On the formation of a tulip flame in closed and semi-open tubes

TL;DR

This study investigates the formation of tulip flames in tubes using high-resolution simulations, revealing the critical role of rarefaction waves and flow interactions in shaping the flame morphology.

Contribution

It provides a detailed numerical analysis of tulip flame formation, highlighting the influence of rarefaction waves and flow dynamics in different tube configurations.

Findings

Rarefaction waves are key to tulip flame formation.

Flow interactions cause the inverted tulip velocity profile.

Flame shape closely follows the axial velocity profile.

Abstract

The paper examines the mechanism of the tulip flame formation for the flames propagating in closed tubes of various aspect ratios and in a half-open tube. The formation of tulip flames in 2D channels is studied using high resolution direct numerical simulations of the reactive Navier Stokes equations coupled with a detailed chemical model for a stoichiometric hydrogen/air flame. It is shown that rarefaction waves generated by the flame during the deceleration stage play a key role in the tulip-shaped flame formation. The interaction of the reverse flow created behind the rarefaction wave with previously produced be accelerating flame flow in the unburned gas, results in the decrease of the flow velocity in the near field zone ahead of the flame and in the increase of the boundary layer thickness. The profile of the axial velocity close ahead of the flame takes the form of an inverted tulip. Therefore, the flame front acquires a tulip shape repeating to a large extent the shape of the of the axial velocity profile in the upstream flow.