Abstract
Evidence shows that in the presence of extended stages of undrained creep, loose sands may approach liquefaction instabilities with a non-negligible time lag with respect to the application of loading. In this paper, a mechanical interpretation of such delayed failure events is provided by using stability criteria for rate-dependent materials. For this purpose, a viscoplastic constitutive law for sands has been calibrated to replicate delayed failure processes documented in the literature. To explain the origin of the transition from stable to unstable creep, the model predictions have been inspected from a mathematical standpoint and a strategy to evaluate the time required for the initiation of failure has been provided. The analyses show that the acceleration of the creep strains anticipates the sharp increase in the rate of pore water pressure, thus constituting a precursor to runaway failure. Furthermore, the computed stresses at which the two variables accelerate are located in proximity of the instability line for static liquefaction, with a shift from it that depends on the rate of loading prior to creep and the soil viscosity. These findings provide support to understand the interplay between rate-dependent soil properties and delayed liquefaction by offering a new conceptual platform to interpret the temporal evolution of flow failures observed under field or laboratory conditions.
Highlights
Offshore oil and gas pipelines in deep water are generally laid directly on the seabed, since trenching is uneconomic
Assumptions concerning the mobilised soil resistance are important in numerical modelling of controlled lateral buckling, which is required for a cost-effective pipeline design
In this paper a more extensive programme of distinctelement method (DEM) simulations is reported, considering the behaviour of a pipe segment on sand undergoing vertical penetration followed by various lateral displacements with different types of control in the vertical direction
Summary
Offshore oil and gas pipelines in deep water are generally laid directly on the seabed, since trenching is uneconomic. In this paper a more extensive programme of DEM simulations is reported, considering the behaviour of a pipe segment on sand undergoing vertical penetration followed by various lateral displacements (small and large, monotonic and cyclic) with different types of control in the vertical direction. Preliminary DEM simulations involving monotonic pipe displacements in the vertical and lateral directions were performed with various particle domain thicknesses and particle sizes to identify appropriate values for these parameters (Macaro, 2015). Displacement control was used to perform DEM simulations of both monotonic and cyclic sideswipe tests in which the pipe was subjected to lateral displacement, u, at constant embedment, w (Fig. 3). The amount of yield surface hardening during a Vertical force, V: N
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