Investigation into the wear behaviour of Tribaloy 400C during rotation as an unlubricated bearing at 600 °C

▶ Wear properties of Tribaloy 400C was investigated in a bespoke bearing rig at 600 °C. ▶ Stable wear protective oxide films often referred to as ‘glazes’ were formed. ▶ Six stages were identified in the formation of the ‘glazes’. ▶ During the formation of the ‘glazes’ discrete oxide films were form...

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Bibliographic Details
Published inWear Vol. 269; no. 11; pp. 763 - 769
Main Authors Wood, P.D., Evans, H.E., Ponton, C.B.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 28.10.2010
Elsevier
Subjects
Applied sciences
Bearings
Exact sciences and technology
Friction, wear, lubrication
Glaze
High temperature wear
Machine components
Mechanical engineering. Machine design
Tribaloy 400C
Tribochemistry
Tribochemistry
Tribaloy 400C
Glaze
High temperature wear
Bearings
Transient response
Oxide layer
Bearing(mechanics)
Rotation speed
Cobalt
Dry friction
Film failure
Superalloy
Chromium oxide
Wear
Groove
Oxidation
Diffusion
Protective coatings
Tribology
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Summary:▶ Wear properties of Tribaloy 400C was investigated in a bespoke bearing rig at 600 °C. ▶ Stable wear protective oxide films often referred to as ‘glazes’ were formed. ▶ Six stages were identified in the formation of the ‘glazes’. ▶ During the formation of the ‘glazes’ discrete oxide films were formed within them. ▶ Eventually the ‘glazes’ were composed of a uniform distribution of oxides. The wear behaviour of a cobalt-based superalloy, Tribaloy 400C, was studied during self-mating rotational sliding in a specially constructed bearing rig at 600 °C between 2 min and 12 h at a rotation speed of 3 ms −1. Stable wear protective oxide films often referred to as ‘glazes’ were formed with their coverage of the wear scar increasing with time. Six stages were identified in the formation of the wear protective oxide films: (i) transient oxidation to form a mixed oxide layer, (ii) preferential oxidation of the chromium to form a chromium oxide layer at the substrate interface, (iii) removal of this layer and compaction onto the surface, (iv) diffusion of mainly Co and Mo cations to the surface through the chromium oxide forming an oxidised layer above it, (v) slow breakdown and formation of the oxide films with further diffusion of mainly Co and Mo to the surface to form Co and Mo dominated layers on top a mixed Co, Cr, Si and Mo oxide film, and (vi) further breakdown and formation of the oxide film to form a uniform distribution of elements within the wear protective oxide film.
ISSN:0043-1648
1873-2577
DOI:10.1016/j.wear.2010.08.003