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Finite element modelling of pipe piles driven in low-to-medium density chalk under monotonic axial loading

Finite element modelling of pipe piles driven in low-to-medium density chalk under monotonic axial loading
Finite element modelling of pipe piles driven in low-to-medium density chalk under monotonic axial loading

Percussive driving in low-to-medium density chalk creates a thin annulus of fully de-structured ‘putty’ chalk around pile shafts and an outer annular zone where fracturing is more intense than in the natural chalk. This damage and the related generation, and subsequent equalisation, of excess pore pressures impacts the piles’ time-dependent axial loading behaviour, as do other ageing processes. This paper presents finite element analyses of open steel tubular piles driven for the recent ALPACA and ALPACA Plus research projects under monotonic axial loading to failure after extended ageing periods. A nonlinear elastic stiffness model with a nonlocal deviatoric strain-based Mohr-Coulomb failure criterion was employed, with different sets of properties to represent the de-structured, fractured chalk and intact chalk. It is shown that the piles’ axial responses are mainly controlled by the puttified chalk annuli. A simplified but efficient means is adopted to impose pre-loading chalk effective stress conditions that explicitly capture the effects of installation damage and subsequent ageing. The potential for strain-softening in the brittle chalk is examined and the effective stress paths developed in representative chalk elements throughout the loading are considered in conjunction with the mobilisation of accumulated deviatoric strains. The simulations indicate 264% higher shaft capacity in compression than in tension, which is mainly attributed to the internal chalk plug.

Axially loaded driven piles, Finite element analysis, Low-to-medium density chalk, Offshore geotechnics
0266-352X
Wen, Kai
f2914054-5942-445d-9138-a8007243794c
Kontoe, Stavroula
d7a94a02-cb14-4ac3-8244-d8b1157aa8dc
Jardine, Richard
3527a76d-bcc6-4926-9145-1b5ddfa03aea
Liu, Tingfa
73a5ad31-63bf-448c-9220-8feac40e3adb
Wen, Kai
f2914054-5942-445d-9138-a8007243794c
Kontoe, Stavroula
d7a94a02-cb14-4ac3-8244-d8b1157aa8dc
Jardine, Richard
3527a76d-bcc6-4926-9145-1b5ddfa03aea
Liu, Tingfa
73a5ad31-63bf-448c-9220-8feac40e3adb

Wen, Kai, Kontoe, Stavroula, Jardine, Richard and Liu, Tingfa (2024) Finite element modelling of pipe piles driven in low-to-medium density chalk under monotonic axial loading. Computers and Geotechnics, 172, [106458]. (doi:10.1016/j.compgeo.2024.106458).

Record type: Article

Abstract

Percussive driving in low-to-medium density chalk creates a thin annulus of fully de-structured ‘putty’ chalk around pile shafts and an outer annular zone where fracturing is more intense than in the natural chalk. This damage and the related generation, and subsequent equalisation, of excess pore pressures impacts the piles’ time-dependent axial loading behaviour, as do other ageing processes. This paper presents finite element analyses of open steel tubular piles driven for the recent ALPACA and ALPACA Plus research projects under monotonic axial loading to failure after extended ageing periods. A nonlinear elastic stiffness model with a nonlocal deviatoric strain-based Mohr-Coulomb failure criterion was employed, with different sets of properties to represent the de-structured, fractured chalk and intact chalk. It is shown that the piles’ axial responses are mainly controlled by the puttified chalk annuli. A simplified but efficient means is adopted to impose pre-loading chalk effective stress conditions that explicitly capture the effects of installation damage and subsequent ageing. The potential for strain-softening in the brittle chalk is examined and the effective stress paths developed in representative chalk elements throughout the loading are considered in conjunction with the mobilisation of accumulated deviatoric strains. The simulations indicate 264% higher shaft capacity in compression than in tension, which is mainly attributed to the internal chalk plug.

Text
COMGE-S-24-00417_Clean Version - Accepted Manuscript
Restricted to Repository staff only until 27 May 2026.
Available under License Creative Commons Attribution Non-commercial No Derivatives.
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More information

Accepted/In Press date: 21 May 2024
e-pub ahead of print date: 27 May 2024
Published date: 27 May 2024
Keywords: Axially loaded driven piles, Finite element analysis, Low-to-medium density chalk, Offshore geotechnics

Identifiers

Local EPrints ID: 490888
URI: http://eprints.soton.ac.uk/id/eprint/490888
DOI: doi:10.1016/j.compgeo.2024.106458
ISSN: 0266-352X
PURE UUID: abed409d-8514-47a5-8bc7-b4962ce6c593
ORCID for Kai Wen: ORCID iD orcid.org/0009-0007-8066-1552

Catalogue record

Date deposited: 07 Jun 2024 17:31
Last modified: 08 Jun 2024 02:09

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Contributors

Author: Kai Wen ORCID iD
Author: Stavroula Kontoe
Author: Richard Jardine
Author: Tingfa Liu

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