The effect of post aging on wear properties of a plasma nitrided ferromagnetic steel under DC magnetic field

Plasma nitriding is an effective surface treatment to improve unsatisfactory wear properties of machine elements. Such machine elements may also subject to magnetic fields in many industrial applications. Therefore, AISI 4140 ferromagnetic steel samples were plasma nitrided. Then, the samples were q...

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Bibliographic Details
Published in:Wear 2015-05, Vol.332-333, p.988-994
Main Authors: Yetim, A.F., Kovacı, H., Yildiz, F., Bayrak, O., Çelik, A.
Format: Article
Language:English
Subjects:
Chromium molybdenum steels
Ferromagnetism
Friction
High strength steels
Ion nitriding
Magnetic field
Magnetic fields
Plasma nitriding
Plasma post-aging
Sliding wear
Steels
Wear
Wear Debris
Wear resistance
Wear tests
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Summary:Plasma nitriding is an effective surface treatment to improve unsatisfactory wear properties of machine elements. Such machine elements may also subject to magnetic fields in many industrial applications. Therefore, AISI 4140 ferromagnetic steel samples were plasma nitrided. Then, the samples were quenched in water and then post-aged at a temperature of 400°C for 30 and 120min in plasma environment. Reciprocating wear tests were performed under different oriented DC magnetic field to determine wear behavior of the samples. It was obtained that the magnetic field and its orientation during wear test were the most effective parameters on wear behavior. It was observed that post-aged samples showed better wear resistance and lower friction coefficient values than the merely nitrided samples. Hard Fe16N2 precipitations were formed in the nitrided layer after post-aging treatment and their amount increased with magnetic field. This gave rise to improvement the wear resistance. •Magnetization effected tribological properties of all the samples.•Magnetic field notably affected both friction and wear properties.•Cubic-like debris formed under parallel magnetic field to the sliding direction.•Perpendicular magnetic field caused to form fine and spherical debris.
ISSN:0043-1648
1873-2577
DOI:10.1016/j.wear.2015.02.035