Analyses of Kolmogorov’s model of breakup and its application into Lagrangian computation of liquid sprays under air-blast atomization

Gorokhovski, Mikhael; Saveliev, V. L.

doi:10.1063/1.1527914

Cited by 83 publications

(44 citation statements)

References 19 publications

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“…Recent studies [7,[9][10][11] have shown that old paradigms for understanding disintegration of Newtonian liquids, based on either cascade theory [12] (leading to log-normal size distributions) or maximum entropy theories [13] (leading to Poisson size distributions) do not adequately capture all physical aspects of these processes. Villermaux et al [10] show that the atomization process for Newtonian liquids can be precisely described by a fragmentationcoalescence scenario [14].…”

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confidence: 99%

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Ligament Mediated Fragmentation of Viscoelastic Liquids

Keshavarz

Houze²,

Moore³

et al. 2016

Phys. Rev. Lett.

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The breakup and atomization of complex fluids can be markedly different than the analogous processes in a simple Newtonian fluid. Atomization of paint, combustion of fuels containing antimisting agents, as well as physiological processes such as sneezing are common examples in which the atomized liquid contains synthetic or biological macromolecules that result in viscoelastic fluid characteristics. Here, we investigate the ligament-mediated fragmentation dynamics of viscoelastic fluids in three different canonical flows. The size distributions measured in each viscoelastic fragmentation process show a systematic broadening from the Newtonian solvent. In each case, the droplet sizes are well described by Gamma distributions which correspond to a fragmentation-coalescence scenario. We use a prototypical axial step strain experiment together with high-speed video imaging to show that this broadening results from the pronounced change in the corrugated shape of viscoelastic ligaments as they separate from the liquid core. These corrugations saturate in amplitude and the measured distributions for viscoelastic liquids in each process are given by a universal probability density function, corresponding to a Gamma distribution with n min ¼ 4. The breadth of this size distribution for viscoelastic filaments is shown to be constrained by a geometrical limit which can not be exceeded in ligament-mediated fragmentation phenomena.

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confidence: 99%

“…However, none of these studies address the role of viscoelasticity on the distribution of droplet sizes. The few attempts in the literature to address the size distributions for polymeric liquids [28,29] base their assumptions on older paradigms [12,13].…”

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confidence: 99%

Ligament Mediated Fragmentation of Viscoelastic Liquids

Keshavarz

Houze²,

Moore³

et al. 2016

Phys. Rev. Lett.

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“…The only macroscopic constraint on the choice of n ij arises from the conservation of mass during a single breakage event (14) and is identically satisfied by equation (13). In addition, equation (13) allows the possibility of producing distribution coefficients consistent with Kolmogorov's hypothesis (see, for instance, Gorokhovski and Saveiliev [26] or Apte et al [11]) that breakups of all sized particles produce the same number of particles.…”

Section: Resultsmentioning

confidence: 78%

Eulerian Multiphase Population Balance Model of Atomizing, Swirling Flows

Rayapati

Panchagnula

Peddieson

et al. 2011

International Journal of Spray and Combustion Dynamics

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An Eulerian/Eulerian multiphase flow model coupled with a population balance model is used as the basis for numerical simulation of atomization in swirling flows. The objective of this exercise is to develop a methodology capable of predicting the local point-wise drop size distribution in a spray, such as would be measured by the Phase Doppler Particle Analyzer (PDA). Model predictions are compared to experimental measurements of particle size distributions in an airblast atomizer spray to demonstrate good qualitative and quantitative agreement. It is observed that the dependence of velocity on drop size inherent in a multiphase description of the drop cloud appears necessary to capture some features of the experimental data. Using this model, we demonstrate the relative contributions of secondary atomization and transport to the variation observed in the downstream spray drop size distribution.

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“…A new approach is developed by Gorokhovski and Saveliev (2003) and Apte et al (2003) based on the Kolmogorov's scenario of the breakup of particles. Kolmogorov wrote a stochastic theory for the breakup of solid particles that describes the cascade of uncorrelated breakage events.…”

Section: Introductionmentioning

confidence: 99%