Limiting cavity depth for spudcan foundations penetrating clay
Limiting cavity depth for spudcan foundations penetrating clay
Centrifuge model tests and unite element (FE) analysis have been conducted to study the penetration of spudcan foundations in uniform clay with nominally constant strength with depth. In particular, the transition between shallow penetration, with soil heaving to the ground surface, and deep penetration, with a localised flow-round mechanism, has been investigated. This transition governs the onset of back-flow and hence the depth of soil lying on the installed spudcan, which in turn influences the bearing capacity and also the potential for suction to develop and hence the uplift capacity and moment resistance of the foundation. The maximum cavity depth above the spudcan prior to any back-flow is therefore a critical issue for spudcan assessment in clay. In the centrifuge model tests, a half-spudcan model penetrating against a transparent window has been used to visualise the soil flow mechanisms around the spudcan during penetration. The formation of a cavity above the spudcan is revealed by both centrifuge modelling and FE analysis. It is found that there are three distinct penetration mechanisms during spudcan installation: during initial penetration, an open cavity is formed with vertical walls; with further penetration, soil flows partially around the spudcan into the cavity; during deep penetration, the spudcan is fully embedded and the soil flow mechanism is entirely localised. Over the wide range of normalised soil strengths explored, the soil back-flow in the second stage was shown to be due to a flow failure that was triggered by the spudcan penetration and not by wall failure, that is, the collapse of the vertical sides of the soil cavity. This observation is supported by FE analysis. The cavity depth due to flow failure is much shallower than the criterion for wall failure that is incorporated in current design guidelines. Instead, a new design chart and expression is suggested with the normalised cavity depth expressed as a function of the soil shear strength, normalised by the effective unit weight of the soil and the spudcan diameter.
Clays, Footings/foundations, Model tests, Numerical modelling, Offshore engineering, Plasticity
679-690
Hossain, M.S.
ba5eb288-0380-4f82-bda6-0a86068f0665
Hu, Y.
58ba91c9-5c7e-4874-8cfc-6d3c7faf55a2
Randolph, M.F.
75caa33a-e630-4ae8-84cd-758797bf9633
White, D.J.
a986033d-d26d-4419-a3f3-20dc54efce93
November 2005
Hossain, M.S.
ba5eb288-0380-4f82-bda6-0a86068f0665
Hu, Y.
58ba91c9-5c7e-4874-8cfc-6d3c7faf55a2
Randolph, M.F.
75caa33a-e630-4ae8-84cd-758797bf9633
White, D.J.
a986033d-d26d-4419-a3f3-20dc54efce93
Hossain, M.S., Hu, Y., Randolph, M.F. and White, D.J.
(2005)
Limiting cavity depth for spudcan foundations penetrating clay.
Geotechnique, 55 (9), .
(doi:10.1680/geot.2005.55.9.679).
Abstract
Centrifuge model tests and unite element (FE) analysis have been conducted to study the penetration of spudcan foundations in uniform clay with nominally constant strength with depth. In particular, the transition between shallow penetration, with soil heaving to the ground surface, and deep penetration, with a localised flow-round mechanism, has been investigated. This transition governs the onset of back-flow and hence the depth of soil lying on the installed spudcan, which in turn influences the bearing capacity and also the potential for suction to develop and hence the uplift capacity and moment resistance of the foundation. The maximum cavity depth above the spudcan prior to any back-flow is therefore a critical issue for spudcan assessment in clay. In the centrifuge model tests, a half-spudcan model penetrating against a transparent window has been used to visualise the soil flow mechanisms around the spudcan during penetration. The formation of a cavity above the spudcan is revealed by both centrifuge modelling and FE analysis. It is found that there are three distinct penetration mechanisms during spudcan installation: during initial penetration, an open cavity is formed with vertical walls; with further penetration, soil flows partially around the spudcan into the cavity; during deep penetration, the spudcan is fully embedded and the soil flow mechanism is entirely localised. Over the wide range of normalised soil strengths explored, the soil back-flow in the second stage was shown to be due to a flow failure that was triggered by the spudcan penetration and not by wall failure, that is, the collapse of the vertical sides of the soil cavity. This observation is supported by FE analysis. The cavity depth due to flow failure is much shallower than the criterion for wall failure that is incorporated in current design guidelines. Instead, a new design chart and expression is suggested with the normalised cavity depth expressed as a function of the soil shear strength, normalised by the effective unit weight of the soil and the spudcan diameter.
This record has no associated files available for download.
More information
Published date: November 2005
Keywords:
Clays, Footings/foundations, Model tests, Numerical modelling, Offshore engineering, Plasticity
Identifiers
Local EPrints ID: 419666
URI: http://eprints.soton.ac.uk/id/eprint/419666
ISSN: 0016-8505
PURE UUID: 79d5e9a8-d93b-420a-b43c-efedb78e4ad8
Catalogue record
Date deposited: 19 Apr 2018 16:30
Last modified: 16 Mar 2024 04:32
Export record
Altmetrics
Contributors
Author:
M.S. Hossain
Author:
Y. Hu
Author:
M.F. Randolph
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
