Tribological Behaviour of Low Temperature Plasma Assisted Carburized 316 L Steel Produced by L-PBF Technique

Alex Lanzutti; Francesco Sordetti; Michele Magnan; Emanuele Vaglio; Alessandra Varone; Roberto Montanari; Claudio Verona; Ekaterina Pakhomova

doi:10.4028/p-g3mBSH

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HomeMaterials Science ForumMaterials Science Forum Vol. 1105Tribological Behaviour of Low Temperature Plasma...

Tribological Behaviour of Low Temperature Plasma Assisted Carburized 316 L Steel Produced by L-PBF Technique

Abstract:

Austenitic stainless steels produced by Laser Powder Bed Fusion (L-PBF) are interesting materials because of their excellent corrosion resistance. Due to their relatively low hardness, the tribological response of these materials is poor, which limits their use in applications where control of wear degradation is important. Nevertheless, low-temperature plasma-assisted carburisation is an interesting process for improving the wear resistance of austenitic stainless steels, as has been observed for wrought materials. In fact, the increase in hardness is guaranteed by a surface layer of expanded austenite (S-phase) with a thin top layer of amorphous carbon. In this work, AISI 316 L, produced by the L-PBF technique, was carburised using 5 different plasma gas mixtures (by varying the CH4/H2 ratio) at 475°C for 7 hours. The samples obtained were then subjected to a detailed microstructural characterisation in order to obtain information on surface modification. The morphological features of the surface were examined by SEM observations in top view and in cross-section. The tribological performance was evaluated by pin-on-flat tests (alumina sphere as counter-material) with 2 different applied loads and a stroke length of 5 mm. Friction coefficient, wear rate (stylus profilometer) and wear mechanisms (SEM) were also evaluated. Preliminary results show an increase in wear resistance of all plasma treated materials compared to the untreated material. The improved tribological performance was discussed in relation to the abrupt increase in surface hardness.

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Periodical:

Materials Science Forum (Volume 1105)

Pages:

141-146

DOI:

https://doi.org/10.4028/p-g3mBSH

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Online since:

November 2023

Authors:

Alex Lanzutti*, Francesco Sordetti, Michele Magnan, Emanuele Vaglio, Alessandra Varone, Roberto Montanari, Claudio Verona, Ekaterina Pakhomova

Keywords:

AISI 316 L, Laser Powder Bed Fusion, Low Temperature Plasma Assisted Carburizing, Wear

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