Lateral bearing factors and elastic stiffness factors for robotic CPT p-y module in undrained clay
Lateral bearing factors and elastic stiffness factors for robotic CPT p-y module in undrained clay
There is a strong incentive to enhance in-situ ground characterisation tools to provide additional data that supports early infrastructure design in engineering projects, prior to completion of laboratory element testing on borehole samples. Advances in robotic technology allow additional soil deformation modes to be probed by integrating a cylindrical section of cone capable of horizontal translation into an expanded standard cone penetrometer, referred to here as ROBOCONE p-y module, which can mimic the load and displacement behaviour of laterally loaded pile element. This paper presents a series of three-dimensional elasto-plastic finite element simulations and semi-analytical upper bound analyses of this p-y module in homogeneous, undrained clay. The aim is to support the optimal choice of p-y module geometry and to lay the foundation of an interpretation method. In particular, the paper investigates the lateral bearing factor (N
RC) and elastic stiffness factor (K
RC) required for the measured load–displacement curves to be converted into practical design soil parameters such as undrained shear strength and elastic shear modulus. The numerical results reveal that N
RC varies inversely with the height-diameter ratio (H
R/D
R) of the p-y module and interface roughness, and these factors are compared to semi-analytical upper-bound solutions. Correction factors that allow for the finite length of the p-y module are derived, and these have minimal variation with interface roughness. The height-diameter ratio H
R/D
R has a similar influence on K
RC. Simple mechanism-based expressions for the lateral bearing and stiffness factors are devised to generalize the numerical results and provide definitive solutions to determine soil undrained strength and elastic stiffness from ROBOCONE p-y module measurements.
Elastic stiffness factor, Finite element simulation, Lateral bearing factor, ROBOCONE p-y module, Undrained clay, Upper bound analysis
Wen, Kai
f2914054-5942-445d-9138-a8007243794c
Cerfontaine, Benjamin
0730daf4-9d6b-4f2d-a848-a3fc54505a02
White, David
a986033d-d26d-4419-a3f3-20dc54efce93
Gourvenec, Susan
6ff91ad8-1a91-42fe-a3f4-1b5d6f5ce0b8
Diambra, Andrea
22d20b7d-0975-4af8-beb3-8ee0a6e4fbc6
4 June 2024
Wen, Kai
f2914054-5942-445d-9138-a8007243794c
Cerfontaine, Benjamin
0730daf4-9d6b-4f2d-a848-a3fc54505a02
White, David
a986033d-d26d-4419-a3f3-20dc54efce93
Gourvenec, Susan
6ff91ad8-1a91-42fe-a3f4-1b5d6f5ce0b8
Diambra, Andrea
22d20b7d-0975-4af8-beb3-8ee0a6e4fbc6
Wen, Kai, Cerfontaine, Benjamin, White, David, Gourvenec, Susan and Diambra, Andrea
(2024)
Lateral bearing factors and elastic stiffness factors for robotic CPT p-y module in undrained clay.
Computers and Geotechnics, 172, [106487].
(doi:10.1016/j.compgeo.2024.106487).
Abstract
There is a strong incentive to enhance in-situ ground characterisation tools to provide additional data that supports early infrastructure design in engineering projects, prior to completion of laboratory element testing on borehole samples. Advances in robotic technology allow additional soil deformation modes to be probed by integrating a cylindrical section of cone capable of horizontal translation into an expanded standard cone penetrometer, referred to here as ROBOCONE p-y module, which can mimic the load and displacement behaviour of laterally loaded pile element. This paper presents a series of three-dimensional elasto-plastic finite element simulations and semi-analytical upper bound analyses of this p-y module in homogeneous, undrained clay. The aim is to support the optimal choice of p-y module geometry and to lay the foundation of an interpretation method. In particular, the paper investigates the lateral bearing factor (N
RC) and elastic stiffness factor (K
RC) required for the measured load–displacement curves to be converted into practical design soil parameters such as undrained shear strength and elastic shear modulus. The numerical results reveal that N
RC varies inversely with the height-diameter ratio (H
R/D
R) of the p-y module and interface roughness, and these factors are compared to semi-analytical upper-bound solutions. Correction factors that allow for the finite length of the p-y module are derived, and these have minimal variation with interface roughness. The height-diameter ratio H
R/D
R has a similar influence on K
RC. Simple mechanism-based expressions for the lateral bearing and stiffness factors are devised to generalize the numerical results and provide definitive solutions to determine soil undrained strength and elastic stiffness from ROBOCONE p-y module measurements.
Text
COGE-106487
- Accepted Manuscript
Text
1-s2.0-S0266352X24004233-main
- Version of Record
More information
Accepted/In Press date: 29 May 2024
e-pub ahead of print date: 4 June 2024
Published date: 4 June 2024
Keywords:
Elastic stiffness factor, Finite element simulation, Lateral bearing factor, ROBOCONE p-y module, Undrained clay, Upper bound analysis
Identifiers
Local EPrints ID: 491209
URI: http://eprints.soton.ac.uk/id/eprint/491209
ISSN: 0266-352X
PURE UUID: 8b94f20a-4d4f-40c1-84d3-ac7e07db12c1
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Date deposited: 17 Jun 2024 16:49
Last modified: 18 Jun 2024 02:07
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Contributors
Author:
Kai Wen
Author:
Andrea Diambra
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