Methods of Accounting for Temperature and Strain Rate Variation in Multilevel Constitutive Models of Metal Deformation (Analytical Review)

Technological metal forming processes involving hot and superplastic deformation are sensitive to temperature and strain rate. This is because inelasticity mechanisms operate in different ways under different conditions, leading to the formation of different structures and therefore different effect...

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Bibliographic Details
Published in:Physical mesomechanics 2024-04, Vol.27 (2), p.133-151
Main Authors: Shveykin, A. I., Vshivkova, A. A., Trusov, P. V.
Format: Article
Language:English
Subjects:
Classical Mechanics
Constitutive models
Deformation
Deformation analysis
Deformation effects
Deformation mechanisms
Elasticity
Energy consumption
Materials Science
Mathematical models
Mechanical properties
Metal forming
Multilevel
Physical properties
Physics
Physics and Astronomy
Solid State Physics
Strain rate
Superplastic deformation
Superplasticity
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Summary:Technological metal forming processes involving hot and superplastic deformation are sensitive to temperature and strain rate. This is because inelasticity mechanisms operate in different ways under different conditions, leading to the formation of different structures and therefore different effective physical and mechanical properties of the material. Optimal temperature and strain rate conditions for the forming process which provide improved performance of the resulting products with acceptable energy consumption (or, conversely, minimum energy consumption with acceptable performance characteristics) can be most effectively determined by mathematical modeling. The key elements of the latter are constitutive models for describing the behavior of the material (physical equations), which account for the influence of temperature and strain rate on various mechanisms of inelastic deformation. Such constitutive models can be most effectively developed using a multilevel approach based on the introduction of internal variables, crystal plasticity, and an explicit description of the material structure and physical deformation mechanisms. There are many works that propose multilevel mathematical models of metals that somehow explicitly account for the temperature and strain rate effects on inelastic deformation. Based on physical considerations, this analytical review defines the most promising approach to constructing multilevel constitutive models with comprehensive consideration of the temperature and strain rate effects.
ISSN:1029-9599
1990-5424
DOI:10.1134/S1029959924020036