Electrostatic sensing of wear and friction dynamics in dry and starved-lubricated tribocontact
Electrostatic sensing of wear and friction dynamics in dry and starved-lubricated tribocontact
Wear mechanisms in dry and starved lubricated contacts are critical factors contributing to the degradation of component surfaces. Real-time monitoring of wear progression presents significant challenges due to the complex nature of these mechanisms and the varying conditions under which they occur. Surface charge offers a way of monitoring wear progression as it is correlated with surface charging from wear debris, contact potential differences associated with surface films, material phase transformations and wear transitions as well as from additive adsorption. This research employs two types of electrostatic wear sensor: a bar sensor for in-situ monitoring of wear progression and an array sensor for charge mapping of the resultant wear mechanisms in the scar.
Two sliding wear tests with tool steel against bearing steel are presented. Tests were conducted under dry sliding conditions or partially lubricated. Positive charge signals were detected for oxidational wear under dry contact conditions. Elemental mapping confirmed a patchy oxide film had developed and loose oxide wear debris became charged. Correlation is seen between surface charge maps and the patchy surface oxide films. A correlation was also found between the coefficient of friction and electrostatic charge, highlighting the potential of electrostatic sensors in detecting changing friction and wear levels. Negative charge signals were observed under starved sliding conditions using polyalphaolefin (PAO), primarily attributed to the degradation of PAO under high shear rates and tribo-charge mechanism. The charge progressively changed towards a more positive value, suggesting the progression of mild oxidational wear. Only very mild wear was measured at the end of the test (i.e. plastic flow of asperity material into valleys).
A map of real-time wear progression/measure of instantaneous wear rate of oxidational wear and mild wear induced by partially lubricated contacts are presented. This advancement could significantly impact digital tribology, as the electrostatic sensing allows the surface chemistry to be better characterised. This allows for wear monitoring of the wear processes in action, allowing for better optimisation of predictive maintenance, as the information is real-time and the sensor is non-invasive.
oxidational wear, electrostatic sensing, friction, starved-lubrication, outlier detection
Tian, Zaihao
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Lu, Ping
fd23d6f6-6474-4a94-95a4-c721d06a354a
Grundy, Jo
0bc72187-8dce-41fc-b809-93a6adbe0980
Powrie, Honor
81067bac-f71e-4bdb-b216-87f4f4da43de
Harvey, Terence
3b94322b-18da-4de8-b1af-56d202677e04
Wood, Robert
d9523d31-41a8-459a-8831-70e29ffe8a73
Tian, Zaihao
6c5ef4d8-60aa-4615-910e-b47954e322e8
Lu, Ping
fd23d6f6-6474-4a94-95a4-c721d06a354a
Grundy, Jo
0bc72187-8dce-41fc-b809-93a6adbe0980
Powrie, Honor
81067bac-f71e-4bdb-b216-87f4f4da43de
Harvey, Terence
3b94322b-18da-4de8-b1af-56d202677e04
Wood, Robert
d9523d31-41a8-459a-8831-70e29ffe8a73
Tian, Zaihao, Lu, Ping, Grundy, Jo, Powrie, Honor, Harvey, Terence and Wood, Robert
(2024)
Electrostatic sensing of wear and friction dynamics in dry and starved-lubricated tribocontact.
25th International Conference on Wear of Materials, , Sitges, Spain.
13 - 17 Apr 2025.
21 pp
.
(In Press)
Record type:
Conference or Workshop Item
(Paper)
Abstract
Wear mechanisms in dry and starved lubricated contacts are critical factors contributing to the degradation of component surfaces. Real-time monitoring of wear progression presents significant challenges due to the complex nature of these mechanisms and the varying conditions under which they occur. Surface charge offers a way of monitoring wear progression as it is correlated with surface charging from wear debris, contact potential differences associated with surface films, material phase transformations and wear transitions as well as from additive adsorption. This research employs two types of electrostatic wear sensor: a bar sensor for in-situ monitoring of wear progression and an array sensor for charge mapping of the resultant wear mechanisms in the scar.
Two sliding wear tests with tool steel against bearing steel are presented. Tests were conducted under dry sliding conditions or partially lubricated. Positive charge signals were detected for oxidational wear under dry contact conditions. Elemental mapping confirmed a patchy oxide film had developed and loose oxide wear debris became charged. Correlation is seen between surface charge maps and the patchy surface oxide films. A correlation was also found between the coefficient of friction and electrostatic charge, highlighting the potential of electrostatic sensors in detecting changing friction and wear levels. Negative charge signals were observed under starved sliding conditions using polyalphaolefin (PAO), primarily attributed to the degradation of PAO under high shear rates and tribo-charge mechanism. The charge progressively changed towards a more positive value, suggesting the progression of mild oxidational wear. Only very mild wear was measured at the end of the test (i.e. plastic flow of asperity material into valleys).
A map of real-time wear progression/measure of instantaneous wear rate of oxidational wear and mild wear induced by partially lubricated contacts are presented. This advancement could significantly impact digital tribology, as the electrostatic sensing allows the surface chemistry to be better characterised. This allows for wear monitoring of the wear processes in action, allowing for better optimisation of predictive maintenance, as the information is real-time and the sensor is non-invasive.
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Accepted/In Press date: 14 December 2024
Venue - Dates:
25th International Conference on Wear of Materials, , Sitges, Spain, 2025-04-13 - 2025-04-17
Keywords:
oxidational wear, electrostatic sensing, friction, starved-lubrication, outlier detection
Identifiers
Local EPrints ID: 497379
URI: http://eprints.soton.ac.uk/id/eprint/497379
PURE UUID: 29becb0a-c4d7-4d85-a2e3-433442201d01
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Date deposited: 21 Jan 2025 17:51
Last modified: 22 Aug 2025 02:26
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Contributors
Author:
Zaihao Tian
Author:
Jo Grundy
Author:
Honor Powrie
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