Abstract:
We consider an initial-boundary problem describing the motion of a two-phase medium with a periodic structure. The first phase of the medium is an isotropic elastic material and the second phase is an incompressible viscoelastic Kelvin-Voigt fluid. This problem consists of second and fourth order partial differential equations, conditions of continuity of displacements and stresses at the phase boundaries, and homogeneous initial and boundary conditions. Using the Laplace transform method, we derive a homogenized problem, which is an initial boundary value problem for the system of fourth order partial integro-differential equations with constant coefficients. The coefficients and convolution kernels of the homogenized equations are found by using solutions of auxiliary periodic problems on the unit cube. In the case of a layered medium, the solutions of the periodic problems are written explicitly, and this allows us to find analytic expressions for the homogenized coefficients and convolution kernels. In particular, we establish that the type and properties of the homogenized convolution kernels depend on the volume fraction of the fluid layers inside the periodicity cell.
Keywords:homogenization, equations of motion, two-phase medium, elastic material, Kelvin-Voigt fluid.