An introduction to linear poroelasticity (1607.04274v1)

Abstract: This study is an introduction to the theory of three-dimensional consolidation. The point of departure in the description are the basic equations of elasticity (i.e. constitutive law, equations of equilibrium in terms of stresses, and the definition of strain), together with the principle of effective stress, and the law of Darcy for fluid flow in porous media. These equations, together with the principle of mass conservation, are the only premises used to derive a drained description of consolidation theory. Next, the increment of fluid content is defined and its constitutive law is derived - with its derivation following naturally from the equation of fluid mass balance. Pore pressure, storage, and undrained coefficients are also introduced and useful relations are proven. Where appropriate, the physical meaning of these coefficients is proven mathematically. Equations of equilibrium and fluid mass conservation are subsequently expressed in terms of the increment of fluid content and undrained coefficients, leading to an undrained description of consolidation theory. Thus the initial approach of using drained description is extended to the formalism of Rice and Cleary. This approach to three-dimensional consolidation is useful for its simplicity. It does not require the ad-hoc definition of constants and that of an elastic energy potential. Instead, it is a direct extension to linear elasticity that accounts for the coupling of skeletal deformations and fluid behaviour.