Premixed Propane–Air Flame Propagation in a Narrow Channel with Obstacles

Yakush, S. E.; Semenov, O. Yu.; Alekseev, M. M.

doi:10.3390/en16031516

Cited by 5 publications

(2 citation statements)

References 34 publications

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“…We used a slow-motion camera to film the process of explosive combustion (290 frames per second). Based on the acquired videos, the front flame location versus time characteristics as well as all axial kinematic parameters of the flame front [16] were defined.…”

Section: Testing Technique To Determine Visible Flame Propagation Rat...mentioning

confidence: 99%

Specific Aspects of Modeling Gas Mixture Explosions in the Atmosphere

Комаров

Korolchenko

Громов

et al. 2023

Fire

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Aspects of mathematical and physical modeling of deflagration explosions emerging during atmospheric (outdoor) accidental explosions are addressed. It has been demonstrated that when physically modeling accidental deflagration explosions, a stoichiometric mixture in the shape of a sphere or hemisphere supported by the ground should be used. This allows us to research the parameters of blast loads for the worst-case accidental scenarios or address the accident using the most conservative approach. A technique has been provided allowing one to create a mixture of a given blend composition in the shape of a sphere or hemisphere supported by the ground in outdoor conditions. It has been demonstrated that there is an ability to conduct modeling studies of accidental atmospheric explosions. We have provided examples of modeling studies of accidental atmospheric explosions; a methodology for analyzing experimental results has also been reviewed. The article discusses the mathematical modeling of outdoor (unobstructed) accidental deflagration explosions. It has been demonstrated that it is most reasonable to base computational experiments on linearized (acoustic) equations of continuum motion, as the visible flame propagation rate emerging during explosive combustion is small (compared to the speed of sound). There has been a satisfactory agreement between the numerical analysis and the experimental data.

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Section: Testing Technique To Determine Visible Flame Propagation Rat...mentioning

confidence: 99%

Specific Aspects of Modeling Gas Mixture Explosions in the Atmosphere

Комаров

Korolchenko

Громов

et al. 2023

Fire

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“…Результаты расчётов показателя преломления света дублировали экспериментальными измерениями угловых отклонений лучей лазера при прохождении через сферический фронт пропановоздушного пламени. Расчёт распределений температуры в сферическом фронте пламени, «однокомпонентном плазмоиде» и шаровой молнии проводили, используя метод цифровой фотометрии [23][24][25]. Цифровые фотографии шаровой молнии, «плазмоида» представлены на рис.…”

Section: рис 3 радиальное распределение концентрации электронов (спло...unclassified

Image Focusing Method for Plasma Structure Analysis

Semenov¹,

Гавриленко²

2023

Успехи Кибернетики / Russian Journal of Cybernetics

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предложен оптический метод изучения структуры короткоживущих, нестационарных и неустойчивых образований низкотемпературной плазмы, использующий ее рефракционные свойства. На основе имеющихся наблюдательных данных об оптических свойствах шаровой молнии и решения интегрального уравнения Абеля получены возможные радиальные распределения показателя преломления, концентрации заряженных частиц и температуры. Правильность предлагаемого подхода проверена в исследовании рефракции света при прохождении через сферический фронт пропановоздушного пламени. Методом цифровой фотометрии проведены сравнительные расчеты температурных полей в пламени, шаровой молнии и «однокомпонентном плазмоиде». this study proposes an optical method for studying the structure of short-lived, non-stationary low-temperature plasmoids using the refractive properties of the plasma. We obtained possible radial distributions of the refractive index, concentration of charged particles, and temperature from the available observations of the ball lightning optical properties and the solution of the Abel integral equation. We verified the proposed method by measuring the refraction of light passing through the spherical front of a propane-air flame. The temperature fields in the flame, ball lightning, and “one-component plasmoid” were compared with digital photometry.

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