A multidimensional combustion model for oblique, wrinkled premixed flames

TL;DR

This paper introduces a multidimensional combustion model that accounts for complex flame wrinkling and oblique angles, improving the accuracy of turbulent premixed flame simulations by incorporating effects of filter width and turbulence levels.

Contribution

It presents a novel multidimensional filtering approach for premixed flames, including analytical solutions and validation against DNS data, enhancing modeling of flame wrinkling effects.

Findings

Model accurately predicts filtered reaction source term across turbulence levels.

Filtered data shows linear increase of reaction source with filter width at larger scales.

Model outperforms traditional 1D filtering approaches in complex flame configurations.

Abstract

A new premixed turbulent combustion model is proposed. It is based on one-dimensional (1D) filtering of density times progress variable and of the reaction source term of laminar premixed flame profiles using a filter kernel which reflects the variation of the slicing area of planar flame fronts as they move through multidimensional filter volumes. It is shown that these multidimensional effects qualitatively change the relation between the filtered reaction source term and the Favre-filtered reaction progress variable compared to 1D filtering, particularly at large filter widths. Analytical results for the filtered quantities are achieved by approximating density times progress variable and reaction source term by suitable Ansatz functions. Filtered data from Direct Numerical Simulations (DNS) of statistically planar turbulent premixed flames at different free stream turbulence levels and heat release parameters is used to develop and validate the model. Two wrinkling factor models as function of filter width and subgrid turbulence level are proposed. For small filter widths up to two times the laminar flame thickness, minor effects from subgrid flame folding are observed. For larger filters, the filtered reaction source term rises linearly with filter width at a rate which increases with subgrid turbulence level. The modelled reaction source term as function of Favre averaged progress variable and filter width shows excellent agreement with filtered DNS data for all investigated free stream turbulence levels, filter widths and heat release parameters.