| dc.creator | Lain, Santiago | |
| dc.creator | Rodríguez, Sara A | |
| dc.creator | Teran, Leonel | |
| dc.creator | Jung, Sunghwan | |
| dc.date.accessioned | 2019-11-05T15:23:57Z | |
| dc.date.accessioned | 2022-09-22T18:36:54Z | |
| dc.date.available | 2019-11-05T15:23:57Z | |
| dc.date.available | 2022-09-22T18:36:54Z | |
| dc.date.created | 2019-11-05T15:23:57Z | |
| dc.date.issued | 2018 | |
| dc.identifier | 10706631 | |
| dc.identifier | http://hdl.handle.net/10614/11392 | |
| dc.identifier | https://doi.org/10.1063/1.5063472 | |
| dc.identifier.uri | http://repositorioslatinoamericanos.uchile.cl/handle/2250/3455198 | |
| dc.description.abstract | Hard particle erosion and cavitation damage are two main wear problems that can affect the internal components of hydraulic machinery such as hydraulic turbines or pumps. If both problems synergistically act together, the damage can be more severe and result in high maintenance costs. In this work, a study of the interaction of hard particles and cavitation bubbles is developed to understand their interactive behavior. Experimental tests and numerical simulations using computational fluid dynamics were performed. Experimentally, a cavitation bubble was generated with an electric spark near a solid surface, and its interaction with hard particles of different sizes and materials was observed using a high-speed camera. A simplified analytical approach was developed to model the behavior of the particles near the bubble interface during its collapse. Computationally, we simulated an air bubble that grew and collapsed near a solid wall while interacting with one particle near the bubble interface. Several simulations with different conditions were made and validated with the experimental data. The experimental data obtained from particles above the bubble were consistent with the numerical results and the analytical study. The particle size, density, and position of the particle with respect to the bubble interface as well as the bubble position strongly affected the maximum velocity of the particles | |
| dc.language | eng | |
| dc.publisher | AIP Publishing | |
| dc.relation | 12 | |
| dc.relation | 30 | |
| dc.relation | Teran, L. A., Rodriguez, S. A., Laín, S., & Jung, S. (2018). Interaction of particles with a cavitation bubble near a solid wall. Physics of Fluids, 30(12), 123304 | |
| dc.relation | Physics of fluids | |
| dc.relation | 1 U. Dorji, R. Ghomashchi, Hydro turbine failure mechanisms: An overview, Engineering Failure Analysis 44 (2014) 136{147. | |
| dc.relation | 2 F. Avellan, Introduction to cavitation in hydraulic machinery, in: The 6th International Conference on Hydraulic Machinery and Hydrodynamics, Timisoara, Romania. | |
| dc.relation | 3 P. Kumar, R. Saini, Study of cavitation in hydro turbinesa re-view, Renewable and Sustainable Energy Reviews 14 (2010) 374-383. | |
| dc.relation | 4 H. P. Neopane, Sediment erosion in hydraulic turbines, Global Journal of researches in engineering, Mechanical and mechanics engineering 11 (2010). | |
| dc.relation | 5. I. Hutchings, Tribology: friction and wear of engineering mate-rials. 1992, Arnold, London (1992). | |
| dc.relation | 6 O. Zambrano, D. Garc a, S. Rodr guez, J. Coronado, The mild-severe wear transition in erosion wear, Tribology Letters 66 (2018) 95. | |
| dc.relation | 7 J.-P. Franc, J.-M. Michel, Fundamentals of cavitation, volume 76, Springer Science & Business Media, 2006. | |
| dc.relation | 8 K.-H. Kim, G. Chahine, J.-P. Franc, A. Karimi, Advanced ex-perimental and numerical techniques for cavitation erosion pre-diction, volume 106, Springer, 2014. | |
| dc.relation | 9 H. Amarendra, G. Chaudhari, S. Nath, Synergy of cavitation and slurry erosion in the slurry pot tester, Wear 290 (2012) 25-31. | |
| dc.relation | 10 S. Li, Cavitation enhancement of silt erosionan envisaged micro model, Wear 260 (2006) 1145-1150. | |
| dc.relation | 11 Y. Tang, L. Liang, Y. X. Pang, Z. M. Zhu, Y. Xu, Research of erosion, cavitation and their interactive wears of uid machinery three-phase ow, in: Applied Mechanics and Materials, volumen 212, Trans Tech Publ, pp. 1261-1266. | |
| dc.relation | 12 Z. Tao, C. Cichang, L. Dongli, L. Dan, Mechanism of silt abrasión enhanced by cavitation in silt laden water ow [j], Journal of Drainage and Irrigation Machinery Engineering 4 (2011) 007. | |
| dc.relation | 13 T. Zhang, C. Chen, D. Li, D. Lv, Experimental study of mech-anism of silt abrasion in uenced by cavitation in hydraulic ma-
chinery, in: ASME-JSME-KSME 2011 Joint Fluids Engineering Conference, American Society of Mechanical Engineers, pp. 195-201. | |
| dc.relation | 14 J. Lian, W. Gou, H. Li, H. Zhang, E ect of sediment size on dam-age caused by cavitation erosion and abrasive wear in sediment-water mixture, Wear 398 (2018) 201-208. | |
| dc.relation | 15 W. Soh, B. Willis, A ow visualization study on the movements of solid particles propelled by a collapsing cavitation bubble, Ex-perimental thermal and uid science 27 (2003) 537{544. 16S. Poulain, G. Guenoun, S. Gart, W. Crowe, S. Jung, Particle motion induced by bubble cavitation, Physical review letters 114 (2015) 214501. | |
| dc.relation | 17 A. Osterman, M. Dular, B. Sirok, Numerical simulation of a near-wall bubble collapse in an ultrasonic eld, Journal of Fluid Science and Technology 4 (2009) 210{221. | |
| dc.relation | 18 A. Philipp, W. Lauterborn, Cavitation erosion by single laser-produced bubbles, Journal of Fluid Mechanics 361 (1998) 75{116. | |
| dc.relation | 19 E. Johnsen, T. Colonius, Numerical simulations of non-spherical bubble collapse, Journal of uid mechanics 629 (2009) 231{262. | |
| dc.relation | 20 A. Jayaprakash, C.-T. Hsiao, G. Chahine, Numerical and exper-imental study of the interaction of a spark-generated bubble and a vertical wall, Journal of Fluids Engineering 134 (2012) 031301. | |
| dc.relation | 21 P. Dunstan, S. Li, Cavitation enhancement of silt erosion: Nu-merical studies, Wear 268 (2010) 946{954. | |
| dc.relation | 22 O. Supponen, D. Obreschkow, P. Kobel, M. Farhat, Detailed jet dynamics in a collapsing bubble, in: Journal of Physics:
Conference Series, volume 656, IOP Publishing, p. 012038. | |
| dc.relation | 23 Y. Lu, J. Katz, A. Prosperetti, Dynamics of cavitation clouds within a high-intensity focused ultrasonic beam, Physics of uids 25 (2013) 073301. | |
| dc.relation | 24 K. S. Suslick, N. C. Eddingsaas, D. J. Flannigan, S. D. Hop-kins, H. Xu, Extreme conditions during multibubble cavitation: Sonoluminescence as a spectroscopic probe, Ultrasonics sono-chemistry 18 (2011) 842{846. | |
| dc.relation | 25A. Zhang, P. Cui, Y. Wang, Experiments on bubble dynamics
between a free surface and a rigid wall, Experiments in uids 54 (2013) 1602. | |
| dc.relation | 26 A. FLUENT, Theory guide release 16.1, Ansys Inc (2015). | |
| dc.relation | 27 D. Brown, Tracker video analysis and modeling tool for physics education, 2018. | |
| dc.relation | 28 M. S. Plesset, A. Prosperetti, Bubble dynamics and cavitation, Annual review of uid mechanics 9 (1977) 145{185. | |
| dc.relation | 29 NASA, Drag of a sphere, 2010. | |
| dc.rights | https://creativecommons.org/licenses/by-nc-nd/4.0/ | |
| dc.rights | info:eu-repo/semantics/OpenAccess | |
| dc.rights | Atribución-NoComercial-SinDerivadas 4.0 Internacional (CC BY-NC-ND 4.0) | |
| dc.rights | Derechos Reservados - Universidad Autónoma de Occidente | |
| dc.source | https://aip.scitation.org/doi/10.1063/1.5063472 | |
| dc.title | Interaction of particles with a cavitation bubble near a solid wall | |
| dc.type | Artículo de revista | |
