Effect of Aluminum on the Structure and Mechanical Properties of Austenitic Steels

The works on the structure and mechanical properties of aluminum-alloyed austenitic steels are analyzed. Aluminum in aging high-nitrogen Cr–Mn–Ni–V nonmagnetic steels is shown to decrease the strength due to a decrease in the amount of dispersed VN nitrides having precipitated during aging because o...

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Published inRussian metallurgy Metally Vol. 2021; no. 9; pp. 1093 - 1101
Main Authors Blinov, V. M., Bannykh, I. O., Lukin, E. I., Blinov, E. V., Samoilova, M. A., Chernenok, D. V.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.09.2021
Springer Nature B.V
Subjects
Aging
Aging (metallurgy)
Alloying
Aluminum
Austenitic stainless steels
Case hardenability
Chemistry and Materials Science
Chromium
Copper
Core hardenability
Ferromagnetism
Intermetallic compounds
Manganese steels
Materials Science
Mechanical properties
Metallic Materials
Nickel aluminides
Nickel base alloys
Nickel compounds
Nitrides
Nitriding
Precipitation hardening steels
Thickness
Vanadium carbide
Wear resistance
nitrogen
carbon
carbides
vanadium
austenitic steel
aluminum
nitrides
structure
mechanical properties
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Summary:The works on the structure and mechanical properties of aluminum-alloyed austenitic steels are analyzed. Aluminum in aging high-nitrogen Cr–Mn–Ni–V nonmagnetic steels is shown to decrease the strength due to a decrease in the amount of dispersed VN nitrides having precipitated during aging because of the formation of coarse AlN particles hard to dissolve on quenching heating. An additional increase in the strength of aging nonmagnetic Mn–Ni–V–C steels is reached by their alloying with aluminum, which does not form hard to dissolve compounds with carbon. A significant increase in the surface hardness and the wear resistance during nitriding is reached as a result of separate or complex alloying of Mn–Ni–V steels with chromium up to 3% and aluminum up to 1.2%, which increase the nitrided layer thickness. The best combination of the properties of the nitrided layer is achieved after nitriding these steels containing 2.5–3.5% V at 700°C (12 h) in a 80% N 2 + 20% HN 3 medium. In this case, the hardening of the core during aging is related to the precipitation of VC carbides, and that of the nitrided layer, to the formation of VN nitrides. A significant increase in the volume fraction of strengthening phases in manganese steels is reached by complex alloying with Al, Ni, Cu, and V in the amounts that provide the simultaneous precipitation of the VC carbide and NiAl intermetallics during aging. Nonmagnetic 50G17N10Yu4F2 steel with a combined carbide–intermetallic hardening is highly competitive in strength (σ u > 1600 MPa, σ 0.2 > 1400 MPa) with high-strength 18Kh2N4VA ferromagnetic steels and significantly surpasses the well-known aging nonmagnetic high-nitrogen alloys.
ISSN:0036-0295
1555-6255
1531-8648
DOI:10.1134/S0036029521090044