Penetration of unconventional spudcan foundations using back analyses of large deformation CPT profiles

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Abstract

Accurate determination of the load-penetration behaviour of spudcan footings is vital in predicting the performance of offshore structures. Often, insufficient site investigation data is a limiting factor in assessing spudcan penetration, with the selection of suitable parameters typically derived from triaxial tests or Cone Penetrometer Test (CPT) data. A method is presented for simulating spudcan insertion in loose to medium-dense sand, based on minimal data, whereby the CPT tip resistance is used in combination with known correlations of soil properties, allowing for back analysis of CPT profiles through Large Deformation Finite Element (LDFE) simulation. The use of LDFE allows for failure mechanisms to be determined a priori, as a result of the simulation process, while a range of constitutive models can be implemented as necessary. Friction angle, dilation angle and relative density correlations are combined with a calibration of the elastic modulus, used to develop numerical models based on a set of soil sub-layers, each 1 m in depth. The resulting soil characterisations were used to calculate the load-penetration behaviour of several spudcan geometries (which deviate from conventional spudcan shapes) using the LDFE, to assess their performance. Results generated using the proposed technique show strong agreement with a presented field observations.