Email this article ASSESSMENT OF SUSTAINING COUNTER PRESSURE OF IMPROVER-INHABITED OILS CONTAINING ADDITIVES OF ZINC AND MOLYBDENUM DITHIOPHOSPHATES UNDER FRICTION IN BOUNDARY LUBRICATION MODE
- Authors: Ilya A. B.A.1, Samusenko V.D.2, Bolshakov A.N.3, Scherbakov Y.I.4
-
Affiliations:
- Institute of Mashine Science named after Blagonravov, RAS
- Institute of Machines Science named after A.A.Blagonravov of the Russian Academy of Sciences
- Institute for Machine Science named after A.A.Blagonravov
- Issue: No 10 (172) (2025)
- Pages: 40-48
- Section: Surface layer quality, contact interaction, friction and wear of machine parts
- URL: https://bakhtiniada.ru/2223-4608/article/view/349991
- DOI: https://doi.org/10.30987/2223-4608-2025-10-40-48
- ID: 349991
Cite item
Full Text
Abstract
The article presents an assessment of the bearing capacity of oils containing additives based on zinc dithiophosphates (DF-11, DF-11k) and molybdenum dithiophosphates (PAF-4) during friction under boundary lubrication conditions. These additives are key components of modern lubricants, which provide the necessary tribological properties under severe operating conditions. The effect of the metal in the composition of dialkyl dithiophosphates on their tribological characteristics, in particular, on the bearing capacity, was studied. The studies were carried out on a standard four-ball machine using MS-20 petroleum oil as a base medium. To assess the tribological characteristics, the RD50-531-85 method was used, which allows determining the parameters of the linear approximation of the dependence of wear intensity on contact pressure: wear coefficient (k) and bearing capacity p0. This approach provides a more in-depth analysis of the tribological properties of lubricants, taking into account contact pressures during wear. The obtained results showed that zinc-containing additives provide a significantly higher load-bearing capacity of the lubricating layer (1235 MPa for DF-11) compared to the molybdenum-containing additive (1038 MPa for PAF-4). This indicates that they form a stronger and more wear-resistant boundary film. At the same time, the molybdenum-based additive demonstrated better antifriction properties, showing the lowest friction coefficient. Thus, the study shows the difference in the functional action of the additives: zinc dithiophosphates act as highly effective antiwear components that increase the ultimate load, while molybdenum dithiophosphate manifests itself primarily as a friction modifier. The obtained results are important for the targeted development of oil formulations for specific operating conditions.
About the authors
Buyanovskiy Aleksandrovich Ilya A.
Institute of Mashine Science named after Blagonravov, RAS
Email: buyan37@mail.ru
ORCID iD: 0000-0003-0691-5095
SPIN-code: 1051-7401
Scopus Author ID: 7003449043
ResearcherId: A-4911-2019
professor, doctor of technical sciences
Vladimir Dmitrievich Samusenko
Institute of Machines Science named after A.A.Blagonravov of the Russian Academy of Sciences
Email: samusenkovd@gmail.com
ORCID iD: 0000-0001-8093-5372
candidate of technical sciences
Andrey Nikolaevich Bolshakov
Institute for Machine Science named after A.A.Blagonravov
Email: buyan37@mail.ru
ORCID iD: 0000-0003-2523-6565
Yuriy Ivanovich Scherbakov
Author for correspondence.
Email: buyan37@mail.ru
ORCID iD: 0009-0000-9786-3491
References
Митин И.В., Татур И.Р. Моторные масла. М.: Изд-во «Проспект». 2025. 432 с. Lubricants and Lubrication / Ed by J. Mang, W. Dressel. NY: John Willey and Son, Ltd: 2018. 944 c. Лашхи В.Л., Чудиновских А.Л. Физико-химические основы химмотологии моторных масел. М.: Издательский дом Недр. 2015. 355 с. Spikes H. The history and mechanisms of ZDDP // Tribology Letters. 2004. Т. 17. № 3. C. 469−489. Spikes H. Mechanisms of ZDDP // Tribology Letters. 2025. Т. 73. № 1. 38 р. Буяновский И.А., Самусенко В.Д. Дитиофосфаты металлов как трибологически активные присадки к смазочным маслам // Сборка в машиностроении, приборостроении. 2024. Т. 25. № 11. С. 501−507. Spikes H. Friction modifier additives // Tribology Letters. 2015. Т. 60. № 1. 5 р. Roache D.C., Devlin M., Li H. Mechanical properties of tribofilms formed by metal dithiophosphates // Tribology International. 2024. Т. 197. 109794 р. Zhang J. Boundary lubrication of ZDDP // Tribology Letters. 2021. Т. 69. 8 р. Sato K., Watanabe S., Sasaki S. High friction mechanism of ZDDP tribofilm based on in situ AFM observation of nanofriction and adhesion properties // Tribology Letters. 2022. Т. 70. № 3. 94 р. Ueda M., Keidrich A., Spikes H. ZDDP tribofilm formation on nonferrous surfaces // Tribology Online. 2020. Т. 15. № 5. 318 р. Chen Y., Renner P., Liang H. A review of current understanding in tribochemical reactions involving lubricant additives // Friction. 2023. Т. 11. № 4. Р. 489−512. Буяновский И.А. Развитие идей М.М. Хрущова о триботехнических испытаниях материалов применительно к изучению противоизносных свойств масел // Трение и износ. Т. 11. № 6. С. 1124−1132. Хрущов М.М. Исследование приработки подшипниковых сплавов и цапф. М.: Изд-во АН СССР. 1946. 160 с. Feng I. A new approach in interpreting the four-ball wear results // Wear. 1962. Т. 5. №. 4. С. 275−288. Большаков А.Н., Щербаков Ю.И. Трибологическое исследование дитиофосфатных присадок по РД 50-531-85 // Трибология: Труды XV Международной научно-технической конференции. М.: ИМАШ РАН, 2024. С. 24−25.
Supplementary files
