APPLICATION OF ANSYS FLUENT FOR CALCULATION OF PARAMETERS OF DISTRIBUTION OF THE SHOCK WAVE IN KNOTS OF crossings of underground excavations

Sharavin E O; Tsygankov V D; Belshina Yu N

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Home / Journals / Problems of risk management in the technosphere / Volume 2018 Issue 4 / APPLICATION OF ANSYS FLUENT FOR CALCULATION OF PARAMETERS OF DISTRIBUTION OF THE SHOCK WAVE IN KNOTS OF crossings of underground excavations

APPLICATION OF ANSYS FLUENT FOR CALCULATION OF PARAMETERS OF DISTRIBUTION OF THE SHOCK WAVE IN KNOTS OF crossings of underground excavations

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APPLICATION OF ANSYS FLUENT FOR CALCULATION OF PARAMETERS OF DISTRIBUTION OF THE SHOCK WAVE IN KNOTS OF CROSSINGS OF UNDERGROUND EXCAVATIONS

Journal: PROBLEMS OF RISK MANAGEMENT IN THE TECHNOSPHERE Volume 2018 № 4 , 2018

Rubrics: FIRE AND INDUSTRIAL SAFETY

Sharavin E O ¹

Tsygankov V D ²

Belshina Yu N ³

Author and publication information

Authors:

1. Saint-Petersburg university of State fire service of EMERCOM of Russia

2. Saint-Petersburg university of State fire service of EMERCOM of Russia

3. Saint-Petersburg university of State fire service of EMERCOM of Russia

Type:

Article

Pages:

from 40 to 48

Status:

Published

Received:

12.12.2018

Accepted:

20.12.2018

Published:

25.12.2018

Language:

Russian

Keywords:

shock wave, ANSYS FLUENT, mathematical modeling, explosive coal dust, maximum explosion pressure, maximum rate of explosion pressure rise

Abstract and keywords

Abstract (English):
In this article the possibility of use of the ANSYS FLUENT software product for mathematical modeling of shock waves in knots of interface of excavations is considered. On the basis of basic data calculations on the basis of which mathematical models for all existing types of interfaces of excavations are constructed are executed. On the basis of the analysis of literary data coherence of the received experimental results with the actual process of distribution of a shock wave in elastic media is established.

Keywords:
shock wave, ANSYS FLUENT, mathematical modeling, explosive coal dust, maximum explosion pressure, maximum rate of explosion pressure rise

References

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