The role of presumed probability density function in the simulation of non premixed turbulent combustion

TL;DR

This paper investigates how different presumed probability density functions (PDFs) influence the accuracy of non-premixed turbulent combustion simulations using Flamelet Progress Variable models, comparing standard, beta, and SMLD-based PDFs.

Contribution

It introduces and compares three PDF models for turbulence-chemistry interaction in combustion, highlighting the advantages of the SMLD approach over traditional methods.

Findings

The SMLD model improves prediction accuracy by incorporating multiple moments.

Standard models with simple PDFs lack turbulence-chemistry interaction details.

The SMLD approach better captures the dependence of the progress variable on its variance.

Abstract

Flamelet Progress Variable (FPV) combustion models allow the evaluation of all thermo chemical quantities in a reacting flow by computing only the mixture fraction Z and a progress variable C. When using such a method to predict a turbulent combustion in conjunction with a turbulence model, a probability density function (PDF) is required to evaluate statistical averages (e.g., Favre average) of chemical quantities. The choice of the PDF is a compromise between computational costs and accuracy level. The aim of this paper is to investigate the influence of the PDF choice and its modeling aspects in the simulation of non premixed turbulent combustion. Three different models are considered: the standard one, based on the choice of a beta distribution for Z and a Dirac distribution for C; a model employing a beta distribution for both Z and C; a third model obtained using a beta distribution for Z and the statistical most likely distribution (SMLD) for C. The standard model, although widely used, doesn't take into account the interaction between turbulence and chemical kinetics as well as the dependence of the progress variable not only on its mean but also on its variance. The SMLD approach establishes a systematic framework to incorporate informations from an arbitrary number of moments, thus providing an improvement over conventionally employed presumed PDF closure models. The rational behind the choice of the three PDFs is described in some details and the prediction capability of the corresponding models is tested versus well known test cases, namely, the Sandia flames, and a test case for supersonic combustion provided by Cheng.