Changes in the Key Physicochemical Parameters and Selected Trace Elements of Oil Due to Its Use in Hydraulic System of Woodworking Equipment

ASTM D5185-18: 2018. Standard test method for multielement determination of used and unused lubricating oils and base oils by inductively coupled plasma atomic emission spectrometry (ICP-AES). Search in Google Scholar

BACZEWSKI, K. – SZCZAWIŃSKI, P. 2016. Investigation of the process of ageing of hydraulic oil during its use. In The Archives of Automotive Engineering – Archiwum Motoryzacji, vol. 73, no. 3, pp. 5–18. Search in Google Scholar

CIULLI, E. 2019. Tribology and industry: From the origins to 4.0. In Frontiers in Mechanical Engineering, vol. 5. Search in Google Scholar

DIN ISO 3448: 2010. Industrial liquid lubricants – ISO viscosity classification. Search in Google Scholar

DU, Y. – WU, T. – ZHOU, S. – MAKIS, V. 2019. Remaining useful life prediction of lubricating oil with dynamic principal component analysis and proportional hazards model. In Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology, vol. 234, no. 6, pp. 964–971. Search in Google Scholar

GE, Z. – SONG, Z. 2012. Multivariable Statistical Process Control: Process Monitoring Methods and Applications (Advances in Industrial Control). London : Springer Science & Business Media, 212 pp. ISBN 9781447145127. Search in Google Scholar

HNILICOVÁ, M. – TURIS, J. – HNILICA, R. 2021. Application of multidimensional statistical analysis in tribotechnical diagnostics of hydraulic fluids in woodworking equipment. In Materials, vol. 14, no. 16, article no. 4628. Search in Google Scholar

HÖNIG, V. – PROCHÁZKA, P. – OBERGRUBER, M. – KUČEROVÁ, V. – MEJSTŘÍK, P. – MACKŮ, J. – BOUČEK, J. 2020. Determination of tractor engine oil change interval based on material properties. In Materials, vol. 13, no. 23, article no. 5403. Search in Google Scholar

HUJO, Ľ. – NOSIAN, J. – ZASTEMPOWSKI, M. – KOSIBA, J. – KASZKOWIAK, J. – MICHALIDES, M. 2021. Laboratory tests of the hydraulic pump operating load with monitoring of changes in the physical properties. In Measurement and Control, vol. 54, no. 3–4, pp. 243–251. Search in Google Scholar

ISO 760: 1978. Determination of water – Karl Fischer Method (General method). Search in Google Scholar

ISO 2909: 2002. Petroleum products – Calculation of viscosity index from kinematic viscosity. Search in Google Scholar

ISO 2592: 2017. Petroleum and related products – Determination of flash and fire points – Cleveland open cup method. Search in Google Scholar

ISO 3104: 2020. Petroleum products – Transparent and opaque liquids – Determination of kinematic viscosity and calculation of dynamic viscosity. Search in Google Scholar

ISO 4406: 2021. Hydraulic fluid power – Fluids – Method for coding the level of contamination by solid particles. Search in Google Scholar

ISO 6618: 1997. Petroleum products and lubricants – Determination of acid or base number –Colour-indicator titration method. Search in Google Scholar

JABLONICKÝ, J. – SIMIKIĆ, M. – TULÍK, J. – TOMIĆ, M. – HUJO, Ľ. – KOSIBA, J. 2020. Monitoring of selected physical and chemical parameters of test oil in the wet disc brake system. In Acta Technologica Agriculturae, vol. 23, no. 1, pp. 46–52. Search in Google Scholar

KALLIGEROS, S. S. 2014. Predictive maintenance of hydraulic lifts through lubricating oil analysis. In Machines, vol. 2, no. 1, pp. 1–12. Search in Google Scholar

KARANOVIĆ, V. V. – JOCANOVIĆ, M. T. – WAKIRU, J. M. – OROŠNJAK, M. D. 2018. Benefits of lubricant oil analysis for maintenance decision support: A case study. In IOP Conference Series: Materials Science and Engineering, vol. 393, pp. 012013. Search in Google Scholar

KOPČANOVÁ, S. – SEJKOROVÁ, M. – KUČERA, M. – HNILICOVÁ, M. 2020. Wear of hydraulic system components assessment based on the analysis of hydraulic oil degradation degree. In Przemysel Chemyszny, vol. 99, no. 9, pp. 1000–1004. Search in Google Scholar

KUČERA, M. – ALEŠ. Z. 2017. Morphology analysis of friction particles generated in tractor transmission oils. In Acta Technologica Agriculturae, vol. 20, no. 3, pp. 57–62. Search in Google Scholar

KUČEROVÁ, V. – LAGAŇA, R. – HÝROŠOVÁ, T. 2019. Changes in chemical and optical properties of silver fir (Abies alba L.) wood due to thermal treatment. In Journal of Wood Science, vol. 65, no. 1, p. 21. Search in Google Scholar

LEI, Y. – JIANG, W. – JIANG, A. – ZHU, Y. – NIU, H. – ZHANG, S. 2019. Fault diagnosis method for hydraulic directional valves integrating PCA and XGBoost. In Processes, vol. 7, no. 9, p. 58910.3390/pr7090589 Search in Google Scholar

LIVINGSTONE, G. – CAVANAUGH, G. 2015. The real reasons why hydraulic fluid fail and strategies to stop problems before they start. In Tribology and Lubrication Technology, pp. 44–51. Search in Google Scholar

NG, F. – HARDING, J. A. – GLASS, J. 2017. Improving hydraulic excavator performance through in line hydraulic oil contamination monitoring. In Mechanical Systems and Signal Processing, vol. 83, pp. 176–193. Search in Google Scholar

OROŠNJAK, M. D. – JOCANOVIĆ, M. T. – KARANOVIĆ, V. V. 2021. Applying contamination control for improved prognostics and health management of hydraulic systems. In BALL, A. – GELMAN, L. – RAO, B. K. N. Advances in Asset Management and Condition Monitoring: COMADEM 2019. Berlin, Heidelberg : Springer, pp. 583–596. ISBN 9783030577445. Search in Google Scholar

SEJKOROVÁ, M. – HURTOVÁ, I. – JILEK, P. – NOVÁK, M. – VOLTR, O. 2021. Study of the effect of physicochemical degradation and contamination of motor oils on their lubricity. In Coatings, vol. 11, no. 1, article no. 60. Search in Google Scholar

SIDDIQUI, M. H. – PAL, S. K. – DEWANGAN, N. – CHATTOPADHYAYA, S. – SHARMA, S. – NEKOONAM, S. – ISSAKHOV, A. 2021. Sludge formation analysis in hydraulic oil of load haul dumper 811MK V machine running at elevated temperatures for bioenergy applications. In International Journal of Chemical Engineering, vol. 2021, p. 4331809. Search in Google Scholar

STN EN ISO 6743-4: 2015. Lubricants, industrial oils and related products (class L) – Classification – Part 4: Family H (Hydraulic systems). Search in Google Scholar

STN EN ISO 3170: 2005. Petroleum liquids. Manual sampling. Search in Google Scholar

TKÁČ, Z. – ČORNÁK, Š. – KOSIBA, J. – JANOUŠKOVÁ, R. – MICHALIDES, M. – VOZÁROVÁ, V. – CSILLAG, J. 2021. Investigation of degradation of ecological hydraulic fluid. In Proceedings of the Institution of Mechanical Engineers: Part C – Journal of Mechanical Engineering Science, vol. 235, no. 24, pp. 7925–7933. Search in Google Scholar

VALIŠ, D. – ŽÁK, L. – POKORA, O. 2015. Failure prediction of diesel engine based on occurrence of selected wear particles in oil. In Engineering Failure Analysis, vol. 56, pp. 501–511. Search in Google Scholar

WAKIRU, J. M. – PINTELON, L. – MUCHIRI, P. N. – CHEMWENO, P. K. 2019. A review on lubricant condition monitoring information analysis for maintenance decision support. In Mechanical Systems and Signal Processing, vol. 118, pp. 108–132. Search in Google Scholar

WALCZAK, M. – CABAN, J. 2021. Tribological characteristics of polymer materials used for slide bearings. In Open Engineering, vol. 11, no. 1, pp. 624–629. Search in Google Scholar

WATTON, J. 2007. Modelling, Monitoring and Diagnostic Techniques for Fluid Power Systems. Berlin, Heidelberg : Springer Verlag, 360 pp. ISBN 9781846283734. Search in Google Scholar

WOLAK, A. – MOLENDA, J. – ZAJĄC, G. – JANOCHA, P. 2021. Identifying and modelling changes in chemical properties of engine oils by use of infrared spectroscopy. In Measurement, vol. 186, article no. 110141. Search in Google Scholar