Characterization of a 2205 Duplex Steel Modified with Boron Obtained via Powder Metallurgy

Stainless steels are commonly used when a good balance between mechanical properties and corrosion resistance is required. Usually, to increase wear resistance, hard particles are added (carbides, borides, nitrides, and others) to the more ductile matrix (ferrite or austenite). The addition of boron...

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Bibliographic Details
Published in:Steel research international 2023-12, Vol.94 (12), p.n/a
Main Authors: Morita Terceiro, Pedro, Soyama, Juliano
Format: Article
Language:English
Subjects:
2205 steels
Atomizing
Borides
Boron
Cold pressing
Corrosion resistance
Corrosive wear
Densification
Duplex stainless steels
Mechanical properties
Metal powders
Microhardness
Phase transitions
Powder metallurgy
Sintering
Sintering (powder metallurgy)
stainless steels
Steel
Temperature effects
Wear resistance
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Summary:Stainless steels are commonly used when a good balance between mechanical properties and corrosion resistance is required. Usually, to increase wear resistance, hard particles are added (carbides, borides, nitrides, and others) to the more ductile matrix (ferrite or austenite). The addition of boron to steels leads to the formation of primary and eutectic borides, which harden the material as solidified. Therefore, herein, the viability to prepare a modified 2205 duplex steel with 2.5 wt% of boron through powder metallurgy is investigated. The boron addition is performed in the atomization step. In addition, the effect of temperature in the sintering process is investigated, as well as the characterization of microstructure formation, phase transformations, and mechanical properties. The specimens are prepared from a prealloyed metal powder with three different granulometries: thick (250–500 μm), medium (106–180 μm), and thin powders (85% is observed with medium powder with an increase of nearly 40% in microhardness in comparison to the reference 2205 steel. The 2205 stainless steel is modified with boron added during the atomization step of a conventional powder metallurgy route achieving an optimal sintering temperature of 1200 °C for all three granulometries studied. However, the highest densification of >85% is observed with the medium powder with an increase of nearly 40% in microhardness in comparison to the reference 2205 steel.
ISSN:1611-3683
1869-344X
DOI:10.1002/srin.202300229