@article{5881e9b5ca124d63a1034b11991b1124,
title = "Modeling and computation of unsteady cavitation flows in injection nozzles",
abstract = "This paper deals with the numerical simulation of cavitation phenomena inside injector nozzles. The numerical approach combines the Volume-of-Fluid technique (VOF) with a model predicting the growth and collapse of bubbles. To model the turbulence effect a k-ω model is introduced for the two-phase flow. Calculations show that the numerical method is able to reproduce complex cavitation phenomena as observed in injection nozzle experiments.",
keywords = "Bubble growth, Cavitation, Croissance de bulles, Dispersed two-phase microhydrodynamics, Injecteurs, Injection nozzle, Microhydrodynamique diphasique, Numerical simulation, Separation, Simulation num{\'e}rique",
author = "Weixing Yuan and J{\"u}rgen Sauer and Schnerr, {G{\"u}nter H.}",
note = "Funding Information: The authors gratefully acknowledge the support from the Deutsche Forschungsgemeinschaft under Grant Schn-352/16-1 during performing this work. Sincere thanks are given to Dr.-Ing. P. Roosen and Dipl.-Ing. O. Genge of the Institute for Technical Thermodynamics of the RWTH Aachen (Germany) for providing the experimental data.",
year = "2001",
month = oct,
doi = "10.1016/S1296-2139(01)01120-4",
language = "English",
volume = "2",
pages = "383--394",
journal = "Mecanique et Industries",
issn = "1296-2139",
publisher = "EDP Sciences",
number = "5",
}