Researching Conditions of Thermomechanical Process under Semihot Forging

Mihail Mihailovich Radkevich; Dmitrii Fomin; Alexandr Gluchihin

doi:10.4028/www.scientific.net/KEM.822.165

Paper Titles

The Method for Determining the Friction Coefficient in Relation to the Hot Forging Processes
p.137

Improving the Quality of Parts Produced by Bending in a Die with an Elastic Element
p.144

Investigation of the Hammer Forging Process of Large-Sized Turbine Blades of Stainless Steel
p.150

Hot Axial Rotary Forging of Flanges Standard EN 1092
p.159

Researching Conditions of Thermomechanical Process under Semihot Forging
p.165

Influence of Contact Friction on the Kinematics of Metal Flow during Equal Channel Angular Pressing
p.171

Determination of Boundary Parameters of Pipelines Elbows Blanking Elements Made from Titanium Alloy Ti-4Al-2Mn and Steel AISI 304
p.178

Mechanical Properties of Bars Produced by Hot Extrusion of Magnesium Shavings
p.185

Manufacturing and Properties of Radiation Resistance Aluminum Alloys and Composites with Addition of Gadolinium
p.195

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Researching Conditions of Thermomechanical Process under Semihot Forging

Abstract:

Questions of thermomechanical parameters appointment under the semihot (warm) forging of metal preforms were considered. The international experience was analyzed as well. Economically effective thermomechanical conditions under semihot/warm forging, which is capable to provide a high complex of the mechanical properties of steel, are offered. The economical effect after the process integration to the industry was considered.

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Periodical:

Key Engineering Materials (Volume 822)

Pages:

165-170

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.822.165

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Online since:

September 2019

Authors:

Mihail Mihailovich Radkevich, Dmitrii Fomin*, Alexandr Gluchihin

Keywords:

Conditions of the Thermomechanical Process, Mechanical Properties, Semihot Forging, Strengthening, Warm Forging

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References

[1] Dahme M. Forged Components. Germany: Egger, Landsberg am Lech. – (2011).

Google Scholar

[2] Kugler H. Umformtechnik. Umformen metallischer konstruktionswerkstoffe. Germany: Fachbuchverlag Leipzig im Carl Hanser Verlag. (2009).

DOI: 10.3139/9783446422223

Google Scholar

[3] Szebsdat O., Apholt H. Presentation of the forging industry. Germany: Infostelle. (2008).

Google Scholar

[4] Rudskoi, A.I., Kodzhaspirov, G., Kliber, J., Apostolopoulos, Ch. Thermomechanical processing of steels and alloys physical foundations, resource saving technique and modelling. 2018. Materials Physics and Mechanics.

Google Scholar

[5] Aksenov, L.B., Kunkin, S.N. Hot orbital forging by tool with variable angle of inclination. 2018. Lecture Notes in Mechanical Engineering.

DOI: 10.1007/978-3-319-72929-9_1

Google Scholar

[6] Aksenov, L.B., Kunkin, S.N. Rotary forging of hollow components with flanges. 2015. Lecture Notes in Mechanical Engineering.

DOI: 10.1007/978-3-319-53363-6_1

Google Scholar

[7] Rudskoi, A., Kodzhaspirov, G. High temperature thermomechanical processing of austenitic-ferritic steel. 2018. METAL 2018 - 27th International Conference on Metallurgy and Materials, Conference Proceedings.

DOI: 10.37904/metal.2021.4097

Google Scholar

[8] Matveev, M.A., Kolbasnikov, N.G., Kononov, A.A. Refinement of the structure of microalloyed steels under plastic deformation near the temperatures of polymorphic transformation. 2017 Metal Science and Heat Treatment.

DOI: 10.1007/s11041-017-0128-7

Google Scholar

[9] Radkevich, M.M. Features of plastic deformation zone forming under conditions of deformational-thermal working. 2001. Kuznechno-Shtampovochnoe Proizvodstvo (Obrabotka Metallov Davleniem).

Google Scholar

[10] Kodzhaspirov, G., Rudskoi, A. Simulation of dynamic recrystallization of steels and alloys during rolling and forging through the use of FEM and experimental planning methods. 2017. METAL 2017 - 26th International Conference on Metallurgy and Materials, Conference Proceedings.

Google Scholar