THE LAWS OF CAVITATION EROSION OF CONSTRUCTION MATERIALS

Objectives. The aim of the research is to find ways to use cavitation effects in the creation of new technologies and means of applying  unique opportunities arising under conditions of developed bubble  cavitation. Erosive destruction of concrete caused by a submerged  cavitation jet is experimentally investigated in the present work in  order to reveal the regularities of the extent of damage under different flow regimes.

Methods. The tests were carried out using an specially constructed experimental bench, containing a receiving tank from  which water was supplied to the plunger pump with an electric motor and pumped through a high-pressure hose into the cavitator. The  criteria for assessing the intensity of cavitation impact were the  dependence of the erosion zone depth on the test time and the relative distance to the cavitator's cut-off ε for different values of the inlet pressure Po.

Results. Experimental dependences and the analytical function of erosion penetration rate over time, as well as the relative distance  between the sample and the cavitator's cut-off, obtained using the  regression analysis method, are presented. For the selected  parameters of jet flow, the optimum distance from the surface to be destroyed to the cavitator lies across the range of (10-40) ε and reaches maximum effect across the pressure interval of 2.5-12.5  MPa on the average for 30 seconds. The relationship between the  depth and the erosion penetration rate for given pressure  parameters P0, the back pressure Pto, the distance from the  cavitator's cut-off to the surface, as well as the cavitator's diameter, correspond to the maximum erosive effect of cavitation.

Conclusion. The study of cavitation erosion opens up wide  possibilities for estimating the service life of hydrotechnical facilities  under the active influence of submerged cavitation jets. By varying  the parameters of jet flow, it is possible to obtain a different  intensity of erosive destruction of material for the application of this  phenomenon in the purification and crushing of concrete.

1. Rodionov V.P. Struinaya superkavitatsionnaya eroziya. Krasnodar: KubSTU; 2005. 223 s. [Rodionov V.P. Supercavitational jet erosion. Krasnodar: KubGTU; 2005. 223 p. (In Russ.)]

2. Rodionov V.P., Ladenko A.A. Ispol'zovanie gidravlicheskikh strui pri ekspluatatsii i obsluzhivanii ob"ektov dobychi nefti. Krasnodar: KubGTU; 2014. 163 s. [Rodionov V.P., Ladenko A.A. Use of hydraulic jets during operation and maintenance of oil production facilities. Krasnodar: KubSTU; 2014. 163 p. (In Russ.)]

3. Pavlović M., Dojčinović M., Martinović S., Vlahović M., Stević Z., Volkov H.T. Non destructive monitoring of cavitation erosion of cordierite based coatings. Composites Part B. 2016;97(15):84-91. doi:10.1016/j.compositesb.2016.04.073.

4. Pedzich Z., Jasionowski R., Ziabka M. Cavitation wear of structural oxide ceramics and selected composite materials. Journal of the European Ceramic Society 2014;34:3351–3356. doi:10.1016/j.jeurceramsoc.2014.04.022.

5. Lunatsi E. D. Otechestvennyi metod prognozirovaniya kavitatsionnoi erozii lopastnykh nasosov s primeneniem legko razrushayushchikhsya ot kavitatsii materialov i kharakteristik ikh otnositel'noi stoikosti. Inzhenernyi vestnik. 2015;8:53- 65.URL:http://engsi.ru/doc/799918.html(data obrashcheniya:04.05.2017. [Lunatsi E. D. National method for predicting the cavitation erosion of vane pumps made of easily destroyed by cavitation and the characteristics of their relative durability. Engineering Bulletin. 2015; 8:53-65. URL:http://engsi.ru/doc/799918.html(access date: 04.05.2017 (In Russ.)]

6. Pris K. Eroziya. M.: Mir; 1982. 465 s. [Pris K. Erosion. M.: Mir; 1982. 465 p. (In Russ.)]

7. Shestoperov V.Yu. Kavitatsionnoe razrushenie materialov i kriterii otsenki ikh erozionnoi stoikosti. Trudy Nizhegorodskogo gosudarstvennogo tekhnicheskogo universiteta im. R.E. Alekseeva. 2013; 102(5):79-83. URL: http://www.nntu.ru/trudy/2013/05/079-083.pdf(data obrashcheniya:15.04.17.[Shestoperov V.Yu. Cavitation destruction of materials and criteria for assessing their erosion resistance. Proceedings of Nizhny Novgorod State Technical University. 2013;102(5):79-83. URL: http://www.nntu.ru/trudy/2013/05/079-083.pdf(access date: 15.04.17. (In Russ.)]

8. Martinovic S., Vlahovic M., Boljanac T., Dojcinovic M., Volkov-Husovic T. Cavitationresistanceofrefractoryconcrete: Influenceofsinteringtemperature. Journal of the European Ceramic Society. 2013; 33(1):7–14. doi.org/10.1016/j.jeurceramsoc.2012.08.004.

9. Martinovic S., Dojcinovic M., Dimitrijevic M., Devecerski A., Matovic B., Volkov-Husovic T. Implementation of image analysis on thermal shock and cavitation resistance testing of refractory concrete.Journal of the European Ceramic Society. 2010;30(16):3303–3309. doi:10.1016/j.jeurceramsoc.2010.07.041.

10. Bourne N.K., Field J.E. A high-speed photographic study of cavitation damage. Journal of Applied Physics.1995;78(7):4423-4427. http://dx.doi.org/10.1063/1.359850.

11. Hutli E.F., Nedeljkovic S.M., Radovic N.A. Mechanics of submerged jet cavitating action: material properties, exposure time and temperature effects on erosion.Archive of Applied Mechanics. 2008; 78(5):329-341. doi.10.1007/s00419-007-0163-8.

12. Momber A.W. Aggregate liberation from concrete by flow cavitation. International Journal of Mineral Processing. 2004; 74(1–4):177-187. doi:10.1016/j.minpro.2003.10.004.

13. Linß E., Muller A. High performance sonic impulses – a new method for crushing of concrete. International Journal of Mineral Processing. 2004;74(10):199- 208.doi.org/10.1016/j.minpro.2004.08.016.

14. Zange R., Hoyer B., Wollenberg G., Scheibe H.P. Shock waves for liberation comminution of mineral materials. Proc. 9th Europ.Symp.onComminution.Europ.Fed.of Chem. Engng.Albi, 1998. P. 185– 192.

15. Momber A.W. Short-time cavitation erosion of concrete. 2000; 241(1):47–52. doi.org/10.1016/S0043-1648(00)00348-3.

16. Promtov M.A. Perspektivy primeneniya kavitatsionnykh tekhnologii dlya intensifikatsii khimikotekhnologicheskikh protsessov. Vestnik TGTU. 2008; 14(4):861– 869.URL: http://www.tstu.ru/structure/inst/pdf/mo/pma2.pdf [Promtov M.A. Prospects for the use of cavitation technologies for the intensification of chemical- technological processes. Transactions of TSTU 2008; 14(4):861–869. URL: http://www.tstu.ru/structure/inst/pdf/mo/pma2.pdf (In Russ.)]

17. Ladenko A.A., Rodionov V.P., Ladenko N.V. Superkavitatsionnaya tekhnologiya ochistki sistem vodootvedeniya. Energosberezhenie i vodopodgotovka. 2016; 103(5):77- 79.URL: https://elibrary.ru/item.asp?id=27265667. [Ladenko A.A., Rodionov V.P., Ladenko N.V. Supercavitation technology for cleaning sewage systems. Energy and Water. 2016;103(5):77-79.URL: https://elibrary.ru/item.asp?id=27265667.( InRuss.)]

18. Gimranov F.M., Belyaev A.N., Flegentov I.V., Kuts E.V. Perspektivy ispol'zovaniya kavitatsionnoi erozii v poluchenii vodnykh suspenzii metallov. Vestnik kazanskogo tekhnologicheskogo universiteta.2014;17(23):65-67. URL: https://elibrary.ru/item.asp?id=22671002.[Gimranov F.M., Belyaev A.N., Flegentov I.V., Kuts E.V. Prospects for the use of cavitation erosion in the preparation of aqueous metal suspensions. Vestnik Kazanskogo tekhnologicheskogo universiteta.2014; 17(23):65-67. URL: https://elibrary.ru/item.asp?id=22671002. (In Russ.)]

19. Fedotkin I.M., Gulyi I.S. Kavitatsiya, kavitatsionnaya tekhnika i tekhnologiya, ikh ispol'zovanie v promyshlennosti: Ch. 2. Kiev: AO «OKO»; 2000. 898 s. [Fedotkin I.M., Gulyi I.S. Cavitation, cavitation technology and technology, their use in industry: Part 2. Kiev: AO «OKO»; 2000. 898 p. (In Russ.)]

20. GogateP.R., Kabadi A.M. Areview of applications of cavitation in biochemical engineering/biotechnology. Biochemical Engineering Journal. 2009; 44(1):60–72. doi:10.1016/j.bej.2008.10.006.

21. Petkovsek M., ZupancM., Dular M. et al.Rotation generator of hydrodynamic cavitation for water treatment. Separation and Purification Technology.2013;118(3):415–423. doi:10.1016/j.seppur.2013.07.029.