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AbstractThe Mad Dog Spar is moored by suction anchors arranged in three Clusters. Two anchor Clusters lie on top of the Sigsbee Escarpment while one anchor Cluster lies in a slump unit below the Escarpment. The soil conditions at the 4 pile locations in the slump deposit vary significantly and are very different from the soil conditions on top of the Escarpment. This dictated the need to make five different designs. This paper describes how the undrained shear strength selected for design was determined by combining the various soil conditions detected by CPT with the results from advanced and index laboratory testing. The design procedures used to design the anchors are explained in this paper. Also presented in the paper are the governing load cases together with results from holding capacity calculations using an efficient 3 D FE program.
Subsea umbilicals are widely used as an essential component in offshore oil and gas recovery and production facilities to transport chemicals, hydraulic fluids and electrical power and signals. The umbilical layout on the seafloor usually has a straight section near the riser touch-down-point (TDP) connected to a floating unit, followed by curved sections further beyond on the seabed. The heave motions of the floating unit at the sea surface due to environmental loading can induce cyclic tension loads on the umbilical at the seafloor and move the TDP location, resulting into axial, lateral and vertical motions along the umbilical. In addition to altering available umbilical embedded length this can also alter the field layout and may constitute violation of the design assumptions. This paper describes the results of a parametric analysis of an umbilical static stability with curved and straight sections, in a deepwater Gulf of Mexico seafloor environment, using finite element method (FEM). The finite element model of the umbilical and the surrounding soil was constructed using thin-walled, pipe elements and non-linear springs, respectively. Both, soil resistance to axial and to lateral motions along the umbilical were modeled. Degradation of soil shear strength due to cyclic loading was considered. Umbilical responses to increasing bottom tension loading at the TDP for a selected set of embedment, axial stiffness, radii and lengths of curved sections were examined and the axial and lateral displacements along the length of the umbilical are presented. Based on the results of the parametric analysis, a simple procedure for estimation of umbilical ultimate bottom tension load is presented.
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