Development of a Micromechanic Theory of Crack Initiation Under High-Cycle Fatigue

Abstract

From the hint provided by extrusion and intrusion in fatigue specimen, a micromechanic model consisting of a thin slice R sandwiched in two thin slices P and Q is developed. P with positive initial shear stress slides forward in the forward loading, while the other Q with negative initial shear stress slides backward during the reversed loading. Micromechanic analysis shows that the positive slip in P relieves the positive shear stress not only in P, but also in Q. This helps Q to slide in the reversed loading. Similarly the negative slip in Q helps P to slide during the next forward loading. The micro stress fields generated by the alternate sliding in P and Q gives the ratchet mechanism in fatigue. Extrusion causes a tensile stress in R. This stress combining with other stress can activate a second slip systems of an aluminum single crystal. The macroscopic deformation & hysteresis loop are thus computed. The computed microstructures check amazingly well with the experimental fatigue data of aluminum single crystals by Zhai et al of Oxford University.

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Document Details

Document Type
Technical Report
Publication Date
Sep 20, 1999
Accession Number
ADA368833

Entities

People

  • T. H. Lin

Organizations

  • University of California, Los Angeles

Tags

Communities of Interest

  • Air Platforms

DTIC Thesaurus Topics

  • Aluminum
  • Composite Materials
  • Crystal Structure
  • Crystals
  • Finite Element Analysis
  • Materials
  • Materials Science
  • Mechanical Properties
  • Mechanics
  • Numerical Analysis
  • Shear Stresses
  • Stress Strain Relations
  • Stresses
  • Tensile Strength
  • Tensile Stress
  • Three Dimensional
  • Turbines

Readers

  • Electrical Engineering
  • Mechanical Engineering/Mechanics of Materials.
  • Structural Health Monitoring of Composite Structures.