Improving the tribological properties of AISI M50 steel using Sns/Zno solid lubricants

Improving the tribological properties of AISI M50 steel using Sns/Zno solid lubricants

Motivated by enhancing the tribological behavior of M50 steel (M), two nanoscale self-lubricants (SnS and/or ZnO) have been incorporated with M50 matrix to form two new matrix composites: M50 + 10%SnS (MS) and M50 + 10% SnS+10%ZnO (MSZ). The samples were fabricated using spark plasma sintering machi...

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Veröffentlicht in:Journal of alloys and compounds 2020-04, Vol.821, p.153494, Article 153494
Hauptverfasser: Elsheikh, Ammar H., Yu, Jingui, Sathyamurthy, Ravishankar, Tawfik, M.M., Shanmugan, S., Essa, F.A.
Format: Artikel
Sprache:eng
Schlagworte:
Bearing steels
Carbonates
Dry friction
Friction reduction
High speed tool steels
M50 steel
Morphology
Plasma sintering
Powder metallurgy
Silicon nitride
Sliding
Solid lubricant
Solid lubricants
Spark plasma sintering
Tin sulfide
Tribology
Zinc oxide
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container_end_page
container_issue
container_start_page 153494
container_title Journal of alloys and compounds
container_volume 821
creator Elsheikh, Ammar H.
Yu, Jingui
Sathyamurthy, Ravishankar
Tawfik, M.M.
Shanmugan, S.
Essa, F.A.
description Motivated by enhancing the tribological behavior of M50 steel (M), two nanoscale self-lubricants (SnS and/or ZnO) have been incorporated with M50 matrix to form two new matrix composites: M50 + 10%SnS (MS) and M50 + 10% SnS+10%ZnO (MSZ). The samples were fabricated using spark plasma sintering machine (SPS). The fabricated samples were tested against silicon nitride ceramics ball on a pin-on-disk tribometer under wide ranges of loads (3–12 N), sliding speeds (0.2–0.8 m/s), and temperatures (RT – 450 °C) to investigate the tribological behavior of the samples. FESEM, EDS, EPMA, XPS, and XRD tests were carried out to explore the morphology of worn surface and recognize the anti-wear and friction-reduction mechanisms of the samples. MSZ recorded the least friction (0.22) compared to MS (0.31) and M (0.58) under severe conditions (12 N load and 0.8 m/s sliding speed at temperature of 450 °C). The synergistic action between SnS and ZnO as well as produced lubricious oxides, molybdenites, and carbonates on interacting surfaces is the main reason to enhance the tribological characteristics of MSZ samples. •Effects of different loads on tribological behavior of M50 composites.•Effects of different sliding speeds on tribological behavior of M50 composites.•Effects of different temperatures on tribological behavior of M50 composites.•Effects of ZnO–SnS hybrid solid lubricants on tribological behavior of M50.•Major lubrication mechanisms of M50 composites are discussed in details.
doi_str_mv 10.1016/j.jallcom.2019.153494
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The samples were fabricated using spark plasma sintering machine (SPS). The fabricated samples were tested against silicon nitride ceramics ball on a pin-on-disk tribometer under wide ranges of loads (3–12 N), sliding speeds (0.2–0.8 m/s), and temperatures (RT – 450 °C) to investigate the tribological behavior of the samples. FESEM, EDS, EPMA, XPS, and XRD tests were carried out to explore the morphology of worn surface and recognize the anti-wear and friction-reduction mechanisms of the samples. MSZ recorded the least friction (0.22) compared to MS (0.31) and M (0.58) under severe conditions (12 N load and 0.8 m/s sliding speed at temperature of 450 °C). 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The samples were fabricated using spark plasma sintering machine (SPS). The fabricated samples were tested against silicon nitride ceramics ball on a pin-on-disk tribometer under wide ranges of loads (3–12 N), sliding speeds (0.2–0.8 m/s), and temperatures (RT – 450 °C) to investigate the tribological behavior of the samples. FESEM, EDS, EPMA, XPS, and XRD tests were carried out to explore the morphology of worn surface and recognize the anti-wear and friction-reduction mechanisms of the samples. MSZ recorded the least friction (0.22) compared to MS (0.31) and M (0.58) under severe conditions (12 N load and 0.8 m/s sliding speed at temperature of 450 °C). 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subjects Bearing steels
Carbonates
Dry friction
Friction reduction
High speed tool steels
M50 steel
Morphology
Plasma sintering
Powder metallurgy
Silicon nitride
Sliding
Solid lubricant
Solid lubricants
Spark plasma sintering
Tin sulfide
Tribology
Zinc oxide
title Improving the tribological properties of AISI M50 steel using Sns/Zno solid lubricants
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