A novel technique for vibro-acoustical diagnostics of turbine cavitation is introduced and its use demonstrated on a Francis turbine. The technique enables identification of different cavitation mechanisms functioning in a turbine and delivers detailed turbine cavitation characteristics, for each of the mechanisms or for the total cavitation. The characteristics specify the contribution of every critical turbine part to the cavitation intensity. Typical diagnostic results: (1) enable optimization of turbine operation with respect to cavitation erosion; (2) show how a turbine’s cavitation behavior can be improved; and (3) form the basis for setting up a high-sensitivity, reliable cavitation monitoring system.
Issue Section:
Additional Technical Papers
1.
Abbot, P. A., 1989, “Cavitation Detection Measurements on Francis and Kaplan Hydroturbines,” Proceedings of the International Symposium on Cavitation Noise and Erosion in Fluid Systems, ASME, New York, FED-Vol. 88, pp. 55–61.
2.
Abbott, P. A., and Morton, D. W., 1991, “Hydroturbine Cavitation Detection Using Advanced Acoustic Emissions Techniques,” Hydroacoustics Facilities, Instrumentation and Experimental Techniques, ASME, New York, NCA-Vol. 10, pp. 75–84.
3.
Gulich, J.-F., 1992, “Kavitationsdiagnose an Kreiselpumpen,” Technische Rundschau Sulzer, (1), pp. 30–35.
4.
Knapp, W., Schneider, Ch., and Schilling, R., 1992, “Experience With an Acoustic Cavitation Monitor for Water Turbines,” Cavitation, Proceedings of the ImechE International Conference, C453/048, ImechE, London, pp. 271–275.
5.
Bourdon, P., Simoneau, R., and Avellan, F., 1993, “Erosion Vibratory Fingerprint of Leading Edge Cavitation of a NACA Profile and of a Francis Model and Prototype Hydroturbine,” Bubble Noise and Cavitation Erosion in Fluid Systems, ASME, New York, FED-Vol. 176, pp. 51–67.
6.
Bajic
, B.
, and Keller
, A.
, 1996
, “Spectrum Normalization Method in Vibro-acoustical Diagnostic Measurements of Hydroturbine Cavitation
,” ASME J. Fluids Eng.
, 118
, pp. 756
–761
.7.
Farhat
, M.
, Bourdon
, P.
, and Lavigne
, P.
, 1996
, “Some Hydro Quebec Experiences on the Vibratory Approach for Cavitation Monitoring
,” Int. J. on Hydropower Dams
, 3
, pp. 151
–160
.8.
Vizmanos
, C.
, Egusquiza
, E.
, and Jou
, E.
, 1996
, “Cavitation Detection in a Francis Turbine
,” Int. J. Hydropower Dams
, 3
, pp. 161
–168
.9.
Bajic
, B.
, 1996
, “Vibro-acoustical Diagnosis of Hydroturbine Cavitation: Some Measurement and Analysis Methods
,” Int. J. on Hydropower Dams
, 3
, pp. 169
–178
.10.
Kaye
, M.
, Holenstein
, A.
, Dupont
, Ph.
, and Rettich
, J.
, 1996
, “Acoustic Methods for Monitoring Mechanical Seal Condition and Cavitation Erosion in Hydro Machinery
,” Int. J. on Hydropower Dams
, 3
, pp. 179
–188
.11.
Bourdon, P., Farahat, M., Simoneau, R., Pereira, F., Dupont, Ph., Avellan, F., and Dorey, J.-M., 1996, “Cavitation Erosion Prediction on Francis Turbines—Part I: Measurements on the Prototype,” Proceedings of the XVIII IAHR Symposium on Hydraulic Machinery Cavitation, Valencia, Spain, 1, pp. 534–543.
12.
Dorey, J. M., Laperrousaz, E., Avellan, F., Dupont, Ph., Simoneau, R., and Bourdon, P., 1996, “Cavitation Erosion Reduction on Francis Turbines—Part III: Methodologies of Prediction,” Hydraulic Machinery and Cavitation: Proceedings of the XVIII IAHR Symposium on Hydraulic Machinery and Cavitation, Valencia, Spain, 1, pp. 564–573.
13.
Dupont, Ph., Caron, J.-F., Avellan, F., Bourdon, P., Lavigne, P., Farhat, M., Simoneau, R., Dorey, J.-M., Archer, A., Laperrousas, E., and Couston, M., 1996, “
Cavitation Erosion Prediction on Francis Turbines—Part II: Model Tests and Flow Analysis,” Hydraulic Machinery and Cavitation: Proceedings of the XVIII IAHR Symposium on Hydraulic Machinery and Cavitation, Valencia, Spain, 1, pp. 574–583.
14.
Bajic
, B.
, 1996
, “A Practical Approach to Vibroacoustical Assessment of Turbine Cavitation
,” Int. J. Hydropower Dams
, 3
, pp. 45
–50
.15.
Farhat, M., Bourdon, P., Lavigne, P., and Simoneau, R., 1997, “The Hydrodynamic Aggressive of Cavitating Flows in Hydro Turbines,” Proceedings of the ASME Fluids Engineering Division, Vancouver, ASME, New York, Vol. FEDS-97, Paper No. 3250.
16.
Bajic
, B.
, 1997
, “Inflow Decomposition: A Vibroacoustical Technique to Reveal Details of Hydroturbine Cavitation
,” Int. J. Hydropower Dams
, 4
, pp. 185
–196
.17.
Bajic, B., 1999, “Would Turbine Uprating be Allowable With Respect to Cavitation?—An Example of Vibroacoustic Diagnosis,” Proceedings of the Third International Symposium on Cavitation, Grenoble, 1, pp. 359–362.
18.
Hermann, O., Holenstein, A., Keck, H., and Rettich, J., 1998, “Kavitationsmonitoring an Francisturbinen, 4,” Symposium Methoden, Nutzen und Trends der Diagnostichen U¨berwachung von Maschinenschwingungen und weiteren Zustandsgro¨ssen in Wasserkraftanlagen, Innsbruck, Austria, TIWAG–Schneck, Tagunsband, pp. 207–223.
19.
Bajic
, B.
, 1998
, “Spectrum Tracing: A Vibroacoustic Technique to Identify Mechanisms of Turbine Cavitation
,” Int. J. Hydropower Dams
, 5
, pp. 641
–652
.20.
Bajic, B., 1998, “Neue Methoden der Vibroakustischen Diagnostik der Turbinekavitation,” 10 Internationales Seminar Wasserkraftanlagen, Vienna, Vienna University of Technology, Tagunsband, pp. 447–458.
Copyright © 2002
by ASME
You do not currently have access to this content.