Cyclic characterisation of low-to-medium density chalk for offshore driven pile design

Tingfa Liu; Reza Ahmadi-Naghadeh; Róisín M. Buckley; Ross A. McAdam; Richard J. Jardine; Ken Vinck; Stavroula Kontoe; Byron W. Byrne

Cyclic characterisation of low-to-medium density chalk for offshore driven pile design

Tingfa Liu, Reza Ahmadi-Naghadeh, Róisín M. Buckley, Ross A. McAdam, Richard J. Jardine, Ken Vinck, Stavroula Kontoe, Byron W. Byrne

School of Civil, Aerospace and Design Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference Contribution (Conference Proceeding)

4 Citations (Scopus)

90 Downloads (Pure)

Abstract

Project-specific advanced laboratory testing is employed increasingly frequently in site investigations for ma-jor offshore projects. Such testing needs to focus on characterising properties under in-situ conditions, while also catering for the effects of foundation installation and subsequent service conditions, including cyclic loading. Low-to-medium density Chalk, a variable soft biomicrite, can be de-structured to soft paste under dynamic percussion or large-strain repetitive shearing, posing significant challenges and uncertainties for driv-en pile design. This paper draws on key outcomes from undrained cyclic triaxial test programmes on both in-tact chalk and dynamically de-structured (putty) chalk. The cyclic response of intact chalk resembles the fa-tigue behaviour of hard rocks and develops little sign of damage before sharp pore pressure reductions and brittle collapse occurs. In contrast, fully de-structured chalk develops both contractive and dilative phases, as seen with silts. The associated effective stress reductions vary systematically with the number of cycles and cyclic stress ratio. A laboratory-based global axial cyclic predictive method is proposed from the experiments and employed to predict the outcomes of field axial cyclic loading pile tests. The research provides the basis for robust cyclic design guidance for piles driven in low-to-medium density Chalk.

Original language	English
Title of host publication	Innovative Geotechnologies for Energy Transition
Subtitle of host publication	9th International SUT Offshore Site Investigation and Geotechnics Conference
Publisher	Society for Underwater Technology
Pages	1098-1105
Number of pages	8
Volume	2
ISBN (Print)	978-0-906940-60-0
Publication status	Published - 14 Sept 2023
Event	9th International SUT OSIG Conference: Innovative Geotechnologies for Energy Transition - Imperial College, London, United Kingdom Duration: 12 Sept 2023 → 14 Sept 2023 https://sut.org/event/osig2023/

Publication series

Name	Edit Offshore Site Investigation and Geotechnics
Publisher	Society for Underwater Technology
ISSN (Print)	2754-6322

Conference

Conference	9th International SUT OSIG Conference
Country/Territory	United Kingdom
City	London
Period	12/09/23 → 14/09/23
Internet address	https://sut.org/event/osig2023/

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Liu, T., Ahmadi-Naghadeh, R., Buckley, R. M., McAdam, R. A., Jardine, R. J., Vinck, K., Kontoe, S., & Byrne, B. W. (2023). Cyclic characterisation of low-to-medium density chalk for offshore driven pile design. In Innovative Geotechnologies for Energy Transition: 9th International SUT Offshore Site Investigation and Geotechnics Conference (Vol. 2, pp. 1098-1105). (Edit Offshore Site Investigation and Geotechnics). Society for Underwater Technology. https://sut.org/books-and-conference-proceedings/offshore-site-investigation-and-geotechnics-2023-conference-proceedings/

Liu, Tingfa ; Ahmadi-Naghadeh, Reza ; Buckley, Róisín M. et al. / Cyclic characterisation of low-to-medium density chalk for offshore driven pile design. Innovative Geotechnologies for Energy Transition: 9th International SUT Offshore Site Investigation and Geotechnics Conference. Vol. 2 Society for Underwater Technology, 2023. pp. 1098-1105 (Edit Offshore Site Investigation and Geotechnics).

@inproceedings{714f33d570c743d59463332aaba1e072,

title = "Cyclic characterisation of low-to-medium density chalk for offshore driven pile design",

abstract = "Project-specific advanced laboratory testing is employed increasingly frequently in site investigations for ma-jor offshore projects. Such testing needs to focus on characterising properties under in-situ conditions, while also catering for the effects of foundation installation and subsequent service conditions, including cyclic loading. Low-to-medium density Chalk, a variable soft biomicrite, can be de-structured to soft paste under dynamic percussion or large-strain repetitive shearing, posing significant challenges and uncertainties for driv-en pile design. This paper draws on key outcomes from undrained cyclic triaxial test programmes on both in-tact chalk and dynamically de-structured (putty) chalk. The cyclic response of intact chalk resembles the fa-tigue behaviour of hard rocks and develops little sign of damage before sharp pore pressure reductions and brittle collapse occurs. In contrast, fully de-structured chalk develops both contractive and dilative phases, as seen with silts. The associated effective stress reductions vary systematically with the number of cycles and cyclic stress ratio. A laboratory-based global axial cyclic predictive method is proposed from the experiments and employed to predict the outcomes of field axial cyclic loading pile tests. The research provides the basis for robust cyclic design guidance for piles driven in low-to-medium density Chalk.",

author = "Tingfa Liu and Reza Ahmadi-Naghadeh and Buckley, \{R{\'o}is{\'i}n M.\} and McAdam, \{Ross A.\} and Jardine, \{Richard J.\} and Ken Vinck and Stavroula Kontoe and Byrne, \{Byron W.\}",

year = "2023",

month = sep,

day = "14",

language = "English",

isbn = "978-0-906940-60-0",

volume = "2",

series = "Edit Offshore Site Investigation and Geotechnics",

publisher = "Society for Underwater Technology",

pages = "1098--1105",

booktitle = "Innovative Geotechnologies for Energy Transition",

address = "United Kingdom",

note = "9th International SUT OSIG Conference : Innovative Geotechnologies for Energy Transition ; Conference date: 12-09-2023 Through 14-09-2023",

url = "https://sut.org/event/osig2023/",

}

Liu, T, Ahmadi-Naghadeh, R, Buckley, RM, McAdam, RA, Jardine, RJ, Vinck, K, Kontoe, S & Byrne, BW 2023, Cyclic characterisation of low-to-medium density chalk for offshore driven pile design. in Innovative Geotechnologies for Energy Transition: 9th International SUT Offshore Site Investigation and Geotechnics Conference. vol. 2, Edit Offshore Site Investigation and Geotechnics, Society for Underwater Technology, pp. 1098-1105, 9th International SUT OSIG Conference, London, United Kingdom, 12/09/23. <https://sut.org/books-and-conference-proceedings/offshore-site-investigation-and-geotechnics-2023-conference-proceedings/>

Cyclic characterisation of low-to-medium density chalk for offshore driven pile design. / Liu, Tingfa; Ahmadi-Naghadeh, Reza; Buckley, Róisín M. et al.
Innovative Geotechnologies for Energy Transition: 9th International SUT Offshore Site Investigation and Geotechnics Conference. Vol. 2 Society for Underwater Technology, 2023. p. 1098-1105 (Edit Offshore Site Investigation and Geotechnics).

Research output: Chapter in Book/Report/Conference proceeding › Conference Contribution (Conference Proceeding)

TY - GEN

T1 - Cyclic characterisation of low-to-medium density chalk for offshore driven pile design

AU - Liu, Tingfa

AU - Ahmadi-Naghadeh, Reza

AU - Buckley, Róisín M.

AU - McAdam, Ross A.

AU - Jardine, Richard J.

AU - Vinck, Ken

AU - Kontoe, Stavroula

AU - Byrne, Byron W.

PY - 2023/9/14

Y1 - 2023/9/14

N2 - Project-specific advanced laboratory testing is employed increasingly frequently in site investigations for ma-jor offshore projects. Such testing needs to focus on characterising properties under in-situ conditions, while also catering for the effects of foundation installation and subsequent service conditions, including cyclic loading. Low-to-medium density Chalk, a variable soft biomicrite, can be de-structured to soft paste under dynamic percussion or large-strain repetitive shearing, posing significant challenges and uncertainties for driv-en pile design. This paper draws on key outcomes from undrained cyclic triaxial test programmes on both in-tact chalk and dynamically de-structured (putty) chalk. The cyclic response of intact chalk resembles the fa-tigue behaviour of hard rocks and develops little sign of damage before sharp pore pressure reductions and brittle collapse occurs. In contrast, fully de-structured chalk develops both contractive and dilative phases, as seen with silts. The associated effective stress reductions vary systematically with the number of cycles and cyclic stress ratio. A laboratory-based global axial cyclic predictive method is proposed from the experiments and employed to predict the outcomes of field axial cyclic loading pile tests. The research provides the basis for robust cyclic design guidance for piles driven in low-to-medium density Chalk.

AB - Project-specific advanced laboratory testing is employed increasingly frequently in site investigations for ma-jor offshore projects. Such testing needs to focus on characterising properties under in-situ conditions, while also catering for the effects of foundation installation and subsequent service conditions, including cyclic loading. Low-to-medium density Chalk, a variable soft biomicrite, can be de-structured to soft paste under dynamic percussion or large-strain repetitive shearing, posing significant challenges and uncertainties for driv-en pile design. This paper draws on key outcomes from undrained cyclic triaxial test programmes on both in-tact chalk and dynamically de-structured (putty) chalk. The cyclic response of intact chalk resembles the fa-tigue behaviour of hard rocks and develops little sign of damage before sharp pore pressure reductions and brittle collapse occurs. In contrast, fully de-structured chalk develops both contractive and dilative phases, as seen with silts. The associated effective stress reductions vary systematically with the number of cycles and cyclic stress ratio. A laboratory-based global axial cyclic predictive method is proposed from the experiments and employed to predict the outcomes of field axial cyclic loading pile tests. The research provides the basis for robust cyclic design guidance for piles driven in low-to-medium density Chalk.

M3 - Conference Contribution (Conference Proceeding)

SN - 978-0-906940-60-0

VL - 2

T3 - Edit Offshore Site Investigation and Geotechnics

SP - 1098

EP - 1105

BT - Innovative Geotechnologies for Energy Transition

PB - Society for Underwater Technology

T2 - 9th International SUT OSIG Conference

Y2 - 12 September 2023 through 14 September 2023

ER -

Liu T, Ahmadi-Naghadeh R, Buckley RM, McAdam RA, Jardine RJ, Vinck K et al. Cyclic characterisation of low-to-medium density chalk for offshore driven pile design. In Innovative Geotechnologies for Energy Transition: 9th International SUT Offshore Site Investigation and Geotechnics Conference. Vol. 2. Society for Underwater Technology. 2023. p. 1098-1105. (Edit Offshore Site Investigation and Geotechnics).

Cyclic characterisation of low-to-medium density chalk for offshore driven pile design

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