The Micromechanic Theory of Constitutive Relations of Polycrystalline Solids

Abstract

This research is to derive the macroscopic multi-axial stress-strain and stress-strain-time relations of metals from those of the component crystals. Since the macroscopic stress-strain relation depends on the grain size, the component crystal properties are also dependent on grain size. Hence the component crystal stress-strain relation is here derived from the uniaxial polycrystal tests. This automatically takes care of the grain size effect. The same approach is used to derive the macroscopic stress-strain-time relation (creep) of metals. In this derivation, the conditions of mechanics i.e., the condition of equilibrium, and the continuity of displacement are fully satisfied. Hence the discrepancy between the calculated and experimental results is likely due to the error in representation of the component crystal characteristics. Recently Bassani (1990) and Wu et. al., (1990) have compressed a single crystal to activate a primary slip system, unloaded this crystal, then reoriented and compressed to activate a second slip system. He found the critical shear stress of the second system increases rapidly, i.e., high rate of hardening. This characteristic is not shown in a single crystal under a tensile loading. In the previous physical theories, the stress-strain relations of the component crystals were calculated from the polycrystal tensile test data (Lin, 1971) and this high hardening rate was not encountered. In the present study, this high hardening rate is considered. It is found that the agreement between the calculated and experimental results is much further improved.

Document Details

Document Type

Technical Report

Publication Date

Dec 24, 1991

Accession Number

ADA251506

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