Warianty tytułu
Języki publikacji
Abstrakty
Acoustic emission method (AE) can be used for the diagnosis of machine parts such as, for example: fuel injectors. This paper presents the methodology and research results of 3AL25/30 engine fuel injector. During research was studied one injector in good condition and second with simulated failure involving closing 2 of 9 holes of the injector tip. Research was carried out on a laboratory test stand using a set of acoustic emission Vallen System. This set included: 4 channel signal recorder AMSY 6, two measurement modules ASIP-2/S, preamplifier with a frequency range 20 kHz-1 MHz and the strengthening of 34 dB, AE signal measurement sensor type VS 150M, with a frequency range 100-450 kHz. During the study, the acoustic emission (AE) generated by tested injector was recorded. The following parameters were determined: amplitude, rise time, duration time, total time, number of events - hits, the effective value of the signal (RMS). Analysis of the results showed significantly longer total time of the injection in the case of damaged injector compared to the injector in good conditions. Signal amplitude was higher, however, the RMS signal reached approximately 3-times lower value for the injector with damaged tip. This means lower quality fuel atomization. Laboratory test results were compared with signals recorded on injectors installed in the engine. Analysis of the signals allowed detection damage of the injector installed in the engine during normal operation.(original abstract)
Słowa kluczowe
Twórcy
autor
- Gdynia Maritime University, Poland
Bibliografia
- Baran, I., Nowak, M., Schmidt, J. and Ono, K. (2007). Potentials of AE application in testing industrial pipelines. Advances in Acoustic Emission, USA, 2007.
- Bejger, A. and Drzewieniecki, J. (2015). Analysis of tribological processes occuring in precision pairs based on example of fuel injection pumps of marine diesel engines. Scientific Journals of the Maritime University of Szczecin, 41 (113), pp. 9-16.
- Dudzik, K. and Charchalis, A. (2015). The use of acoustic emission for the diagnosis of 3Al25/30 engine fuel injector. Logistyka, 3(2015), pp. 1077-1083.
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- Murawski, L. (2017). Thermal displacement of crankshaft axis of slow-speed marine engine. Brodogradnja, 67(4), pp. 17-29.
- Wu, H., Wang, Y. and Yu, Z. (2016). In situ monitoring of FDM machine condition via acoustic emission. International Journal of Advanced Manufacturing Technology, 84, pp. 1483-1495.
- Wu, H., Yu, Z. and Wang, Y. (2017). Real-time FDM machine condition monitoring and diagnosis based on acoustic emission and hidden semi-Markov model. International Journal of Advanced Manufacturing Technology, 90, pp. 2027-2036.
- Wu, W., Lin, T.R. and Tan, A.C.C. (2015). Normalization and source separation of acoustic emission signals for condition monitoring and fault detection of multi-cylinder diesel engines. Mechanical Systems and Signal Processing, 64-65, pp. 479-497.
- Ziegler, B. (2007). Contribution of acoustic emission into optimal bearing lubrication. Journal of KONES, 14(4), pp. 571-578.
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Typ dokumentu
Bibliografia
Identyfikatory
Identyfikator YADDA
bwmeta1.element.ekon-element-000171585480
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