Cavitation is one of the main concern on centrifugal pump faults that could cause component damages up to production failure in the industries. It is essential to detect and diagnose the fault as early as possible to prevent a catasthropic failure. Cavitation on sentrifugal pump could be caused by many factor, one of them are caused by the pump operating speed. This paper presents a method that able to detect cavitation by monitoring the vibrations level of the pump based on statistical analysis of time domain. This method is known as vibration monitoring technique that is undoubtedly the most effective technique to detect rotational machinery faults. The cavitation simulated on the test rig by varying the operating speed at 1000 RPM, 1200 RPM, 1400 RPM, …, 2600 RPM and by varying the size of suction valve opening. The cavitation phenomena are measured and indicated by magnitude of vibration level changes in stastical parameter such as Probability Density Function (PDF), Variance, Standard Deviation, Root Mean Square (RMS), Peak Value, Crest Factors and Kurtosis. The results show that PDF, Variance, Standard Deviation and RMS are proved to be able to detect cavitation caused by the pump operating speed variation. However, parameter such as Peak Value, Crest Factor and Kurtosis show low sensitivity and not suitable for the cavitation detection purposes.

cavitation, operating speed, vibration monitoring, statistical parameters, time domain.

Abdulaziz, A. M., & Kotb, A. (2016). Detection of pump cavitation by vibration signature, 4846(October). https://doi.org/10.1080/14484846.2015.1093261

Al-Hashmi, S. A. (2009). Statistical analysis of vibration signals for cavitation detection ISIEA 2009. 2009 IEEE Symposium on Industrial Electronics and Applications, ISIEA 2009 - Proceedings, 1(Isiea), 78–82. https://doi.org/10.1109/ISIEA.2009.5356506

Al-Tobi, M. A. S., & Al-Sabari, M. H. J. (2016). Cavitation detection of centrifugal pump using Time – Domain method, 4(5), 161–167.

Birajdar, R., Patil, R., & Khanzode, K. (2009). Vibration and noise in centrifugal pumps - Sources and diagnosis methods. 3rd International Conference on Integrity, Reliability and Failure, (May 2016), 20–24.

Brandt, A. (2010). NOISE AND VIBRATION ANALYSIS SIGNAL ANALYSIS AND.

Brennen, E. C. (1977). Cavitation and bubble dynamics. Annual Review of Fluid Mechanics (Vol. 9). https://doi.org/10.1017/CBO9781107338760

Cunha, I. Da, Strack, T., & Stricker, S. (2008). PUMP SYSTEMS: Energy Efficiencyreference Guide. CEATI International.

Gülich, J. F. (2013). Centrifugal Pumps. Springer. https://doi.org/10.1017/CBO9781107415324.004

Karassik, I. J., Cooper, P., & Heald, C. C. (2008). PUMP HANDBOOK.

Luo, Y., Sun, H., Yuan, S., & Yuan, J. (2015). Research on Statistical Characteristics of Vibration in Centrifugal Pump, 38, 49–61.

McKee, K. K., Forbes, G. L., Mazhar, I., Entwistle, R., Hodkiewicz, M., & Howard, I. (2015). A vibration cavitation sensitivity parameter based on spectral and statistical methods. Expert Systems with Applications, 42(1), 67–78. https://doi.org/10.1016/j.eswa.2014.07.029

Scheffer, C., & Girdhar, P. (2004). Practical Machinery Vibration Analysis and Predictive Maintenance. Machinery Vibration Analysis & Predictive Maintenance. https://doi.org/10.1016/0301-679X(78)90097-X