One-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation
Traditional consolidation theories cannot provide good predictions of consolidation settlement in land reclamation because of their assumptions that the influence of soil's self-weight is often neglected, and the drainage boundary is considered as fully pervious/impervious. In view of these lim...
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sg-ntu-dr.10356-1511492021-06-29T01:43:56Z One-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation Feng, Jianxue Ni, Pengpeng Mei, Guoxiong School of Civil and Environmental Engineering Engineering::Civil engineering Analytical Solution Consolidation Traditional consolidation theories cannot provide good predictions of consolidation settlement in land reclamation because of their assumptions that the influence of soil's self-weight is often neglected, and the drainage boundary is considered as fully pervious/impervious. In view of these limitations, an analytical solution is derived for one-dimensional self-weight consolidation problems with a continuous drainage boundary using the finite Fourier sine transform method. Following the classical Terzaghi's small strain theory, the soil's self-weight is considered to produce consolidation settlement in dredged materials with a constant coefficient of consolidation. The continuous drainage boundary can essentially describe the time-dependent variation of drainage capacity at the interface between two adjacent soil layers. By reducing the interface parameters, the effectiveness of the calculation is demonstrated against the Terzaghi's solution. The influence of interface parameters and soil's self-weight stress coefficient on self-weight consolidation is discussed. As expected, the rate of consolidation considering the self-weight stress is faster, although the dependency of consolidation rate on the material property of void ratio is neglected. Moreover, the plane of maximum excess pore-water pressure is estimated as a function of time factor, based on which a design chart is developed to optimize the layout of horizontal drains in land reclamation. This work was supported by the National Natural Science Foundation of China (grants 41672296, 41867034, 51578164,and 51878185), the Natural Science Foundation of Guangxi Province (grant 2016GXNSFGA380008), and the Ministry of Education of China through the Changjiang Scholars Program 2021-06-29T01:43:56Z 2021-06-29T01:43:56Z 2019 Journal Article Feng, J., Ni, P. & Mei, G. (2019). One-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation. International Journal for Numerical and Analytical Methods in Geomechanics, 43(8), 1634-1652. https://dx.doi.org/10.1002/nag.2928 0363-9061 0000-0002-2422-3458 https://hdl.handle.net/10356/151149 10.1002/nag.2928 2-s2.0-85064814784 8 43 1634 1652 en International Journal for Numerical and Analytical Methods in Geomechanics © 2019 John Wiley & Sons, Ltd. All rights reserved. |
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Engineering::Civil engineering Analytical Solution Consolidation Feng, Jianxue Ni, Pengpeng Mei, Guoxiong One-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation |
| description |
Traditional consolidation theories cannot provide good predictions of consolidation settlement in land reclamation because of their assumptions that the influence of soil's self-weight is often neglected, and the drainage boundary is considered as fully pervious/impervious. In view of these limitations, an analytical solution is derived for one-dimensional self-weight consolidation problems with a continuous drainage boundary using the finite Fourier sine transform method. Following the classical Terzaghi's small strain theory, the soil's self-weight is considered to produce consolidation settlement in dredged materials with a constant coefficient of consolidation. The continuous drainage boundary can essentially describe the time-dependent variation of drainage capacity at the interface between two adjacent soil layers. By reducing the interface parameters, the effectiveness of the calculation is demonstrated against the Terzaghi's solution. The influence of interface parameters and soil's self-weight stress coefficient on self-weight consolidation is discussed. As expected, the rate of consolidation considering the self-weight stress is faster, although the dependency of consolidation rate on the material property of void ratio is neglected. Moreover, the plane of maximum excess pore-water pressure is estimated as a function of time factor, based on which a design chart is developed to optimize the layout of horizontal drains in land reclamation. |
| author2 |
School of Civil and Environmental Engineering |
| author_facet |
School of Civil and Environmental Engineering Feng, Jianxue Ni, Pengpeng Mei, Guoxiong |
| format |
Article |
| author |
Feng, Jianxue Ni, Pengpeng Mei, Guoxiong |
| author_sort |
Feng, Jianxue |
| title |
One-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation |
| title_short |
One-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation |
| title_full |
One-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation |
| title_fullStr |
One-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation |
| title_full_unstemmed |
One-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation |
| title_sort |
one-dimensional self-weight consolidation with continuous drainage boundary conditions : solution and application to clay-drain reclamation |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/151149 |
| _version_ |
1703971225697517568 |