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Analysis of the Evolution of the Surface Density Function During Premixed V-Shaped Flame–Wall Interaction in a Turbulent Channel Flow at <i> Re <sub>τ</sub> </i> = 395

Reo Kai, Abhishek Lakshman Pillai, Umair Ahmed, Nilanjan Chakraborty, Ryoichi Kurose

2022Combustion Science and Technology16 citationsDOIOpen Access PDF

Abstract

The flame–turbulence interaction and statistical behavior of the surface density function (SDF; i.e. magnitude of the reaction progress variable gradient) in the vicinity of the wall for a stoichiometric methane-air flame are investigated using a three-dimensional direct numerical simulation of a turbulent premixed V-flame interacting with an isothermal inert wall in a fully developed turbulent channel flow at a friction Reynolds number Reτ=395. The results show that the mean SDF significantly decreases in the viscous sublayer in comparison to the corresponding values for the same reaction progress variable in the unstretched laminar flame. Moreover, the mean values of SDF for a given value of reaction progress variable decrease in the downstream direction with the progress of flame quenching in all zones of turbulent boundary layer. The effective normal strain rate aneff (=an+n⋅∇Sd), which acts to reduce the SDF as it increases, is much higher in the viscous sublayer than in the other layers. In the viscous sublayer, the contribution of the gradient of displacement speed in the flame-normal direction (n⋅∇Sd) to aneff has been shown to dominate the fluid-dynamic normal strain rate (an). This tendency is qualitatively similar to the previous findings for a V-flame interacting with an isothermal inert wall at Reτ=110. However, the maximum mean value of aneff at Reτ=395 is approximately twice of that at Reτ=110, which causes a sharper drop in the SDF in the viscous sublayer at higher Reτ.

Topics & Concepts

Laminar flowTurbulenceMechanicsLaminar sublayerBoundary layerPremixed flameThermodynamicsChemistryReynolds numberDirect numerical simulationVelocity gradientLaminar flame speedMaterials scienceCombustionPhysicsCombustorPhysical chemistryCombustion and flame dynamicsAdvanced Combustion Engine TechnologiesFire dynamics and safety research
Analysis of the Evolution of the Surface Density Function During Premixed V-Shaped Flame–Wall Interaction in a Turbulent Channel Flow at <i> Re <sub>τ</sub> </i> = 395 | Litcius