Physicomathematical Modeling of Explosive Dispersion of Liquid and Powders

Kudryashova, O. B.; Vorozhtsov, B.I.; Muravlev, Eugene V.; Akhmadeev, I. R.; Павленко, А. А.; Titov, S. S.

doi:10.1002/prep.200900101

Cited by 11 publications

(5 citation statements)

References 1 publication

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“…The both designs under question generate acoustic vibrations that create conditions for cavitation. Let us show, following the report [6], what droplet size one should expect in this case.…”

Section: Cavitation and Droplet Diametermentioning

confidence: 80%

“…The aerosol generation process by using the impulse atomizer was considered earlier [6]. The triggered explosive charge produces a shock wave that translates into a series of resonant acoustic vibrations with wavelength λ=L and frequency c f L  .…”

Section: Impulse Atomizermentioning

confidence: 99%

“…The aerodynamic atomization has a theoretical limit on the size of the resulting droplets as a function of the jet outflow rate [5]. However, there is a possibility to produce fine aerosol even at moderate outflow velocities and energy inputs for atomization demonstrated by the example of an impulse aerosol generator powered by a high-energy material (HEM) [6]. It was shown that droplet' size could be reduced by the cavitation phenomenon in the impulse atomization as compared to aerodynamic atomization techniques.…”

Section: Introductionmentioning

confidence: 99%

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The role of cavitation in submicron aerosol dispersion

et al. 2018

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Here we discuss the problem of atomizing submicron aerosols by special design atomizers enabling the cavitation regime. The formation of submicron aerosol was studied using an impulse atomizer model powered by a high-energy material and an atomizer model with a special spray nozzle generating countercurrent flows. For these atomizers, the role played by cavitation in producing submicron liquid aerosols is demonstrated herein. A mathematical model is also suggested to describe the aerosol cloud genesis. The cavitation development critical pressure, outflow velocity, and the resulting droplet sizes were evaluated. The aerosol particle size and concentration were experimentally measured by optical methods. The measured disperse parameters of aerosols during the origination and propagation of the aerosol cloud resulted from the cavitation-assisted atomization of liquids are reported: the intrinsic particle diameter of water aerosol is 10…30 μm depending on the features of the atomizer designs and their operating regimes.

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Section: Cavitation and Droplet Diametermentioning

confidence: 80%

Section: Impulse Atomizermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The role of cavitation in submicron aerosol dispersion

et al. 2018

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“…The proposed technique for decontaminating aerosol clouds utilizes a pulsed generation method, which was introduced in [ 13 , 14 , 15 ]. This method employs high-energy materials to rapidly spray powders or liquids into the atmosphere.…”

Section: Introductionmentioning

confidence: 99%

Mathematical Model of Propagation of an Aerosol Created by an Impulse Method in Space

Kudryashova,

Sokolov,

Vorozhtsov

2023

Materials

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When developing neutralization systems for harmful agents, it is necessary to understand the mechanisms of the formation and evolution of an aerosol cloud in a closed or open space. Effective decontamination with aerosol clouds is provided by a rather high particle concentration and dispersion in an open space or on contaminated surfaces. This paper considers neutralization systems based on pulsed powder aerosol generators. It is shown that an aerosol cloud consisting of micron- and submicron-sized particles appears for several seconds after spraying. A further evolution of the aerosol cloud in a room is associated with the gravitational settling, diffusion, and coagulation of particles and their settling on the walls and ceiling. In the case of an open space or a ventilation system in a room, the evolution of the aerosol cloud is affected by the airflow. The main purpose of this paper is to determine the most important parameters and critical conditions of pulsed aerosol generation. A mathematical model is, thus, proposed for pulsed aerosol generation, and its parametric study is conducted in the most typical conditions. The purpose performance predicted by the model is the mass concentration of aerosol particles in the air and on surfaces, depending on the time of particle spraying and dispersion.

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“…In this work, we do not consider detailed models for the interaction between the shock wave and the packed particles (e.g. [8][9][10][11]) nor the chemical aspects which are beyond the scope of this work. 1 We make the following simplifying assumptions:…”

Section: Introductionmentioning

confidence: 99%

On firework blasts and qualitative parameter dependency

Zohdi

2016

Proc. R. Soc. A.

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In this paper, a mathematical model is developed to qualitatively simulate the progressive time-evolution of a blast from a simple firework. Estimates are made for the blast radius that one can expect for a given amount of detonation energy and pyrotechnic display material. The model balances the released energy from the initial blast pulse with the subsequent kinetic energy and then computes the trajectory of the material under the influence of the drag from the surrounding air, gravity and possible buoyancy. Under certain simplifying assumptions, the model can be solved for analytically. The solution serves as a guide to identifying key parameters that control the evolving blast envelope. Three-dimensional examples are given.

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Physicomathematical Modeling of Explosive Dispersion of Liquid and Powders

Cited by 11 publications

References 1 publication

The role of cavitation in submicron aerosol dispersion

The role of cavitation in submicron aerosol dispersion

Mathematical Model of Propagation of an Aerosol Created by an Impulse Method in Space

On firework blasts and qualitative parameter dependency

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