A Fitting Formula for Predicting Droplet Mean Diameter for Various Liquid in Effervescent Atomization Spray

Qian, Lijuan; Lin, Jianzhong; Xiong, Hongbin

doi:10.1007/s11666-009-9457-4

Cited by 34 publications

(64 citation statements)

References 20 publications

(10 reference statements)

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“…The particles must be accelerated and melted, once freed from their liquid carrier (transport media with higher momentum than that of gas) (Ref 65 An optimal liquid injection, to avoid droplets poorly treated in the jet fringes, requires that drop velocities and diameters can be controlled separately before their injection into the hot stream (Ref 64,66). Unfortunately, this is not the case with the three means actually used for injection into plasma jets: (1) co-axial atomization by the injection of a low-velocity liquid inside a nozzle where it is fragmented by a gas (mostly Ar) expanding inside the nozzle, (2) mechanical injection producing uniformly spaced droplets, whose diameters depend on the liquid velocity, these two parameters being not controlled separately, (3) effervescent atomization, where a small amount of gas is injected into the liquid before the exit orifice to form a bubbly mixture of gas and liquid (Ref 67,68). On emerging, due to the pressure difference, the gas bubbles rapidly expand and shatter the liquid into ligaments and fine droplets.…”

Section: Suspension Sprayingmentioning

confidence: 99%

The 2016 Thermal Spray Roadmap

et al. 2016

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Considerable progress has been made over the last decades in thermal spray technologies, practices and applications. However, like other technologies, they have to continuously evolve to meet new problems and market requirements. This article aims to identify the current challenges limiting the evolution of these technologies and to propose research directions and priorities to meet these challenges. It was prepared on the basis of a collection of short articles written by experts in thermal spray who were asked to present a snapshot of the current state of their specific field, give their views on current challenges faced by the field and provide some guidance as to the R&D required to meet these challenges. The article is divided in three sections that deal with the emerging thermal spray processes, coating properties and function, and biomedical, electronic, aerospace and energy generation applications.

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Section: Suspension Sprayingmentioning

confidence: 99%

The 2016 Thermal Spray Roadmap

et al. 2016

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“…Most modeling work focused on the external two-phase flow out of the effervescent atomizer exit [13,14,16,23,[27][28][29][30][31][32][33][34][35][36]. For gas-liquid two phase flow, there are two approaches to establish the numerical model.…”

Section: General Remarksmentioning

confidence: 99%

“…Without considering secondary atomization, these models could not account for the spray evolution along the downstream of the exit orifice, which is critical to the engineering applications of atomization sprays. Lin and his co-workers [27][28][29][30][31][32][33][34][35][36] proposed a three-dimensional model to predict the droplet mean size and other spray characteristics by describing both primary and secondary atomizations [27][28][29]. They described the breakup mechanisms for both Newtonian fluid and non-Newtonian fluid by different primary atomization models [30,31], discussing the characteristics of impinging spray field in detail and indicated the proper plate distance [32,33].…”

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confidence: 99%

“…They also studied the evolution of droplets mean diameter along the axial distance, the mean size and statistical distribution of atomized droplets at cross sections, as well as calculating and analyzing the change of droplet velocity and to reveal their inner driving force [27][28][29]31]. They worked on the influence of operating conditions and liquid physical properties [31], concluded the factors for achieving good atomization effects [27][28][29][30][31][32][33][34][35][36], quantified the influences of various operating conditions and liquid physical properties on atomization effects and impinging outcomes [34,35], and extended the use of effervescent atomization to suspension plasma spray [30,37].…”

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confidence: 99%

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Modeling on effervescent atomization: A review

Qian

Lin

2011

Sci. China Phys. Mech. Astron.

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The study and modeling process of effervescent atomization are reviewed. The mechanism of droplet events and the treatment of liquid fragmentation process and dispersed particles are systematically presented, which includes the primary atomization of Newtonian and non-Newtonian fluid, instability analysis, turbulence treatment, particle tracking, secondary atomization and droplets collision. The review on the sub-models involved in the simulation of effervescence is followed by a summary of the achievements of modeling. First is the validation of models; then the parametric study is summarized; the third part introduces the fitting formula of droplet mean size and impinging factors, and finally the scope of future study is indicated. effervescent atomization spray, modeling, review PACS: 47.55.Ca, 47.55.df, 47.60.Kz ALR air-to-liquid ratio, by mass C D drag coefficient D noz nozzle diameter, m d d the droplet diameter, m e internal energy, J F force, N g gravity force, N k turbulent kinetic energy per unit mass k bu breakup frequency, s 1 k  wave number m  mass flow rate, kg/s m mass, kg p pressure kg s 2 /m Q heat source, J q heat flux vector r droplet radius, m Re Reynolds number Sr nterface velocity slip ratio SMD Sauter mean diameter, m U rel relative velocity vector, m/s u, v, w velocity, m/s x radial coordinate, m y axial coordinate, m Greek symbols  volume fraction of gas  deformation parameter  dynamic viscosity, kg/ms  density, kg/m 3  surface tension, kg/m 2  thickness sheet, m  growth rate  viscous dissipation rate, J/ms  distance between the center of one drop and U rel , m  drop oscillation frequency, /s  viscous shear stress tensor Subscript cr criteria g gas l liquid

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“…For effects of liquid properties on the spraying, a fitting formula for predicting droplet mean diameter for various liquids in effervescent atomisation spray has been created and a non-Newtonian suspension plasma spraying in an inductively coupled plasma torch has been modelled. [9,10] Meanwhile, effects of operating conditions on the droplet deposition onto the surface in the atomisation impinging spray with an impinging plate have been studied. [11] Until now, there is little literature on the equal consistency spraying.…”

Section: Introductionmentioning

confidence: 99%

Equal consistency spraying and flow field characteristics of spraying water pipe

et al. 2012

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As one of the key parts of discharging system in the diluted zone at the bottom of high consistency bleaching tower, the spraying water pipe would be used to dilute the pulp uniformly while it was rotating, with a range from 0 to 90 rpm. Fluid dynamics of the three kinds of spraying water pipes such as straight-shaped, spindle-shaped and waist-shaped were studied by performing computational fluid dynamics (CFD) simulations and particle image velocimetry (PIV) measurements. Simulated velocity fields were compared with experiment PIV data. The results from the simulations and experiments are in good agreement. The works show that CFD simulations using the Realisable Ä-ε model combined with the MRF technique can predict the hydrodynamic characteristics in industrial scales spraying water pipes. Spindle-shaped spraying water pipe would be better finished equal consistency spraying water.

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A Fitting Formula for Predicting Droplet Mean Diameter for Various Liquid in Effervescent Atomization Spray

Cited by 34 publications

References 20 publications

The 2016 Thermal Spray Roadmap

The 2016 Thermal Spray Roadmap

Modeling on effervescent atomization: A review

Equal consistency spraying and flow field characteristics of spraying water pipe

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