On the kinetic physical and mathematical metal creep theory controlled by thermally activated dislocation sliding

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Abstract

The rationale for the prospects of using the physical and mathematical theory of metal creep in creep computations is carried out by a comparative analysis of the classical phenomenological and physical and mathematical metal creep theories. On the example of the description by both theories specific results of non-stationary creep experiments and analysis of the theories equations it is shown that implementing the physical kinetic equation for the actual structural parameter of the material, namely the scalar density of immobile dislocations, makes the physical and mathematical theory universal for solving non-stationary metal creep problems with multiaxial loading, when change, including abruptly, temperature, forces and loading rates.

About the authors

V. M. Greshnov

Ufa University of Science and Technology

Author for correspondence.
Email: Greshnov_VM@list.ru
Russian Federation, Ufa

R. I. Shaikhutdinov

Ufa University of Science and Technology

Email: shaykhutdinovri@gmail.com
Russian Federation, Ufa

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