Safety in Technosphere

Безопасность в техносфере

1998-071X

10159

10.12737/16965

Аналитический обзор

Analytical review

Аналитический обзор

Physical Modeling of Concentrated Fire Whirls (Review)

Физическое моделирование концентрированных огненных вихрей (обзор)

Вараксин

А. Ю.

Varaksin

A. Yu.

varaksin_a@mail.ru

доктор физико-математических наук;

doctor of physical and mathematical sciences;

Объединённый институт высоких температур Российской академии наук Joint Institute for High Temperatures of the Russian Academy of Sciences

25 10 2015

4 5 62 78

https://naukaru.ru/en/nauka/article/10159/view

Огненные смерчи являются примером экологической катастрофы, наносящей огромный ущерб окружающей среде и приводящей к многочисленным разрушениям и человеческим жертвам. Огненные вихри — редкая, но потенциально катастрофическая форма огня, драматически увеличивающая опасность происходящих природных и техногенных пожаров и их последствия. Они возникают при крупных лесных пожарах, массовых пожарах в городах и авариях на крупных пожароопасных объектах нефтехимии, лесоперерабатывающей промышленности и т.п. Полномасштабное физическое моделирование огненных вихрей осложнено большими рисками, дороговизной и сложностями контролирования граничных условий, поэтому наибольший объем информации получают при проведении маломасштабных экспериментов. В обзоре приводится описание экспериментальных установок различных типов для генерации стационарных и нестационарных огненных вихрей и изучения их характеристик. Представлены и проанализированы результаты экспериментов по скорости горения и основным параметрам огненных вихрей (высота, скорость, температура). Проведены оценки критической скорости бокового ветра, при которой образуются наиболее интенсивные огненные вихри. Рассмотрены особенности и условия генерации огненных вихрей при пожарах в замкнутых пространствах.

Fire tornadoes are an example of environmental disaster, which causes an enormous damage to the environment and leads to destruction and human fatalities. Fire whirls is a rare but potentially catastrophic form of fire, which dramatically increases the danger of occurring natural and man-made fires and their consequences. They occur in large forest fires, massive fires in cities and major accidents at flammable objects of petrochemical, timber industry, etc. providing full physical modeling of fire whirls is complicated by high risks, costs and complexity of controlling boundary conditions, so the major part of information is obtained through small-scale experiments. The review describes experimental facilities for generating different types of stationary and non-stationary fire vortices and studying their characteristics. We presented and analyzed the results of experiments on the burning rate and the main parameters of fire whirls (height, velocity, temperature).We estimated critical velocity of crosswinds, which yields to generation of the most intensive fire vortices. The features and conditions for the generation of fire whirls during the fires in closed spaces were considered.

огненные вихри концентрированные вихри физическое моделирование.

fire whirls concentrated vortices physical modeling.

1. ВведениеВоздушные и огненные смерчи являются примерами экологических катастроф, наносящих огромный ущерб окружающей среде и приводящих к многочисленным разрушениям и человеческим жертвам. Огненные вихри — редкая, но потенциально катастрофическая форма огня. Эти вертикально ориентированные вращающиеся огненные факелы драматически увеличивают опасность происходящих природных и техногенных пожаров и их последствия [1–4]. По сравнению с воздушными смерчами огненные смерчи довольно редкие природные явления, которые возникают при крупных лесных пожарах, массовых пожарах в городах и авариях на крупных пожароопасных объектах нефтехимии, лесоперерабатывающей промышленности и других (рис. 1, см. обл., с. 3). Последствиями атомной бомбардировки Хиросимы (1945 г.), массированных бомбардировок Гамбурга (1943 г.) и Дрездена (1945 г.), Касселя и Дармштадта стали опасные продолжительные неуправляемые пожары [5]. После множественных одновременных возгораний в условиях города, плотно насыщенного горючими материалами, пламена сливались, образуя достаточно однородно горящую площадь, вследствие чего возникли огненные смерчи. В 1926 г. в Калифорнии (США) в результате удара молнии в нефтехранилище также наблюдались огненные смерчи [6].

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