LES combustion modeling using the Eulerian stochastic field method coupled with tabulated chemistry

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• 作者：Amer Avdić^a ; Guido Kuenne^a ; Francesca di Mare^b ; Johannes Janicka ; ^a ; ^{janicka@ekt.tu-darmstadt.de}
• 关键词：Large eddy simulation ; Turbulent stratified combustion ; Joint probability density function ; Eulerian stochastic field method ; Tabulated chemistry
• 刊名：Combustion and Flame
• 出版年：2017
• 出版时间：January 2017
• 年：2017
• 卷：175
• 期：Complete
• 页码：201-219
• 全文大小：4091 K
• 卷排序：175

文摘

In this work a transported joint scalar probability density function method is combined with the flamelet generated manifolds (FGM) tabulated chemistry approach for large eddy simulation (LES) modeling of turbulent combustion. This strategy accounts for the turbulence-chemistry interaction at reasonable computational costs and allows the usage of detailed chemistry information by tabulation. Apart from the details regarding the solution procedure, a technique for an improved stability of the proposed approach is introduced and validated using a one-dimensional test case. Next, a two-dimensional flame configuration is considered in order to perform an in-depth analysis regarding the laminar and turbulent behavior of the model. Here, transient and time-averaged simulation data is used to provide insight into the predicted flame shape and its dynamics, where the implemented approach is compared with the well-established artificially thickened flame (ATF) combustion model. Moreover, the sensitivity of the results to different modeling approaches and model parameters is investigated. Finally, the method is applied to a three-dimensional turbulent stratified burner. Here, in addition to the ATF model, the suggested approach is compared to measurements of the velocity and scalar quantities to evaluate its prediction capability. Consequently, the investigation conducted in this work aims to provide a complete picture on the ability of the proposed method to reproduce the flame propagation and the resulting flow conditions within complex premixed and stratified turbulent flames.