Comparison of various C2Hx for high‐temperature lubrication by in situ pyrolysis

The effectiveness of ‘far‐field’ vapour‐phase lubrication, in which areas of a bearing surface that are cycled through the contact are exposed to vapour while outside the contact, has been demonstrated in both sliding and combined roll slide tests using acetylene vapours to deposit pyrolytic graphite. Friction coefficients as low as μ = 0.008 have been measured for steel at 540°C with far‐field acetylene concentrations as low as 5%. Effective vapour‐phase lubrication depends on solid lubricant deposition that exceeds the contact's capacity to remove solid lubricant through wear. While the rate of removal is increased by increasing the sliding velocity, in far‐field vapour‐phase lubrication the rate of lubricant deposition, and therefore the lubrication effectiveness, is augmented by increased areas available for far‐field deposition, such as those provided by performing wear tests with increased wear‐track diameters. These geometric concepts may be considered in rolling‐element bearing and gear set applications where vapour‐phase lubrication is to be employed.

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Geometric effects in high‐temperature vapour‐phase lubrication using hydrocarbon feed gases

Gardner

Sawyer

Blanchet

2002

Lubrication Science

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A fractional coverage model for gas–surface interaction in reciprocating sliding contacts

Sawyer

Dickrell

2004

Wear

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Vapor-Phase Lubrication in Combined Rolling and Sliding Contacts: Modeling and Experimentation

Sawyer

Blanchet

2000

Journal of Tribology

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The in situ vapor-phase lubrication of M50 steel, in combined rolling and sliding contacts at 540°C using nitrogen atmospheres containing acetylene, is achieved. Acetylene partial pressures of 0.05 atmospheres are capable of providing continuous lubrication to combined rolling and sliding contacts through pyrolytic carbon deposition. In these tests, friction coefficients as low as μ=0.01 are found for contacts at 2.0 m/s rolling speed, 10 cm/s sliding speed, 100 N load (1.3 GPa Hertzian contact pressure), and ambient temperature of 540°C, with even lower values observed at more modest sliding speeds. One example of a model for vapor phase lubrication of combined rolling and sliding contacts is developed which predicts the lubricant steady-state fractional coverage of the contact surfaces, and from this makes friction coefficient predictions using a linear rule-of-mixture. Friction coefficient responses to step changes in acetylene partial pressure, sliding speed, and disk wear-track diameter are measured. Increased partial pressure of acetylene and increased area available for deposition are observed to be beneficial, while increased sliding speed is detrimental to lubrication performance. Shapes and trends of steady-state friction coefficient versus acetylene partial pressure, sliding speed, and disk wear-track diameter are described and curve-fit by the model. In combined rolling and sliding this example model predicts large regions of operating conditions over which friction coefficient is independent of rolling speed, as well as regions of independence of vapor partial pressure. In the special case of pure sliding, a region of friction coefficient independence of a ratio of partial pressure to sliding speed and another region of independence of a ratio of partial pressure to the product of sliding speed and normal load are predicted.

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Comparison of various C₂H_x for high‐temperature lubrication by in situ pyrolysis

Cited by 4 publications

References 9 publications

Geometric effects in high‐temperature vapour‐phase lubrication using hydrocarbon feed gases

Geometric effects in high‐temperature vapour‐phase lubrication using hydrocarbon feed gases

A fractional coverage model for gas–surface interaction in reciprocating sliding contacts

Vapor-Phase Lubrication in Combined Rolling and Sliding Contacts: Modeling and Experimentation

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