Preventing electrically induced subsurface initiated pitting failures (incl. WSF, WEC, WEA) with copper based lubricant additives
Premature bearing failures in large electric machines such as wind turbines and locomotives are often caused by White Etching Cracks (WEC), White Etching Areas (WEA), and White Structure Flaking (WSF)—phenomena that, despite extensive study, remain not fully understood. This work introduces a new hy...
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| Format: | Article |
| Language: | English |
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Frontiers Media S.A.
2025-05-01
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| Series: | Frontiers in Mechanical Engineering |
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| Online Access: | https://www.frontiersin.org/articles/10.3389/fmech.2025.1585472/full |
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| author | Sergei Mamykin Marc Ingram Leyla Alieva Varvara Privalova |
| author_facet | Sergei Mamykin Marc Ingram Leyla Alieva Varvara Privalova |
| author_sort | Sergei Mamykin |
| collection | DOAJ |
| description | Premature bearing failures in large electric machines such as wind turbines and locomotives are often caused by White Etching Cracks (WEC), White Etching Areas (WEA), and White Structure Flaking (WSF)—phenomena that, despite extensive study, remain not fully understood. This work introduces a new hypothesis of WEC, WEA and WSF formation combining Garkunov’s scientific discoveries of “hydrogen wear of metals” and the “wearlessness effect” with the existing knowledge and offers a possible solution. To test this hypothesis and solution, a prototype lubricant containing oil-soluble copper salts was evaluated using an electrically induced WEC test on a three ring-on-roller tribometer. The test applied high contact pressures and direct current to simulate operating conditions, followed by subsurface serial sectioning to examine material degradation. The results showed that the reference lubricant exhibited typical WEC and WEA damage, while the copper-based candidate lubricant prevented such failures entirely. This outcome supports the idea that hydrogen activity plays a central role in damage formation, and that targeted additives can prevent it by reducing surface temperatures and forming protective film, which blocks hydrogen diffusion. These findings offer a scientifically grounded and practically viable solution to extend bearing life and prevent costly failures in high-load, high-reliability applications. |
| format | Article |
| id | doaj-art-fa31713a47c54d1785fe8f6f1d323b5f |
| institution | Kabale University |
| issn | 2297-3079 |
| language | English |
| publishDate | 2025-05-01 |
| publisher | Frontiers Media S.A. |
| record_format | Article |
| series | Frontiers in Mechanical Engineering |
| spelling | doaj-art-fa31713a47c54d1785fe8f6f1d323b5f2025-08-20T03:47:28ZengFrontiers Media S.A.Frontiers in Mechanical Engineering2297-30792025-05-011110.3389/fmech.2025.15854721585472Preventing electrically induced subsurface initiated pitting failures (incl. WSF, WEC, WEA) with copper based lubricant additivesSergei Mamykin0Marc Ingram1Leyla Alieva2Varvara Privalova3Neol Copper Technologies Ltd., London, United KingdomIngram Tribology Ltd., Johnstown, United KingdomNeol Copper Technologies Ltd., London, United KingdomNeol Copper Technologies Ltd., London, United KingdomPremature bearing failures in large electric machines such as wind turbines and locomotives are often caused by White Etching Cracks (WEC), White Etching Areas (WEA), and White Structure Flaking (WSF)—phenomena that, despite extensive study, remain not fully understood. This work introduces a new hypothesis of WEC, WEA and WSF formation combining Garkunov’s scientific discoveries of “hydrogen wear of metals” and the “wearlessness effect” with the existing knowledge and offers a possible solution. To test this hypothesis and solution, a prototype lubricant containing oil-soluble copper salts was evaluated using an electrically induced WEC test on a three ring-on-roller tribometer. The test applied high contact pressures and direct current to simulate operating conditions, followed by subsurface serial sectioning to examine material degradation. The results showed that the reference lubricant exhibited typical WEC and WEA damage, while the copper-based candidate lubricant prevented such failures entirely. This outcome supports the idea that hydrogen activity plays a central role in damage formation, and that targeted additives can prevent it by reducing surface temperatures and forming protective film, which blocks hydrogen diffusion. These findings offer a scientifically grounded and practically viable solution to extend bearing life and prevent costly failures in high-load, high-reliability applications.https://www.frontiersin.org/articles/10.3389/fmech.2025.1585472/fullwhite etching area (WEA)white etching crack (WEC)large electric machinesbearingshydrogen wearno-wear effect |
| spellingShingle | Sergei Mamykin Marc Ingram Leyla Alieva Varvara Privalova Preventing electrically induced subsurface initiated pitting failures (incl. WSF, WEC, WEA) with copper based lubricant additives Frontiers in Mechanical Engineering white etching area (WEA) white etching crack (WEC) large electric machines bearings hydrogen wear no-wear effect |
| title | Preventing electrically induced subsurface initiated pitting failures (incl. WSF, WEC, WEA) with copper based lubricant additives |
| title_full | Preventing electrically induced subsurface initiated pitting failures (incl. WSF, WEC, WEA) with copper based lubricant additives |
| title_fullStr | Preventing electrically induced subsurface initiated pitting failures (incl. WSF, WEC, WEA) with copper based lubricant additives |
| title_full_unstemmed | Preventing electrically induced subsurface initiated pitting failures (incl. WSF, WEC, WEA) with copper based lubricant additives |
| title_short | Preventing electrically induced subsurface initiated pitting failures (incl. WSF, WEC, WEA) with copper based lubricant additives |
| title_sort | preventing electrically induced subsurface initiated pitting failures incl wsf wec wea with copper based lubricant additives |
| topic | white etching area (WEA) white etching crack (WEC) large electric machines bearings hydrogen wear no-wear effect |
| url | https://www.frontiersin.org/articles/10.3389/fmech.2025.1585472/full |
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