Your search keyword '"Pedro, Antonio M. G."' showing total 3 results

1. IC MAGE Model 02 – Simple state-parameter dependent model with isotropic small strain stiffness

Author

Taborda, David M G, Pedro, Antonio M G, Kontoe, Stavroula, and Tsiampousi, Aikaterini

Subjects

Computer Science::Hardware Architecture, Sand, Finite Element Analysis, Geotechnical Analysis, Geotechnical Engineering, Constitutive Modelling

Abstract

IC MAGE M02 is a user-defined model for PLAXIS built using the IC MAGE UMIP framework which combines the state-parameter framework by Been & Jefferies (1985) with a Mohr-Coulomb failure criterion. The elastic response is given by the isotropic small strain stiffness model IC.G3S by Taborda et al. (2016). A reversal detection algorithm within a cyclic nonlinear elastic framework allows for the generation of hysteresis (and energy dissipation)., {"references":["Been, K. and Jefferies, M.G. (1985) A state parameter for sands. Geotechnique, 35(2), 99-112. https://doi.org/10.1680/geot.1985.35.2.99","Taborda, D.M.G., Potts, D.M. and Zdravković, L. (2016). On the assessment of energy dissipated through hysteresis in finite element analysis. Computers and Geotechnics, 71, 180–194. https://doi.org/10.1016/j.compgeo.2015.09.001","Taborda, D.M.G., Potts, D.M., Zdravković, L. and Pedro, A.M.G. (2018) Incorporating the state parameter into a simple constitutive model for sand. Numerical Methods in Geotechnical Engineering IX. https://doi.org/10.1201/9780429446931","Taborda, D.M.G and Zdravković, L. (2012). Application of a Hill-Climbing technique to the formulation of a new cyclic nonlinear elastic constitutive model. Computers and Geotechnics, 43, 80-91. https://doi.org/10.1016/j.compgeo.2012.02.001","Taborda, David M G, Kontoe, Stavroula, & Tsiampousi, Aikaterini. (2021, June 23). IC MAGE UMIP - universal model interface for PLAXIS (Version 2.0). Zenodo. http://doi.org/10.5281/zenodo.5018865"]}

Published

2023

2. IC MAGE Model 09 – Non-local simple state-parameter dependent model with isotropic small strain stiffness

Author

Taborda, David M G, Pedro, Antonio M G, Kontoe, Stavroula, and Tsiampousi, Aikaterini

Subjects

Computer Science::Hardware Architecture, Sand, Finite Element Analysis, Geotechnical Analysis, Geotechnical Engineering, Constitutive Modelling

Abstract

IC MAGE M09 is a user-defined model for PLAXIS built using the IC MAGE UMIP framework which combines the state-parameter framework by Been & Jefferies (1985) with a Mohr-Coulomb failure criterion. The elastic response is given by the isotropic small strain stiffness model IC.G3S by Taborda et al. (2016). A reversal detection algorithm within a cyclic nonlinear elastic framework allows for the generation of hysteresis (and energy dissipation). This model is the nonlocal version of IC MAGE M02., {"references":["Been, K. and Jefferies, M.G. (1985) A state parameter for sands. Geotechnique, 35(2), 99-112. https://doi.org/10.1680/geot.1985.35.2.99","Taborda, D.M.G., Potts, D.M. and Zdravković, L. (2016). On the assessment of energy dissipated through hysteresis in finite element analysis. Computers and Geotechnics, 71, 180–194. https://doi.org/10.1016/j.compgeo.2015.09.001","Taborda, D.M.G., Potts, D.M., Zdravković, L. and Pedro, A.M.G. (2018) Incorporating the state parameter into a simple constitutive model for sand. Numerical Methods in Geotechnical Engineering IX. https://doi.org/10.1201/9780429446931","Taborda, D.M.G and Zdravković, L. (2012). Application of a Hill-Climbing technique to the formulation of a new cyclic nonlinear elastic constitutive model. Computers and Geotechnics, 43, 80-91. https://doi.org/10.1016/j.compgeo.2012.02.001"]}

Published

2022

3. PISA design model for monopiles for offshore wind turbines: application to a marine sand.

Author

Burd, Harvey J., Taborda, David M. G., Zdravković, Lidija, Abadie, Christelle N., Byrne, Byron W., Houlsby, Guy T., Gavin, Kenneth G., Igoe, David J. P., Jardine, Richard J., Martin, Christopher M., McAdam, Ross A., Pedro, Antonio M. G., and Potts, David M.

Subjects

WIND turbines, CLAY soils, CYCLIC loads, SPECIFIC gravity, SOIL density, STIFFNESS (Engineering), SAND

Abstract

This paper describes a one-dimensional (1D) computational model for the analysis and design of laterally loaded monopile foundations for offshore wind turbine applications. The model represents the monopile as an embedded beam and specially formulated functions, referred to as soil reaction curves, are employed to represent the various components of soil reaction that are assumed to act on the pile. This design model was an outcome of a recently completed joint industry research project – known as PISA – on the development of new procedures for the design of monopile foundations for offshore wind applications. The overall framework of the model, and an application to a stiff glacial clay till soil, is described in a companion paper by Byrne and co-workers; the current paper describes an alternative formulation that has been developed for soil reaction curves that are applicable to monopiles installed at offshore homogeneous sand sites, for drained loading. The 1D model is calibrated using data from a set of three-dimensional finite-element analyses, conducted over a calibration space comprising pile geometries, loading configurations and soil relative densities that span typical design values. The performance of the model is demonstrated by the analysis of example design cases. The current form of the model is applicable to homogeneous soil and monotonic loading, although extensions to soil layering and cyclic loading are possible. [ABSTRACT FROM AUTHOR]

Published

2020