Thermomechanical Hardening of Steels

Vladimir P. Shveikin

doi:10.4028/www.scientific.net/SSP.284.507

Paper Titles

The Possibility of Obtaining Electrical Steel with Texture {100} <001>
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Thermal Cycles and Peculiar Properties of Austenite Decomposition when Laser-Hybrid Welding Steel of K60 Strength Class
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Thermal Processes Simulation during Processing Bevel Gears
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The Influence of Heat Treatment on the Size of the Carbide Inclusions and Hardness of Multilayer Composite Material ZD-0803
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Thermomechanical Hardening of Steels
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To the Influence of the Deformation Speed on Hardening Process during the Cold Sheet Forming
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To the Question of Evaluation of the Anode Voltage Drop
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Using of Smoothed Particle Hydrodynamics Method for Constructing a Mathematical Model of Electron-Beam Surfacing Process
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HN45VMTYUBR Alloy: Impact of Laser Beam Welding Modes on Microstructure and Distribution of Alloying Elements in the Seam
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HomeSolid State PhenomenaSolid State Phenomena Vol. 284Thermomechanical Hardening of Steels

Thermomechanical Hardening of Steels

Abstract:

The methods of the hot working of metals by pressure are discussed. The features of the hot plastic deformation of the metal which determine the formation of the structure and properties of steel are noted. The definition of thermomechanical treatment is given. The definitions of a variety of thermomechanical and high-temperature thermomechanical processes are given. The features of the thermomechanical treatment of steels toughened to martensite are discussed. The temperature, deformation-velocity and time parameters of high-temperature thermomechanical processing are given. Their influence on the structure and properties of steels is analyzed

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Periodical:

Solid State Phenomena (Volume 284)

Pages:

507-512

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.284.507

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Online since:

October 2018

Authors:

Vladimir P. Shveikin*

Keywords:

Ductility, High-Temperature Thermomechanical Treatment, Metal Working with Pressure, Strength, Structure, Thermomechanical Hardening, Viscosity

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