Cavitation can be observed in many hydraulic systems and its effects can do great harm. Basic problem with cavitation is its observation. This article continues the topic of optoelectronic system registering the shape of cavitation cloud. The aim of this paper is to analyse the possibility of broadening the use of that system, i.e., using it for the purpose of the frequency analysis of cavitating flow. The system assumes that cavitation leads to diffusion of lasers light on the vapor bubbles. Signals obtained from photodetectors is subjected to frequency analysis. Obtained results are promising - in our opinion, frequency analysis of cavitation flow can be treated as interesting source of additional information on parameters of cavitation.

Franc, J.P., Michel J.M., Fundamentals of Cavitation, Springer Netherlands, 2004.

Kinjo T., Matsumoto M., Cavitation processes and negative pressure, Fluid Phase Equilibria 1998, 144(1–2), 343–350.

Plesset, M.S. Prosperetti A., Bubble Dynamics and Cavitation, Annual Review of Fluid Mechanics 1997, 9, 145-185.

Karimi, A., Martin, J.L., Cavitation erosion of materials, International Metals Reviews 1986, 31(1), 1-26.

Kwok C.T., Man H.C., Cheng F.T., Lo K.H., Developments in laser-based surface engineering processes: with particular reference to protection against cavitation erosion, Surface and Coatings Technology 2016, 291, 189-204.

Song, Y., Ren, X., Gu, C. W., Li, X. S., Experimental and numerical studies of cavitation effects in a tapered land thrust bearing, Journal of Tribology 2015, 137(1), 011701.

Niedźwiedzka, A., Lipiński S., Metody badań eksperymentalnych zjawiska kawitacji (Methods of experimental investigations of cavitation phenomenon), Przegląd Mechaniczny 2017, 76(9), 44-46.

Lauterborn, W., Kurz, T., The Bubble Challenge for High-Speed Photography, The Micro-World Observed by Ultra High-Speed Cameras, 19-47, Springer Cham, 2018.

Lipiński S., Niedźwiedzka A., Analysis of high-speed photography of cavitating flow in convergent-divergent nozzle, Journal of Physics: Conference Series 2018, 1101, 012020.

Hepher, M.J., Duckett, D., Loening, A., High-speed video microscopy and computer enhanced imagery in the pursuit of bubble dynamics, Ultrasonics Sonochemistry 2000, 7(4), 229-233.

Coetmellec, S., Pejchang, D., Allano, D., Gréhan, G., Lebrun, D., Brunel, M., Janssen, A.J.E.M., Digital in-line holography in a droplet with cavitation air bubbles, Journal of the European Optical Society-Rapid Publications 2014, 9, 14056.

Pervunin, K.S., Timoshevskiy, M.V., Churkin, S.A., Kravtsova, A.Y., Markovich, D.M., Hanjalić, K., Cavitation on a scaled-down model of a Francis turbine guide vane: high-speed imaging and PIV measurements, Journal of Physics: Conference Series 2015, 656(1), 012166.

Duke, D., Swantek, A., Tilocco, Z., Kastengren, A., Fezzaa, K., Neroorkar, K., Moulai, M., Powell, C., Schmidt D., X-ray imaging of cavitation in diesel injectors, SAE International Journal of Engines 2014, 7(2), 1003-1016.

Kaznacheev, A., Kuznetsov, I., Investigations of unsteady flow in the draft tube of the pump-turbine model using laser Doppler anemometry, IOP Conference Series: Earth and Environmental Science 2014, 22(3), 032041.

Lipiński, S., Niedźwiedzka, A., Optoelectronic System Registering the Shape of Cavitation Cloud, Measurement Automation Monitoring 2016, 62(7), 238-240.

Niedźwiedzka, A., Lipiński S., Validation of Numerical Simulations of Cavitating Flow in Convergent-Divergent Nozzle, Measurement Automation Monitoring 2016, 62(10), 329-332.

Niedźwiedzka, A., Sobieski, W., Experimental investigations of cavitating flows in a Venturi tube, Technical Sciences 2016, 19(2), 151-164.

Fortes-Patella, R., Coutier-Delgosha, O., Perrin, J., Reboud, J.L., Numerical model to predict unsteady cavitating flow behavior in inducer blade cascades, Journal of Fluid Engineering 2007, 129(2), 128-135.

De Giorgi, M. G., Ficarella, A., Tarantino, M., Evaluating cavitation regimes in an internal orifice at different temperatures using frequency analysis and visualization, International Journal of Heat and Fluid Flow 2013, 39, 160-172.