Elastothermodynamic Damping in Composite and Cracked Media

Abstract

When a composite material is subjected to a stress field, different regions undergo different temperature fluctuations due to the well-known thermoelastic effect. As a result irreversible heat conduction occurs, and entropy is produced which is manifested as a conversion of mechanical energy into heat. Moreover, the changes in temperature produce a thermal strain that is out of phase with the stress, thus converting mechanical energy into heat, i.e. work is lost. We define this process as elastothermodynamic damping. Herein, using the linear one-way coupled theory of elastothermodynamic relaxation, the elastothermodynamic damping of composite and cracked media is examined. Two equivalent descriptions of elastothermodynamic damping are first established: (1) the mechanical description and (2) the entropic description. An integral-transform technique is then developed to solve for the temperature field of a general composite medium with arbitrary heat generation. With this solution, a general expression for the damping of the composite material is derived.

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Document Details

Document Type
Technical Report
Publication Date
Dec 01, 1995
Accession Number
ADA334876

Entities

People

  • Joseph E. Bishop

Organizations

  • Air Force Research Laboratory

Tags

Communities of Interest

  • Air Platforms
  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Air Force
  • Applied Mechanics
  • Cartesian Coordinates
  • Composite Materials
  • Differential Equations
  • Fiber Reinforced Composites
  • Heat Energy
  • Materials
  • Mechanical Properties
  • Mechanics
  • Metal Matrix Composites
  • Modulus Of Elasticity
  • Polymer Matrix Composites
  • Temperature Gradients
  • Thermal Conductivity
  • Thermal Expansion
  • Thermodynamics

Fields of Study

  • Engineering

Readers

  • Energy Conservation and Renewable Energy Engineering.
  • Fluid Dynamics.
  • Reinforced Composite Materials