Displacement and strain paths during plane-strain model pile installation in sand
Displacement and strain paths during plane-strain model pile installation in sand
The underlying mechanisms governing the behaviour of displacement piles in sand are not well understood, leading to unreliability in design methods. A series of planestrain calibration chamber tests has been conducted in order to quantify the penetration mechanism around the pile tip, and the response of the interface layer adjacent to the shaft during further penetration. A series of eight tests is reported, examining the influence of soil type, initial state, pile breadth and the use of a driving shoe. A novel image-based deformation measurement technique has been used to observe the displacement and strain paths, which are found to be relatively independent of soil type. The measured strain paths are similar to predictions made by the strain path method, and contrast sharply with assumptions implicit in cavity expansion solutions. An interface zone adjacent to the pile shaft comprising fine broken soil particles was observed to contract while shearing along the pile-soil interface. This mechanism offers an explanation for the degradation of shaft friction at a given soil horizon with increased pile penetration ('friction fatigue'), and a subsequent recovery of capacity over time ('set-up').
Bearing capacity, Calcareous soils, Friction, Model tests, Piles, Sands
375-397
White, D.J.
a986033d-d26d-4419-a3f3-20dc54efce93
Bolton, M.D.
9fbf6ba8-1095-4220-a7f6-38f5463a58e7
August 2004
White, D.J.
a986033d-d26d-4419-a3f3-20dc54efce93
Bolton, M.D.
9fbf6ba8-1095-4220-a7f6-38f5463a58e7
White, D.J. and Bolton, M.D.
(2004)
Displacement and strain paths during plane-strain model pile installation in sand.
Geotechnique, 54 (6), .
(doi:10.1680/geot.54.6.375.45427).
Abstract
The underlying mechanisms governing the behaviour of displacement piles in sand are not well understood, leading to unreliability in design methods. A series of planestrain calibration chamber tests has been conducted in order to quantify the penetration mechanism around the pile tip, and the response of the interface layer adjacent to the shaft during further penetration. A series of eight tests is reported, examining the influence of soil type, initial state, pile breadth and the use of a driving shoe. A novel image-based deformation measurement technique has been used to observe the displacement and strain paths, which are found to be relatively independent of soil type. The measured strain paths are similar to predictions made by the strain path method, and contrast sharply with assumptions implicit in cavity expansion solutions. An interface zone adjacent to the pile shaft comprising fine broken soil particles was observed to contract while shearing along the pile-soil interface. This mechanism offers an explanation for the degradation of shaft friction at a given soil horizon with increased pile penetration ('friction fatigue'), and a subsequent recovery of capacity over time ('set-up').
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Published date: August 2004
Keywords:
Bearing capacity, Calcareous soils, Friction, Model tests, Piles, Sands
Identifiers
Local EPrints ID: 419847
URI: http://eprints.soton.ac.uk/id/eprint/419847
ISSN: 0016-8505
PURE UUID: 4ed7f4fa-f2fe-4631-ad85-fd286b52196d
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Date deposited: 23 Apr 2018 16:30
Last modified: 16 Mar 2024 04:32
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Author:
M.D. Bolton
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