Although suction caissons have been used as mooring systems for offshore structures since 1980s, the working principles of caissons installed in clay and subjected to uplift loading have not been fully understood. Those phenomena include (1) installation resistance during both self-weight and suction penetration; (2) distribution of excess pore pressures, EPPs induced by installation in the soil and their dissipation after installation; (3) setup development; (4) failure mechanism and corresponding appropriate parameters for reasonable prediction of pullout capacity; and (5) distribution of EPPs in soil during pullout of a suction caisson. This study was to investigate these phenomena using both centrifuge modeling and finite element analysis (FEA).; The first part of this study focuses on centrifuge modeling on the behavior of suction caissons in normally consolidated (NC) or slightly overconsolidated (SOC) clay. All caissons were installed in-flight by both self-weight and active suction. The undrained shear strength profile, the penetration resistance profile, the distribution and dissipation of the EPPs in clay during both installation and pullout phases, the passive suction, and the pullout capacity were measured.; The second part of this study focuses on the numerical investigation of the behavior of suction caissons subjected to vertical loading. A finite element model based on centrifuge model test SAT06 was developed. The caisson-soil interaction was simulated using interface elements. A new method, in which the water inside the caisson is simulated by a very soft porous-elastic material, was introduced to simulate the development of passive suction. This numerical model was validated using the centrifuge experimental results.; Finite element analysis (FEA) results confirmed the failure mechanism of suction caisson in clay observed in the centrifuge tests. FEA results also indicated that the distribution of the EPPs in the soil inside the caisson is different from that in the outside soil during pullout of a suction caisson.; In summary, this study has combined centrifuge modeling and finite element analysis to investigate the performance of suction caissons in clay. The study presented in this thesis clarifies several working principles of suction caissons to provide better understanding. They include the friction coefficients for predicting the installation resistance during both self-weight and suction penetration, the distribution of EPPs in clay induced by installation and their dissipation with time, the setup development, the failure mechanism with corresponding parameters, the EPPs in clay during pullout of the caisson, and the simulation of passive suction using FEA. (Abstract shortened by UMI.)
展开▼
