Aerospace Technic and Technology

The application of a vibration sensor with an in-cylinder pressure sensor extends the capabilities of internal combustion engines and compressor diagnostics for various types of plants and installations, such as marine diesel engines, refrigeration piston compressors, aircraft engines. The fuel injection equipment malfunctions as valve as valve train system malfunctions could be detected from the experimental indicated diagrams P(V), P(deg) of the engine cylinder operating process as it is known. The main indicators are the following: the shape of the diagram and the parameters of working cycle – the maximum combustion pressure Pmax, the compression pressure Pcomp, mean indicated pressure IMEP, etc. However, it should be considered that different types of malfunctions could have the same reflection on the indicated diagram. For instance, the late fuel injection and the fuel-injection equipment wear could have almost similar effects on the indicated diagram and main diagnostic parameters. Another example is the low compression pressure Pcomp, which could be caused by the cylinder or compression rings wear and by the exhaust valves wrong timing or valve leakage.  It should also be mentioned that many types of malfunctions at their early stages are very difficult to detect and clarify based solely on the indicated diagrams analysis. The detection of such malfunctions usually requires the direct measurements of the fuel injection pressure and injector’s needle lift diagrams with accurate valve timing measurements. However, mentioned measurements could be performed under laboratory conditions and are difficult to apply under engine operating conditions. The vibration sensor application could be a reasonable alternative to the direct measurements, as it allows the determination of the injector’s needle lift-off and landing timing, high-pressure fuel pump cut-off and discharge timing, the preheated heavy fuel circulation start/stop timing as well as gas-distribution valves opening and closing timing, the oscillation frequency, and amplitude from the refrigeration system piston compressor valve operation and the cylinder oil injector timing. The vibration sensor has a magnetic basement that allows its easy mounting on the engine parts. All this information could be directly measured during engines and compressor trials by the vibration sensor applied in the advanced diagnostic systems.

turbocharger diagnostics; marine diesel engine; compressor; gas distribution, cylinder lubrication nozzles

Resolution MEPC.317(74). Amendments to the technical code on control of emission of nitrogen oxides from marine diesel engines. International Maritime Organization (IMO), 2019. 21 p. Available at: https://wwwcdn.imo.org/localresources/en/KnowledgeCentre/IndexofIMOResolutions/MEPCDocuments/MEPC.319(74).pdf (Accessed 28 April 2022).

Heywood, J. B. Internal combustion engine fundamentals. McGraw-Hill, New York, 1988. 930 p.

Neumann, S. High temperature pressure sensor based on thin film strain gauges on stainless steel for continuous cylinder pressure control. CIMAC Congress. Hamburg, Digest, 2001, pp. 1-12.

Neumann, S., Varbanets, R., Kyrylash, O., Yeryganov, O. V., Maulevych, V. O. Marine diesels working cycle monitoring on the base of IMES GmbH pressure sensors data. Diagnostyka, 2019, no. 20(2), pp. 19-26. DOI: 10.29354/diag/104516.

Varbanets, R. Diagnostic control of the working process of marine diesel engines in operation. Dissertation of the Doctor of Technical Sciences. Odessa National Maritime University. Odessa, 2010. 314 p.

Varbanets, R., Fomin, O., Píštěk, V., Klymenko, V., Minchev, D., Khrulev, A., Zalozh, V., Kučera, P. Acoustic Method for Estimation of Marine Low-Speed Engine Turbocharger Parameters. Journal of Marine Science and Engineering, 2021, no. 9(3), article no. 321. 13 p. DOI: 10.3390/jmse9030321.

Varbanets, R., Karianskiy, A. Analyse of marine diesel engine performance. Journal of Polish CIMAC. Energetic Aspects, Gdansk, Faculty of Ocean Engineering and Ship Technology. Gdansk University of Technology, 2012, vol. 7, no. 1, pp. 269-275.

Varbanets, R., Karianskyi, S., Rudenko, S. Improvement of diagnosing methods of the diesel engine functioning under operating conditions. SAE Technical Paper, 2017, vol. 2017. 12 р. DOI: 10.4271/2017-01-2218.

Minchev, D., Varbanets, R., Aleksandrovskaya, N., Pisintsaly, L., Marine diesel engines operating cycle simulation for diagnostics issues. Acta Polytechnica, 2021, vol. 61, iss. 3, pp. 428–440. DOI: 10.14311/AP.2021.61.0435.

Minchev, D. S. Blitz-PRO User’s manual. 2018. 96 p. Available at: http://blitzpro.zeddmalam.com/extra/Tutorial/Help.pdf (Accessed 27.04.2022).

Varbanets, R. A., Zalozh, V. I., Shakhov, A. V., Savelieva, I. V., Piterska, V. M. Determination of top dead centre location based on the marine diesel engine indicator diagram analysis. Diagnostyka, 2020, vol. 21, iss. 1, pp. 51-60. DOI: 10.29354/diag/116585.

Minchev, D., Varbanets, R. Centrifugal compressor performance maps treatment for internal combustion engines operating cycle simulation. Internal combustion engines, 2021, no. 1(21), pp. 9-15. DOI: 10.20998/0419-8719.2021.1.02.

Rakopoulos, C. D., Dimaratos, A. M. Giakoumis, E. G. Investigation of turbocharged diesel engine operation, exhaust emissions, and combustion noise radiation during starting under cold, warm, and hot conditions. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 2011, vol. 225, iss. 9, pp. 1118–1133. DOI: 10.1177/0954407011400155.