3-dimensional solutions from two variables

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Abstract

In this paper, we consider stationary 3-dimensional equations of ideal plasticity with the Mises flow condition. The material is assumed to be incompressible. The case when all three components of the velocity vector and hydrostatic pressure depend only on two coordinates x, y is studied in detail. For this case, a new name is introduced – 3-dimensional solutions from two variables, to distinguish it from the generally accepted two-dimensional state, when only two components of the velocity vector and hydrostatic pressure differ from zero. It is proved that the system admits, in the sense of S. Lie, a Lie algebra of dimension 10. It is shown that are all 3-dimensional solutions from two variables a superposition of the plane stress state and plastic torsion around the z-axis. Two invariant solutions of the equations describing the 3-dimensional deformed state are constructed. The first solution can be used to describe plastic flows between two rigid plates that approach at different speeds. The second solution is used to describe the stress-strain state of the material inside a flat channel formed by converging plates.

About the authors

Sergei I. Senashov

Siberian State University of Science and Technology

Author for correspondence.
Email: sen@sibsau.ru

Dr. Sc, Professor, Head of the Department of IES

Russian Federation, 31, Krasnoyarskii rabochii prospekt, Krasnoyarsk, 660037

Irina S. Savostyanova

Siberian State University of Science and Technology

Email: savostyanova@sibsau.ru

Cand. Sc., Associate Professor of the Department of IES

31, Krasnoyarskii rabochii prospekt, Krasnoyarsk, 660037

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