Evaluation of Quadrature-based Moment Methods in turbulent premixed combustion

TL;DR

This paper evaluates quadrature-based moment methods, QMOM and EQMOM, for modeling turbulent premixed combustion, demonstrating their efficiency and comparable accuracy to stochastic approaches while requiring lower spatial resolution.

Contribution

The study assesses the performance of QMOM and EQMOM in turbulent premixed flames, highlighting their computational efficiency and suitability compared to traditional stochastic PDF methods.

Findings

QMOM and EQMOM accurately reproduce turbulent flame properties.

Moment methods require lower spatial resolution than stochastic approaches.

Both methods are effective in simulating turbulent premixed combustion.

Abstract

Transported probability density function (PDF) methods are widely used to model turbulent flames characterized by strong turbulence-chemistry interactions. Numerical methods directly resolving the PDF are commonly used, such as the Lagrangian particle or the stochastic fields (SF) approach. However, especially for premixed combustion configurations, characterized by high reaction rates and thin reaction zones, a fine PDF resolution is required, both in physical and in composition space, leading to high numerical costs. An alternative approach to solve a PDF is the method of moments, which has shown to be numerically efficient in a wide range of applications. In this work, two Quadrature-based Moment closures are evaluated in the context of turbulent premixed combustion. The Quadrature-based Moment Methods (QMOM) and the recently developed Extended QMOM (EQMOM) are used in combination with a tabulated chemistry approach to approximate the composition PDF. Both closures are first applied to an established benchmark case for PDF methods, a plug-flow reactor with imperfect mixing, and compared to reference results obtained from Lagrangian particle and SF approaches. Second, a set of turbulent premixed methane-air flames are simulated, varying the Karlovitz number and the turbulent length scale. The turbulent flame speeds obtained are compared with SF reference solutions. Further, spatial resolution requirements for simulating these premixed flames using QMOM are investigated and compared with the requirements of SF. The results demonstrate that both QMOM and EQMOM approaches are well suited to reproduce the turbulent flame properties. Additionally, it is shown that moment methods require lower spatial resolution compared to SF method.