Advantages of the adoption of a generalized flame displacement velocity as a central element of flamelet theory

TL;DR

This paper introduces a generalized flame displacement velocity vector for two scalars, leading to a new flamelet framework that enhances understanding of partially-premixed flames and broadens the scope of flamelet theory.

Contribution

It extends the flame displacement concept to two scalars, enabling a more versatile and compact two-dimensional flamelet formulation for thermochemical analysis.

Findings

The generalized velocity vector unifies different flamelet coordinate systems.

New two-dimensional flamelet equations are derived for scalar gradients.

Framework provides insights into partially-premixed flame dynamics.

Abstract

In combustion theory, flames are usually described in terms of the dynamics of iso-surfaces of a specific scalar. The flame displacement speed is then introduced as a local variable quantifying the progression of these iso-surfaces relative to the flow field. While formally defined as a scalar, the physical meaning of this quantity allows relating it with a vector pointing along the normal direction of the scalar iso-surface. In this work, this one-dimensional concept is extended by the introduction of a generalized flame displacement velocity vector, which is associated with the dynamics of iso-surfaces of two generic scalars, $\alpha$ and $\beta$. It is then shown how a new flamelet paradigm can be built around this velocity vector, which leads to a very compact and generic set of two-dimensional flamelet equations for thermochemical quantities and the conditioning scalar gradients, $g_{\alpha} = \lvert \nabla \alpha \rvert$ and $g_{\beta} = \lvert \nabla \beta \rvert$. The most important features of the developed framework are discussed in the context of partially-premixed flames, which provides significant insights into several aspects of the theory, including the nature of the different contributions to the flamelet equations for the conditioning scalar gradients and the fact that different flamelet coordinate systems (orthogonal and non-orthogonal) can be characterized by the same flame displacement velocity vector. This approach opens an entire spectrum of possibilities for the definition of new two-dimensional composition spaces, which represents a very promising basis for the development of new variants of flamelet theory.