Numerical study of strongly-nonlinear regimes of steady premixed flame propagation. The effect of thermal gas expansion and finite-front-thickness effects

TL;DR

This study numerically investigates steady premixed flame propagation in channels, focusing on effects like thermal expansion and finite-front-thickness, revealing how flame compression influences speed and identifying limitations of analytical models.

Contribution

It introduces a novel numerical algorithm for solving nonlinear on-shell equations and explores the impact of flame compression and other effects on flame dynamics.

Findings

Flame speed sharply increases with channel width, especially under strong compression.

Flame compression significantly alters the dependence of propagation speed on channel parameters.

The study highlights limitations of weak-nonlinearity analytical approaches and discusses noise effects.

Abstract

Steady propagation of premixed flames in straight channels is studied numerically using the on-shell approach. A first numerical algorithm for solving the system of nonlinear integro-differential on-shell equations is presented. It is based on fixed-point iterations and uses simple (Picard) iterations or the Anderson acceleration method that facilitates separation of different solutions. Using these techniques, we scan the parameter space of the problem so as to study various effects governing formation of curved flames. These include the thermal gas expansion and the finite-front-thickness effects, namely, the flame stretch, curvature, and compression. In particular, the flame compression is demonstrated to have a profound influence on the flame, strongly affecting the dependence of its propagation speed on the channel width b. Specifically, the solutions found exhibit a sharp increase of the flame speed with the channel width. Under a weak flame compression, this increase commences at b/lambda_c = 2 - 3, where lambda_c is the cutoff wavelength, but this ratio becomes significantly larger as the flame compression grows. The results obtained are also used to identify limitations of the analytical approach based on the weak-nonlinearity assumption, and to revise the role of noise in the flame evolution.