”

Section: Introductionmentioning

confidence: 99%

Modelling helical screw piles in soft clay and design implications

Stanier

Black

Hird

2014

Proceedings of the Institution of Civil Engineers - Geotechnica

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Helical screw piles are a popular solution for relatively low-capacity, removable or recyclable foundations supporting road and rail signage or similar light structures. When specifying a helical screw pile, a designer must choose the active length and the helical plate spacing ratio, which are governed by the number, spacing and size of the individual helices. This paper presents an investigation using transparent synthetic soil and particle image velocimetry to observe the failure of helical screw piles with helical plate spacing ratios of 1 . 5-3 and active lengths up to three times the diameter. For the geometries and properties examined, capacity is shown to be a function of active length and the dominant failure mechanism is characterised by the formation of a cylindrical failure surface. A simple analytical model is developed and used to assess the impact of different design methodologies on immediate displacements under loading. A traditional 'permissible stress' method is shown to be conservative, whereas modern 'partial factor' methods are more economical and lead to greater immediate displacements for a given design load.Designers using modern 'partial factor' approaches, such as Eurocode 7, might benefit from specifying a helical plate spacing ratio of less than 1 . 5 to maximise the stiffness of the response to axial loading and minimise the immediate displacements experienced upon application of working loads.

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Modelling vibrated stone columns in soft clay

Cited by 134 publications

References 4 publications

Numerical modelling of stone columns beneath a rigid footing

Numerical modelling of stone columns beneath a rigid footing

The settlement performance of stone column foundations

Modelling helical screw piles in soft clay and design implications

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