Method for the Determination of Rational Constructional and Technological Parameters for the Processes of Powder Materials Forming

Anatoliy Mikhailov; Yevgenii Shtefan; Oleg Mikhailov; Mikhail Shtern

doi:10.4028/p-N63Szt

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Effect of Individual Alloying Addition on the Microstructure and Creep Behavior of Squeeze Cast AZ91 Magnesium Alloy
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Method for the Determination of Rational Constructional and Technological Parameters for the Processes of Powder Materials Forming
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Optimization and Evaluation of Mechanical and Electrochemical Properties of Ferritic Stainless Steel Welding Using Taguchi Design
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Peculiarities Formation of Welded Joints under the External Electromagnetic Influence
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 973Method for the Determination of Rational...

Method for the Determination of Rational Constructional and Technological Parameters for the Processes of Powder Materials Forming

Abstract:

The main theoretical aspects of porous and powder materials technological processing is worked out. The proposed material model is based on: - the four-parameter plasticity theory, which reflect the influence of porosity, resistance and the presence of dilatancy of solid phase deformation regime; - the dissipative potential and the load surface expression, that allow to take account such materials elastic - viscous - plastic properties; - the solid phase energy deformation speed with its subsequent over the representative element volume averaging. The peculiarity of this model is that the equilibrium flow concept elastic-viscous-plastic material is an alternative to its elastic-plastic deformation. The proposed equations are suitable for their effective practical using for digital models creation that based on existent software for the of equilibrium processes of compact materials deformation finite–element analysis. The practical use of the proposed methodologies made it possible to determine: - the regularities of the different modules material layers interaction during stamping of bimetallic blanks with an conical working surface; - the porosity distribution over the product volume at the final stage of radial extrusion of the bushings with an internal flange; - the effect of powder material decompression during reverse extrusion of cylindrical products.

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Periodical:

Key Engineering Materials (Volume 973)

Pages:

53-60

DOI:

https://doi.org/10.4028/p-N63Szt

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Online since:

February 2024

Authors:

Anatoliy Mikhailov, Yevgenii Shtefan, Oleg Mikhailov*, Mikhail Shtern

Keywords:

Bimetallic Blanks Stamping, Elastic-Viscous-Plasticity, Load Surface, Mathematical Simulation, Mechanical Energy Dissipation, Non-Equilibrium Forming Process, Porosity, Porous Materials, Powders, Radial Extrusion, Representative Element, Reverse Extrusion

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References

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