The present study is aimed at modeling a high-pressure water-mist spray employing two classic numerical codes. To this end, an experimental campaign has been performed both to obtain the input data for the numerical approach and to serve as a validating tool to quantify the predictive capability of the proposed models. In particular, experiments have been conducted to determine volume-flux distribution, drop-size distribution, initial velocity and spray-cone angle. Advanced laser-based diagnostics (Malvern Spraytec and Particle Image Velocimetry) has been employed together with simple ad hoc built instruments to measure these parameters over a prescribed range of high operative pressures (50-90 bar). Specific measurement methodologies have been developed to gain a proper experimental evaluation of any subject of investigation. Then, a computational simulation of the water-mist spray has been im-plemented in Fluent and FDS (Fire Dynamics Simulator) codes. Characteristic drop size, velocity and cone angle have been introduced as input parameters, while volume-flux distribution has been employed to compare numerical results to experimental data as a final validating task. A good qualitative agreement has been gained: the spray phys-ics appears to be properly expressed by the proposed models. However, intrinsic limitations characterize both the experimental tools and the computational codes and may explain some still-to-be-solved discrepancies from a quantitative point of view.

Discharge and Dispersion in Water-Mist Sprays: Experimental and Numerical Analysis

PULVIRENTI, BEATRICE;VALDISERRI, PAOLO
2009

Abstract

The present study is aimed at modeling a high-pressure water-mist spray employing two classic numerical codes. To this end, an experimental campaign has been performed both to obtain the input data for the numerical approach and to serve as a validating tool to quantify the predictive capability of the proposed models. In particular, experiments have been conducted to determine volume-flux distribution, drop-size distribution, initial velocity and spray-cone angle. Advanced laser-based diagnostics (Malvern Spraytec and Particle Image Velocimetry) has been employed together with simple ad hoc built instruments to measure these parameters over a prescribed range of high operative pressures (50-90 bar). Specific measurement methodologies have been developed to gain a proper experimental evaluation of any subject of investigation. Then, a computational simulation of the water-mist spray has been im-plemented in Fluent and FDS (Fire Dynamics Simulator) codes. Characteristic drop size, velocity and cone angle have been introduced as input parameters, while volume-flux distribution has been employed to compare numerical results to experimental data as a final validating task. A good qualitative agreement has been gained: the spray phys-ics appears to be properly expressed by the proposed models. However, intrinsic limitations characterize both the experimental tools and the computational codes and may explain some still-to-be-solved discrepancies from a quantitative point of view.
2009
ICLASS 2009, 11th Triennial International Annual Conference on Liquid Atomization and Spray Systems
1
6
P. E. Santangelo; P. Tartarini; B. Pulvirenti; P. Valdiserri
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/87820
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