Analytical prediction of ground movements due to circular shaft construction in clayey soils

Chen   Zheng; Andrea Franza; Rafael  Jimenez

doi:10.1139/cgj-2022-0381

Analytical prediction of ground movements due to circular shaft construction in clayey soils

Chen Zheng
, Andrea Franza^*
, Rafael Jimenez

^*Corresponding author for this work

Department of Civil and Architectural Engineering - Structural Dynamics and Geotechnical Engineering

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

4 Citations (Scopus)

190 Downloads (Pure)

Abstract

With the rapid expansion of urbanization, shafts are needed to provide access to tunnelling projects or be utilized for permanent works. Their construction causes ground movements, affecting nearby foundations and buried infrastructure. This study presents an analytical equivalent volume loss approach for predicting three-dimensional ground movements resulting from a circular shaft construction: namely, ground losses in the elastic isotropic half space as a sequence of cavity contractions around the shaft are employed. First, the applicability and accuracy of proposed solutions are evaluated with published case studies and centrifuge tests. Thereafter, the method is employed to investigate the influence of the circular shaft construction on the surface and subsurface soil displacements. Considering design ground losses, this method allows for quick estimations of ground deformations and associated risk of serviceability losses.

Original language	English
Journal	Canadian Geotechnical Journal
Volume	60
Issue	8
Pages (from-to)	1132-1139
Number of pages	8
ISSN	0008-3674
DOIs	https://doi.org/10.1139/cgj-2022-0381
Publication status	Published - 2023

Keywords

analytical solution
ground loss
ground movements
shaft construction

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10.1139/cgj-2022-0381

circular_shaft_gf_aam_nonum-f32aqcygwvulky4corbxtlolq4rqgwz3Accepted manuscript, 1.08 MBLicence: CC BY

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title = "Analytical prediction of ground movements due to circular shaft construction in clayey soils",

abstract = "With the rapid expansion of urbanization, shafts are needed to provide access to tunnelling projects or be utilized for permanent works. Their construction causes ground movements, affecting nearby foundations and buried infrastructure. This study presents an analytical equivalent volume loss approach for predicting three-dimensional ground movements resulting from a circular shaft construction: namely, ground losses in the elastic isotropic half space as a sequence of cavity contractions around the shaft are employed. First, the applicability and accuracy of proposed solutions are evaluated with published case studies and centrifuge tests. Thereafter, the method is employed to investigate the influence of the circular shaft construction on the surface and subsurface soil displacements. Considering design ground losses, this method allows for quick estimations of ground deformations and associated risk of serviceability losses.",

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T1 - Analytical prediction of ground movements due to circular shaft construction in clayey soils

AU - Zheng, Chen

AU - Franza, Andrea

AU - Jimenez, Rafael

PY - 2023

Y1 - 2023

N2 - With the rapid expansion of urbanization, shafts are needed to provide access to tunnelling projects or be utilized for permanent works. Their construction causes ground movements, affecting nearby foundations and buried infrastructure. This study presents an analytical equivalent volume loss approach for predicting three-dimensional ground movements resulting from a circular shaft construction: namely, ground losses in the elastic isotropic half space as a sequence of cavity contractions around the shaft are employed. First, the applicability and accuracy of proposed solutions are evaluated with published case studies and centrifuge tests. Thereafter, the method is employed to investigate the influence of the circular shaft construction on the surface and subsurface soil displacements. Considering design ground losses, this method allows for quick estimations of ground deformations and associated risk of serviceability losses.

AB - With the rapid expansion of urbanization, shafts are needed to provide access to tunnelling projects or be utilized for permanent works. Their construction causes ground movements, affecting nearby foundations and buried infrastructure. This study presents an analytical equivalent volume loss approach for predicting three-dimensional ground movements resulting from a circular shaft construction: namely, ground losses in the elastic isotropic half space as a sequence of cavity contractions around the shaft are employed. First, the applicability and accuracy of proposed solutions are evaluated with published case studies and centrifuge tests. Thereafter, the method is employed to investigate the influence of the circular shaft construction on the surface and subsurface soil displacements. Considering design ground losses, this method allows for quick estimations of ground deformations and associated risk of serviceability losses.

KW - analytical solution

KW - ground loss

KW - ground movements

KW - shaft construction

U2 - 10.1139/cgj-2022-0381

DO - 10.1139/cgj-2022-0381

M3 - Journal article

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VL - 60

SP - 1132

EP - 1139

JO - Canadian Geotechnical Journal

JF - Canadian Geotechnical Journal

IS - 8

ER -

Analytical prediction of ground movements due to circular shaft construction in clayey soils

Abstract

Keywords

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