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Large-eddy simulation of cavitating nozzle flow and primary jet break-up

Journal Article · · Physics of Fluids (1994)
DOI:https://doi.org/10.1063/1.4928701· OSTI ID:22482476
; ; ;  [1];  [1]
  1. Institute of Aerodynamics and Fluid Mechanics, Technische Universität München, Boltzmannstr. 15, 85748 Garching bei München (Germany)
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We employ a barotropic two-phase/two-fluid model to study the primary break-up of cavitating liquid jets emanating from a rectangular nozzle, which resembles a high aspect-ratio slot flow. All components (i.e., gas, liquid, and vapor) are represented by a homogeneous mixture approach. The cavitating fluid model is based on a thermodynamic-equilibrium assumption. Compressibility of all phases enables full resolution of collapse-induced pressure wave dynamics. The thermodynamic model is embedded into an implicit large-eddy simulation (LES) environment. The considered configuration follows the general setup of a reference experiment and is a generic reproduction of a scaled-up fuel injector or control valve as found in an automotive engine. Due to the experimental conditions, it operates, however, at significantly lower pressures. LES results are compared to the experimental reference for validation. Three different operating points are studied, which differ in terms of the development of cavitation regions and the jet break-up characteristics. Observed differences between experimental and numerical data in some of the investigated cases can be caused by uncertainties in meeting nominal parameters by the experiment. The investigation reveals that three main mechanisms promote primary jet break-up: collapse-induced turbulent fluctuations near the outlet, entrainment of free gas into the nozzle, and collapse events inside the jet near the liquid-gas interface.

OSTI ID:
22482476
Journal Information:
Physics of Fluids (1994), Journal Name: Physics of Fluids (1994) Journal Issue: 8 Vol. 27; ISSN 1070-6631; ISSN PHFLE6
Country of Publication:
United States
Language:
English

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Related Subjects

42 ENGINEERING
71 CLASSICAL AND QUANTUM MECHANICS
GENERAL PHYSICS
ASPECT RATIO
CAVITATION
COMPRESSIBILITY
ENTRAINMENT
EQUILIBRIUM
FLUCTUATIONS
FUELS
HOMOGENEOUS MIXTURES
JETS
LARGE-EDDY SIMULATION
LIQUIDS
NOZZLES
THERMODYNAMIC MODEL
VALVES
VAPORS