ВПЛИВ ТУРБУЛЕНТНОСТІ ПОТОКУ НА ПРОЦЕСИ ДЕТОНАЦІЇ

ВПЛИВ ТУРБУЛЕНТНОСТІ ПОТОКУ НА ПРОЦЕСИ ДЕТОНАЦІЇ

            Recently, the study of the mechanisms of occurrence and propagation of detonation processes has been of particular interest. The aim of this work is to theoretically analyze the interaction...

Full description

Saved in:
Bibliographic Details
Date:2025
Main Authors: Avramenko, A.A., Tyrinov, A.I., Kovetska, Yu.Yu., Anastasiev, D.V.
Format: Article
Language:Ukrainian
Published: Institute of Engineering Thermophysics of NAS of Ukraine 2025
Online Access:https://ihe.nas.gov.ua/index.php/journal/article/view/612
Tags: Add Tag
No Tags, Be the first to tag this record!
Journal Title:Thermophysics and Thermal Power Engineering

Institution

Thermophysics and Thermal Power Engineering
Description
Summary:            Recently, the study of the mechanisms of occurrence and propagation of detonation processes has been of particular interest. The aim of this work is to theoretically analyze the interaction of a turbulent gas flow with a normal detonation wave. For the first time, a simplified K-ε model was applied to analyze turbulence.             A modified Hugoniot detonation equation is derived for detonation, which takes into account the thermal effect and the level of flow turbulence. Thus, for the first time, the relationship between thermodynamic and gasdynamic processes in a detonation wave was demonstrated. At zero turbulence, combustion products flow from the detonation front at a critical (sonic) velocity. As the degree of turbulence increases, the velocity of detonation products also increases. It is evident that the energy of turbulent fluctuations contributes to an increase in the kinetic energy of the averaged flow behind the detonation wave. It has been shown that the thermal effect weakens the influence of turbulence.             A dependency has been established that allows evaluating the effect of heat release and turbulence on the velocity ahead of the shock wave. It has been demonstrated that both the thermal effect and turbulence lead to an acceleration of the flow ahead of the shock wave. It is also shown that when the flow passes through a shock wave, the value of turbulent viscosity is preserved.

Similar Items