The Study of Wave Propagation in a Shell with Soft Nonlinearity and with a Viscous Liquid Inside
Received 10 April 2019
2019, Vol. 15, no. 3, pp. 233-250
Author(s): Mogilevich L., Ivanov S.
This article is devoted to studying longitudinal deformation waves in physically nonlinear
elastic shells with a viscous incompressible fluid inside them. The impact of construction damping
on deformation waves in longitudinal and normal directions in a shell, and in the presence
of surrounding medium are considered.
The presence of a viscous incompressible fluid inside the shell and the impact of fluid
movement inertia on the wave velocity and amplitude are taken into consideration. In the case
of a shell filled with a viscous incompressible fluid, it is impossible to study deformation wave
models by qualitative analysis methods. This makes it necessary to apply numerical methods.
The numerical study of the constructed model is carried out by means of a difference scheme
analogous to the Crank – Nickolson scheme for the heat conduction equation. The amplitude
and velocity do not change in the absence of surrounding medium impact, construction damping
in longitudinal and normal directions, as well as in the absence of fluid impact. The movement
occurs in the negative direction, which means that the movement velocity is subsonic. The
numerical experiment results coincide with the exact solution, therefore, the difference scheme
and the modified Korteweg – de Vries – Burgers equation are adequate.
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