A general solution for vertical-drain consolidation with impeded drainage boundaries

• Published in: Journal of Central South University Vol. 23; no. 4; pp. 934 - 943
• Main Authors: Fu, Cui-wei, Lei, Guo-hui
• Format: Journal Article
• Language: English
• Published: Changsha Central South University 01.04.2016
• Subjects: Civil; Energy and Traffic Engineering; Engineering; Geological; Metallic Materials; vertical drain; drainage boundary condition; consolidation; surcharge preloading; multi-ramp loading
• ISSN: 2095-2899; 2227-5223
• DOI: 10.1007/s11771-016-3141-x

An analytical solution is derived from the generalized governing equations of equal-strain consolidation with vertical drains under multi-ramp surcharge preloading. The hydraulic boundary conditions at both top and bottom of the consolidating soil are modelled as impeded drainage. The impeded drainage is described by using the third type boundary condition with a characteristic factor of drainage efficiency. Fully drained and undrained boundary conditions can also be modelled by applying an infinite and a zero characteristic factor, respectively. Simultaneous radial and vertical flow conditions are considered, together with the effects of drain resistance and smear. An increase in total stress due to multi-ramp loading is reasonably modelled as a function of both time and depth. A solution to calculate excess pore-water pressure at any arbitrary point in soil is derived, and the overall average degree of consolidation is obtained. It shows that the proposed solution can be used to analyze not only vertical-drain consolidation but also one-dimensional consolidation under either one-way or two-way vertical drainage conditions. The characteristic factors of drainage efficiency of top and bottom boundaries have a potentially important influence on consolidation. The boundary may be considered fully drained when the characteristic factor is greater than 100 and fully undrained when the characteristic factor is less than 0.1. The stress distribution along depth induced by the surcharge loading has a limited effect on the overall average degree of consolidation. However, it has a significant effect on the dissipation of excess pore-water pressure.