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Research Article | Open Access

Predicting the coefficient of friction in a sliding contact by applying machine learning to acoustic emission data

Robert GUTIERREZ1( )Tianshi FANG2Robert MAINWARING3Tom REDDYHOFF1( )
Tribology Group, Department of Mechanical Engineering, Imperial College London, Exhibition Road, London SW7 2AZ, UK
Shell Global Solutions (US) Inc. Shell Technology Center Houston, 3333 Highway 6 South, Houston, TX 77082, USA
Shell International Petroleum Company Limited, Shell Centre, York Road, London SE1 7NA, UK
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Graphical Abstract

Abstract

It is increasingly important to monitor sliding interfaces within machines, since this is where both energy is lost, and failures occur. Acoustic emission (AE) techniques offer a way to monitor contacts remotely without requiring transparent or electrically conductive materials. However, acoustic data from sliding contacts is notoriously complex and difficult to interpret. Herein, we simultaneously measure coefficient of friction (with a conventional force transducer) and acoustic emission (with a piezoelectric sensor and high acquisition rate digitizer) produced by a steel‒steel rubbing contact. Acquired data is then used to train machine learning (ML) algorithms (e.g., Gaussian process regression (GPR) and support vector machine (SVM)) to correlated acoustic emission with friction. ML training requires the dense AE data to first be reduced in size and a range of processing techniques are assessed for this (e.g., down-sampling, averaging, fast Fourier transforms (FFTs), histograms). Next, fresh, unseen AE data is given to the trained model and the resulting friction predictions are compared with the directly measured friction. There is excellent agreement between the measured and predicted friction when the GPR model is used on AE histogram data, with root mean square (RMS) errors as low as 0.03 and Pearson correlation coefficients reaching 0.8. Moreover, predictions remain accurate despite changes in test conditions such as normal load, reciprocating frequency, and stroke length. This paves the way for remote, acoustic measurements of friction in inaccessible locations within machinery to increase mechanical efficiency and avoid costly failure/needless maintenance.

Keywords

acoustic emissioncondition monitoringfrictionmachine learningGaussian process regressionsupport vector machine

References

[1]
Holmberg K, Erdemir A. Influence of tribology on global energy consumption, costs and emissions. Friction 5(3): 263284 (2017)
Crossref Google Scholar
[2]
Holmberg K, Kivikytö-Reponen P, Härkisaari P, Valtonen K, Erdemir A. Global energy consumption due to friction and wear in the mining industry. Tribol Int 115: 116139 (2017)
Crossref Google Scholar
[3]
Anonymous, Machine Condition Monitoring Market by Monitoring Technique (Vibration Monitoring, Thermography, Oil Analysis, Corrosion Monitoring, Ultrasound Emission), Monitoring Process (Online, Portable), Deployment, Offering - Global Forecast to 2027. In MarketsandMarkets, 2022.
[4]
Anonymous, Oil Condition Monitoring Market by Product Type (Turbines, Compressors, Engines, Gear Systems, Hydraulic Systems), Sampling Type, Vertical (Transportation, Industrial, Oil & Gas), and Region (2021-2026). In MarketsandMarkets, 2021.
[5]
Mazal P, Dvoracek J, Pazdera L. Application of acoustic emission method in contact damage identification. Int J Mater Prod Technol 41(1/2/3/4): 140 (2011)
Crossref Google Scholar
[6]
Feng P P, Borghesani P, Smith W A, Randall R B, Peng Z X. A review on the relationships between acoustic emission, friction and wear in mechanical systems. Appl Mech Rev 72(2): 020801 (2020)
Crossref Google Scholar
[7]
Zhang X, Wang K W, Wang Y, Shen Y, Hu H S. Rail crack detection using acoustic emission technique by joint optimization noise clustering and time window feature detection. Appl Acoust 160: 107141 (2020)
Crossref Google Scholar
[8]
Bol’shakov A M, Andreev Y M. Acoustic-emission testing of vertical steel tanks in hard-to-reach areas of the far north. Russ J Nondestruct Test 55(3): 181184 (2019)
Crossref Google Scholar
[9]
Crivelli D, McCrory J, Miccoli S, Pullin R, Clarke A. Gear tooth root fatigue test monitoring with continuous acoustic emission: Advanced signal processing techniques for detection of incipient failure. Struct Health Monit 17(3): 423433 (2018)
Crossref Google Scholar
[10]
Liu Z, Peng Q, He C, Wu B. Time difference mapping method for acoustic emission source location of composite plates. ACTA ACUSTICA 45(3): 385393 (2020) (in Chinese).
Google Scholar
[11]
Chernov D V, Matyunin V M, Barat V A, Marchenkov A Y, Elizarov S V. Investigation of acoustic emission in low-carbon steels during development of fatigue cracks. Russ J Nondestruct Test 54(9): 638647 (2018)
Crossref Google Scholar
[12]
Krampikowska A, Pała R, Dzioba I, Świt G. The use of the acoustic emission method to identify crack growth in 40CrMo steel. Materials 12(13): 2140 (2019)
Crossref Google Scholar
[13]
Nivesrangsan P, Steel J A, Reuben R L. Source location of acoustic emission in diesel engines. Mech Syst Signal Process 21(2): 11031114 (2007)
Crossref Google Scholar
[14]
Sun J, Wood R J K, Wang L, Care I, Powrie H E G. Wear monitoring of bearing steel using electrostatic and acoustic emission techniques. Wear 259(7–12): 14821489 (2005)
Crossref Google Scholar
[15]
Miettinen J, Siekkinen V. Acoustic emission in monitoring sliding contact behaviour. Wear 181–183: 897900 (1995)
Crossref Google Scholar
[16]
Lingard S, Ng K K. An investigation of acoustic emission in sliding friction and wear of metals. Wear 130(2): 367379 (1989)
Crossref Google Scholar
[17]
Boness R J, McBride S L, Sobczyk M. Wear studies using acoustic emission techniques. Tribol Int 23(5): 291295 (1990)
Crossref Google Scholar
[18]
Mussa A, Krakhmalev P, Bergström J. Sliding wear and fatigue cracking damage mechanisms in reciprocal and unidirectional sliding of high-strength steels in dry contact. Wear 444–445: 203119 (2020)
Crossref Google Scholar
[19]
Chevallier E. Mechanical model of the electrical response from a ring–wire sliding contact. Tribol Trans 63(2): 215221 (2020)
Crossref Google Scholar
[20]
Yang H J, Hu Y, Chen G X, Zhang W H, Wu G N. Correlation between the wear and vibration of the contact strip in a contact wire rubbing against a contact strip with electrical current. Tribol Trans 57(1): 8693 (2014)
Crossref Google Scholar
[21]
Jiaa C L, Dornfeld D A. Experimental studies of sliding friction and wear via acoustic emission signal analysis. Wear 139(2): 403424 (1990)
Crossref Google Scholar
[22]
Fan Y B, Gu F S, Ball A. Modelling acoustic emissions generated by sliding friction. Wear 268(5–6): 811815 (2010)
Crossref Google Scholar
[23]
Hu S T, Huang W F, Shi X, Peng Z K, Liu X F, Wang Y M. Bi-Gaussian stratified effect of rough surfaces on acoustic emission under a dry sliding friction. Tribol Int 119: 308315 (2018)
Crossref Google Scholar
[24]
Towsyfyan H, Gu F S, Ball A D, Liang B. Modelling acoustic emissions generated by tribological behaviour of mechanical seals for condition monitoring and fault detection. Tribol Int 125: 4658 (2018)
Crossref Google Scholar
[25]
Fuentes R, Dwyer-Joyce R S, Marshall M B, Wheals J, Cross E J. Detection of sub-surface damage in wind turbine bearings using acoustic emissions and probabilistic modelling. Renew Energy 147: 776797 (2020)
Crossref Google Scholar
[26]
Suzuki H, Kinjo T, Hayashi Y, Takemoto M, Ono K, Hayashi Y. Wavelet transform of acoustic emission signals. J Acoust Emiss 14(2): 6984 (1996)
Google Scholar
[27]
Geng Z, Puhan D, Reddyhoff T. Using acoustic emission to characterize friction and wear in dry sliding steel contacts. Tribol Int 134: 394407 (2019)
Crossref Google Scholar
[28]
Strablegg C, Renhart P, Summer F, Grün F. Methodology, validation & signal processing of acoustic emissions for selected lubricated tribological contacts. Mater Today Proc 62: 26042610 (2022)
Crossref Google Scholar
[29]
Baccar D, Söffker D. Wear detection by means of wavelet-based acoustic emission analysis. Mech Syst Signal Process 60–61: 198207 (2015)
Crossref Google Scholar
[30]
Hase A, Mishina H, Wada M. Correlation between features of acoustic emission signals and mechanical wear mechanisms. Wear 292–293: 144150 (2012)
Crossref Google Scholar
[31]
Fuentes R, Howard T P, Marshall M B, Cross E J, Dwyer-Joyce R S. Observations on acoustic emissions from a line contact compressed into the plastic region. Proc Inst Mech Eng Part J J Eng Tribol 230(11): 13711376 (2016)
Crossref Google Scholar
[32]
König F, Sous C, Ouald Chaib A, Jacobs G. Machine learning based anomaly detection and classification of acoustic emission events for wear monitoring in sliding bearing systems. Tribol Int 155: 106811 (2021)
Crossref Google Scholar
[33]
Sattari Baboukani B, Ye Z J, G Reyes K, Nalam P C. Prediction of nanoscale friction for two-dimensional materials using a machine learning approach. Tribol Lett 68(2): 57 (2020)
Crossref Google Scholar
[34]
Hasan M S, Kordijazi A, Rohatgi P K, Nosonovsky M. Triboinformatic modeling of dry friction and wear of aluminum base alloys using machine learning algorithms. Tribol Int 161: 107065 (2021)
Crossref Google Scholar
[35]
Strablegg C, Summer F, Renhart P, Grün F. Prediction of friction power via machine learning of acoustic emissions from a ring-on-disc rotary tribometer. Lubricants 11(2): 37 (2023)
Crossref Google Scholar
[36]
Rastegaev I A, Merson D L, Danyuk A V, Afanasyev M A, Vinogradov A. Using acoustic emission signal categorization for reconstruction of wear development timeline in tribosystems: Case studies and application examples. Wear 410–411: 8392 (2018)
Crossref Google Scholar
[37]
Benabdallah H S, Aguilar D A. Acoustic emission and its relationship with friction and wear for sliding contact. Tribol Trans 51(6): 738747 (2008)
Crossref Google Scholar
[38]
Hanchi J, Klamecki B E. Acoustic emission monitoring of the wear process. Wear 145(1): 127 (1991)
Crossref Google Scholar
[39]
Braga-Neto U. Fundamentals of Pattern Recognition and Machine Learning. Cham: Springer International Publishing, (2020).
Crossref
[40]
Stalph P. Analysis and Design of Machine Learning Techniques: Evolutionary Solutions for Regression, Prediction, and Control Problems. Wiesbaden: Springer Fachmedien Wiesbaden, (2014).
Crossref
[41]
Rasmussen C, Nickisch H. Gaussian Processes for Machine Learning. MIT Press, 2005.
Crossref
[42]
Drezet P, Harrison RF. Directly optimised support vector machines for classification and regression. ACSE Research Report 715, The University of Sheffield (1998)
Google Scholar
[43]
Friel T, Harrison R. Linear programming support vector machines for pattern classification and regression estimation and the SR Algorithm: Improving speed and tightness of VC bounds in SV algorithms. In ACSE Research Report 706, Sheffield, UK, 1998
Google Scholar
[44]
Weiss J, Richeton T, Louchet F, Chmelik F, Dobron P, Entemeyer D, Lebyodkin M, Lebedkina T, Fressengeas C, McDonald R J. Evidence for universal intermittent crystal plasticity from acoustic emission and high-resolution extensometry experiments. Phys Rev B 76(22): 224110 (2007)
Crossref Google Scholar
[45]
Miguel M C, Vespignani A, Zapperi S, Weiss J, Grasso J R. Intermittent dislocation flow in viscoplastic deformation. Nature 410(6829): 667671 (2001)
Crossref Google Scholar
[46]
Richeton T, Dobron P, Chmelik F, Weiss J, Louchet F. On the critical character of plasticity in metallic single crystals. Mater Sci Eng A 424(1–2): 190195 (2006)
Crossref Google Scholar
[47]
Bougherira Y, Entemeyer D, Fressengeas C, Kobelev N P, Lebedkina T A, Lebyodkin M A. The intermittency of plasticity in an Al3%Mg alloy. J Phys: Conf Ser 240: 012009 (2010)
Crossref Google Scholar
[48]
Lebyodkin M A, Kobelev N P, Bougherira Y, Entemeyer D, Fressengeas C, Gornakov V S, Lebedkina T A, Shashkov I V. On the similarity of plastic flow processes during smooth and jerky flow: Statistical analysis. Acta Mater 60(9): 37293740 (2012)
Crossref Google Scholar
[49]
Lebyodkin M A, Shashkov I V, Lebedkina T A, Mathis K, Dobron P, Chmelik F. Role of superposition of dislocation avalanches in the statistics of acoustic emission during plastic deformation. Phys Rev E 88(4): 042402 (2013)
Crossref Google Scholar
[50]
Merchant M E. The Friction and Lubrication of Solids. Bowden F P and Tabor D. New York: Oxford Univ. Press, 1950. 337 pp. $7.00. Science 113(2938): 443444 (1951)
Crossref Google Scholar
Friction
Volume 12 Issue 6,
June 2024
Pages 1299-1321
DOI: 10.1007/s40544-023-0834-7
Cite this article:
GUTIERREZ R, FANG T, MAINWARING R, et al. Predicting the coefficient of friction in a sliding contact by applying machine learning to acoustic emission data. Friction, 2024, 12(6): 1299-1321. https://doi.org/10.1007/s40544-023-0834-7

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Received: 28 April 2023
Revised: 28 June 2023
Accepted: 21 September 2023
Published: 02 February 2024
© The author(s) 2023.

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