Abstract:
Methodologies of implementing nonlinear constitutive models of soil in FLAC are
studied in order to reduce numerical distortion, which has been found to occur in
nonlinear dynamic analysis when a nonlinear soil model is implemented using an
‘apparent modulus’ approach. Analyses undertaken using several simple nonlinear soil
models indicate that use of ‘plastic correction’ approach can eliminate or minimize the
problem. This approach is therefore adopted in the thesis to implement in FLAC a
bounding surface bubble soil model, i.e. the Bubble model. Satisfactory performance of
the Bubble model has been obtained in dynamic analysis without using any of the
additional mechanical damping given in FLAC.
An analytical study on the Bubble model is carried out with FLAC. On the basis of the
study, the hardening function is modified to better incorporate size ratio effects of the
yield surface and is explored to eliminate abrupt transition in stiffness from elastic region
to yielding. Pore water pressure is formulated with the assumption that the pore water
pressure is generated as a response to the constant volume constraint which prevents the
tendency for volume change when plastic volumetric strain takes place. The formulation
is added to the Bubble model so that pore water pressure can be generated automatically
by the model for fully saturated and undrained soil. FLAC analyses indicate that the
Bubble model is generally in good agreement with published experimental data.
The parameters and initial conditions associated with the Bubble model are studied with
FLAC analyses in triaxial stress space to investigate their influence on the model and to
investigate their effective ranges. Both large and small strain behaviors of the model are
explored in the parametric study.
Finally, the Bubble model is applied in the modeling of vertical vibration of rigid strip
foundations. The influence of soil nonlinearity on vertical compliance of rigid
foundations is investigated. Some major factors are considered, which include initial
stress level in soil, level of excitation and mass ratio of foundation.