Litcius/Paper detail

Chapman–Jouguet deflagration criteria and compressibility dynamics of turbulent fast flames for turbulence-induced deflagration-to-detonation transition

Hardeo M. Chin, Jessica Chambers, Alexei Poludnenko, Vadim N. Gamezo, Kareem A. Ahmed

2023Physics of Fluids16 citationsDOIOpen Access PDF

Abstract

This work characterizes the compressibility dynamics in turbulent fast flames for a range of turbulent flame speeds. These turbulent fast flames experience increased effects of compressibility through the formation of strong shocks and may develop a runaway acceleration combined with a pressure buildup that leads to turbulence induced deflagration-to-detonation transition (tDDT). Simultaneous high-speed particle image velocimetry, OH* chemiluminescence, schlieren, and pressure measurements are used to examine the reacting flow field and flame dynamics. We examine flames with turbulent flame speeds ranging from 100 to 600 m/s. At lower turbulent flame speeds, the flame is not able to produce favorable background conditions for deflagration-to-detonation transition (DDT) onset, and thus flame compressibility and turbulence amplification are less dominant, resulting in a weaker acoustic coupling between the flame and compressed region. As the turbulent burning velocities exceed the Chapman–Jouguet deflagration speed, favorable background conditions are produced, as we observe flame-generated shocks and flame-generated turbulence with higher turbulent velocities and larger turbulent scales. At this regime, the flame is categorized to be at the runaway transition regime that leads to tDDT.

Topics & Concepts

TurbulenceMechanicsDeflagration to detonation transitionDeflagrationPhysicsDetonationPremixed flameCompressibilityFlame speedThermodynamicsSchlieren photographyCombustionCombustorFlow (mathematics)ChemistryFlow visualizationOrganic chemistryExplosive materialCombustion and Detonation ProcessesFire dynamics and safety researchCombustion and flame dynamics