Cavitation erosion – phenomenon and test rigs

• Autorzy: Krella A. K. , Zakrzewska D. E.

Identyfikatory

DOI

10.1515/adms-2017-0028

• Języki publikacji: EN

Abstrakty

EN

The cavitation and cavitation erosion phenomenon have been shortly presented. The main four types of test rigs to investigate the cavitation erosion resistance have been shown. Each type of test design is described and an example of a design is shown. A special attention has been payed to the designs described in the International ASTM Standards: a vibratory design and a cavitating jet cell. There was shown that the design of a test device and the test conditions affect the resistance to cavitation erosion of a material.

Słowa kluczowe

EN

cavitation; cavitation erosion; test rig

PL

kawitacja; erozja kawitacyjna; stanowisko badawcze

• Wydawca: Politechnika Gdańska
• Czasopismo: Advances in Materials Science
• Rocznik: 2018
• Tom: Vol. 18, nr 2(56)
• Strony: 15--26
• Opis fizyczny: Bibliogr. 43 poz., rys., wykr.

Twórcy

autor

Krella A. K.

• Institute of Fluid Flow Machinery, Polish Academy of Sciences, Fiszera 14, 80-231 Gdansk, Poland

autor

Zakrzewska D. E.

• Institute of Fluid Flow Machinery, Polish Academy of Sciences, Fiszera 14, 80-231 Gdansk, Poland
• Gdańsk University of Technology, Interdisciplinary Doctoral Studies, Narutowicza,11/12 80-233 Gdansk, Poland

Bibliografia

• 1. Karimi A., Martin J.L.: Cavitation erosion of materials. International Metals Reviews 31 (1986), pp. 1-26.
• 2. Hubballi V., Sondur V.: A Review on the prediction of cavitation erosion inception in hydraulic control Valves. International Journal of Emerging Technology and Advanced Engineering 3 (2013), 110-119.
• 3. Bourne N.K.: On impacting liquid jets and drops onto polymethylmethacrylate targets, Proc. R. Soc. A (2005) 461, 1129–1145
• 4. Kuiper G.: Cavitation research and ship propeller design, Applied Scientific Research (1998) 58, 33–50.
• 5. Dular M., Stoffel B., Sirok B., Development of a cavitation erosion model. Wear 261 (2006) 642-655.
• 6. Brennen Ch.E.: Cavitation and bubble Dynamics. Oxford University Press, New York, 1977.
• 7. Śniegocka B., Szkodo M., Chmiel J.: Influence of spatial structures of 316L stainless steel on its cavitation resistance. Solid State Phenomena 225 (2015) 109-114.
• 8. Wójs K.: Kawitacja w cieczach o różnych właściwościach reologicznych. A. Kaczak [ed.], Oficyna Wydawnicza Politechniki Wrocławskiej, Wrocław, 2004. (in Polish)
• 9. Knapp R. T., Daily J. W., Hammit F.G.: Cavitation, McGraw-Hill, New York 1970.
• 10. Lauterborn W., Bolle H.: Experimental investigations of cavitation-bubble collapse in the neighbourhood of a solid boundary. J. Fluid Mech. 72, part 2 (1975) 391-399.
• 11. Lindau O., Lauterborn W.: Cinematographic observation of the collapse and rebound of a laser-produced cavitation bubble near a wall, J. Fluid Mech. (2003), vol. 479 327–348.
• 12. Philipp, A., Lauterborn, W.: Cavitation erosion by single laser-produced bubbles. J. Fluid Mech. 361 (1998) 75–116.
• 13. Kim K., Chahine G. L., Franc J.-P., Karimi A.: Advanced Experimental and Numerical Techniques for Cavitation Erosion Prediction. Kim K., Chahine G. L., Franc J.-P., Karimi A. [eds], Springer International Publishing, Dordrecht, 2014.
• 14. Laterborn W.: Cavitation and Coherent Optics, 1980, Proc. Of the 1st. International Cnference, Göttingen, Fed. Rep. Of Germany, 1979, 3-12.
• 15. Steller J., Gireń G.: International Cavitation Erosion Test. Final report. Zeszty Naukowe IMP PAN, Gdańsk, 2015.
• 16. Jasionowski R.: Badania odporności materiałów na erozję kawitacyjną, Cz. I Stanowiska badawcze. Zeszyty Naukowe WSM Szczecin nr 72, Szczecin 2003. (in Polish)
• 17. Kmieć M., Karpiński B., Szkodo M.: Cavitation erosion of P110 steel in different drilling muds. Advances in Materials Science 16 (2016) 57-66.
• 18. Li Z., Han J., Lu J., Zhou J., Chen J.: Vibratory cavitation erosion behavior of AISI 304 stainless steel in water at elevated temperatures. Wear 321 (2014) 33-37.
• 19. Mitelea I., Bordeasu I., Pelle M., Craciunescu C.: Ultrasonic cavitation erosion of nodular cast iron with ferrite-pearlite microstructure. Ultrasonics Sonochemistry 23 (2015) 385-390.
• 20. Niederhofer P., Huth S.: Cavitation erosion resistance of high intersitial CrMnCN austenitic stainless steel. Wear 301 (2013) 457-466.
• 21. Kim S-J., Lee S-J., Chong S-O.: Electrochemical characteristics under cavitation-erosion for STS 316L in seawater. Materials Research Bulletin 58 (2014) 244-247
• 22. Wu J-h., Wang Y., Ma F., Gou W-j. Cavitation erosion in bloods. Journal of Hydrodynamics, Ser. B, 29 (2017) 724-727.
• 23. Gottardi G., Tocci M., Montesano L., Pola A.: Cavitation erosion behaviour of an innovative aluminium alloy for Hybrid Aluminium Forging, Wear 394–395 (2018) 1-10.
• 24. Hu H.X., Zheng Y.G.: The effect of sand particle concentrations on the vibratory cavitation erosion. Wear 384–385 (2017) 95-105.
• 25. Momma T.: Cavitation Loading and Erosion Produced by a Cavitating Jet. PhD thesis, Nottingham, 1991.
• 26. Lichtarowicz, A. and Sakkejha, F., "Cutting with Cavitating Jets," Paper G6, Proc. 1st Int. Symp. Jet Cutting Tech., BHRA, Coventry, UK, April 1972
• 27. Hutli E., Nedeljkovic M.S., Radovic N.A., Bonyár A., The relation between the high speed submerged cavitating jet behaviour and the cavitation erosion process, International Journal of Multiphase Flow 83 (2016) 27–38.
• 28. Lipej A.: Cavitation and dynamic problems. S. Muhic (ed), 6th IAHR meeting of the Working Group, IAHRWG 2015, Slovenia, September 9-11, 2015.
• 29. Thapa B., Chaudhary P., Dahlhaug O., Upadhyay P.: Study of combined effect of sand erosion and cavitation in hydraulic turbines. Proc. International Conference on Small Hydropower, Sri Lanka, 2007, 22-24.
• 30. Hutli E. A. F., Nedeljković M.S.: Investigation of a Submerged Cavitation Jet Behaviour: Part One- The Phenomenon, Detection Technique and Sono-Luminescence. FME Transactions vol. 35 (2007) 113-119.
• 31. Hutli E. A. F., Nedeljković M.S.: Investigation of a Submerged Cavitation Jet Behaviour: Part Two – Influences of operating conditiond, geometrical parameters and arrangements of detection system. FME Transactions vol. 35 (2007) 121-128.
• 32. Soyama H.: Effect of nozzle geometry on a standard cavitation erosion test using a cavitating jet, Wear 297 (2013) 895–902
• 33. Peng Ch., Tian S., Li G.: Joint experiments of cavitation jet: High-speed visualization and erosion test. Ocean Engineering 149 (2018) 1-13.
• 34. Steller J.: International Cavitation Erosion Test and quantitative assessment of material resistance to cavitation. Wear 233–235 (1999) 51 – 64.
• 35. Veerabhadra R., Syamala Rao B., Buckley D.H.: Size scale effect in cavitation erosion. Proc. Cavitation and Multiphase Flow Forum, Louisiana, 1984, 11-17.
• 36. Dular M., Petkovšek M., On the mechanisms of cavitation erosion – Coupling high speed videos to damage patterns, Experimental Thermal and Fluid Science 68 (2015) 359-370.
• 37. He J., Hammitt F. G.: Comparision of cavitation erosion test results from venturi and vibratory facilities. Wear vol. 76 (1982) 269–292.
• 38. Krella A.: The experimental resistance parameter for TiN coating to cavitation action. Advances in Materials Science 10 (23) (2010) 4-18
• 39. Dular M., Stoffel B., Širok B.: Development of a cavitation erosion model. Wear 261 (2006) 42-655.
• 40. Hart D., Whale D.: A review of cavitation-erosion resistance weld surfacing alloys for hydroturbines. Eutectic Cast. Pty. Ltd. (2007) 15-30.
• 41. Mann B.S.: Boronizing of cast martensitic chromium nickel stainless steel and its abrasion and cavitation-erosion behavior. Wear v.208 (1997), 125-131.
• 42. Bazanini G., Bressan J. D., Klems M.A.: Cavitation erosion wear of metallic specimens using the new compact rotating disk device. Thermal Engineering Vol. 7 (2008), 31-36.
• 43. Rashed M.K., Abdulbari H.A., Salled M.A., Ismail M.H.: Rotating disc apparatus: types, developments and future applications. Modern Applied Science 10 (2016) 198-229.

Uwagi

PL

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).