Methods for Solving the Viscoelasticity Equations for Cylinder and Sphere Problems

Abstract

This report considers techniques used to solve the Navier field equations of viscoelasticity in the Kelvin-Voigt or Maxwell models, for cylindrical of spherical geometries. Introducing scalar and vector potentials into the viscoelasticity equations formulation, ultimately yields telegraph-type partial differential equations governing those potentials. For harmonic time- dependence, these reduce to scalar and vector Helmholtz's equations with complex propagation constants. These constants are shown to be related to the viscoelastic material-constants in a more or less complicated fashion depending on the viscoelastic model used. The stresses, strains and displacements are then found from these potentials for a dozen cases of interest in those two coordinate systems. The formulation resembles that of electrodynamics in a Coulomb gauge. The above information is vital to set-up and solve various kinds of boundary-value-problems of dynamic viscoelasticity which appear when studying cases of acoustic scattering from sound-absorbing structures.

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Document Details

Document Type
Technical Report
Publication Date
Mar 22, 1976
Accession Number
ADA025302

Entities

People

  • G. C. Gaunaurd

Organizations

  • Naval Ordnance Laboratory

Tags

Communities of Interest

  • Advanced Electronics
  • Air Platforms
  • Biomedical
  • Energy and Power Technologies
  • Weapons Technologies

DTIC Thesaurus Topics

  • Acoustic Scattering
  • Artificial Intelligence
  • Boundary Value Problems
  • Computational Science
  • Coordinate Systems
  • Differential Equations
  • Elastic Properties
  • Equations
  • Fluid Mechanics
  • Geometry
  • Mathematical Analysis
  • Mechanics
  • Navy
  • Partial Differential Equations
  • Theorems
  • Time Dependence
  • Wave Equations

Fields of Study

  • Mathematics

Readers

  • Calculus or Mathematical Analysis
  • Structural Dynamics.