Effect of strain-softening and strength anisotropy on the undrained bearing capacity of non-associated clay

Abstract

The bearing capacity of soils are critical for the design and analysis of foundations. The classical solutions derived from methods of characteristics and bound theories are based on the rigid plasticity and associated flow rule, which may not be realistic for natural soils. The undrained shear strength of soft clays exhibits strain-softening and anisotropic behavior in the lab tests, which creates complexity to choose appropriate strength parameters in conventional design process. In addition, the stress-strain characters are non-associative and path dependent, which also affects the bearing capacity of soils. This paper investigates two classical stability problems (i.e. deeply embedded pile/pipe section, and rigid strip footing) using the finite element analysis and MIT-E3 soil model, and demonstrates the effects of stain-softening and strength anisotropy on the undrained bearing capacity of soils. The computed results are compared with analytical solutions and finite element limit analysis, as well as those from finite element analysis using conventional soil models. These findings have strong practical implications to predict the bearing capacity of foundations and interpret insitu tests.