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Constitutive Equations For The Rate Dependent Deformation Of Metals At Elevated Temperatures

Constitutive Equations for High-Temperature Deformation of Metals

Background

Constitutive equations play a crucial role in analyzing the rate-dependent deformation of metals at elevated temperatures. These equations provide a framework for understanding and predicting the material's behavior under various loading conditions.

Early Research

In 1985, the International Journal of Plasticity published a study that proposed approximate constitutive equations for hot-working analysis of metals. These equations considered the effects of homologous temperatures above 0.5. Other research has explored the impact of deformation rate, mode, and temperature on the constitutive equations for metals. A 2-parameter viscosity function has been proposed that promotes a maximum change in viscosity across multiple deformation modes.

Modern Developments

Recent advancements in constitutive equations have focused on developing accurate models with minimal parameters. A variable-order fractional model has been proposed to establish a concise equation that captures the rate-dependent deformation characteristics of soft materials. FEM software has also been updated to incorporate advanced constitutive equations. The commercial software Marc, for example, has implemented a constitutive equation that reflects the nonlinear relationship between flow stress and process variables.

Applications

Constitutive equations have practical applications in various industries, including: * Analysis of metal forming processes at elevated temperatures * Design of metal components that operate under extreme conditions * Understanding the behavior of metallic materials in high-temperature applications Accurately predicting the deformation of metals is essential for designing safe and efficient structures, components, and processes.


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