WOS:000400312700018International audienceLarge-eddy simulation of a supersonic hydrogen-air non-premixed lifted jet flame is reported in the configuration studied by Cheng et al. (1994). The emphasis of the study is on the mechanism driving flame stabilization. The resolution issue is first addressed by considering three meshes of, respectively, 4, 32 and 268 millions of cells. The highest resolution of 60 mu m allows for resolving the flame with a reduced chemical kinetics. LES results are found in good agreement with experimental data and previous simulations of the literature. It is observed in the simulations that the highly unstable flame base exhibits a cyclic period of around 0.25 ms, with the transient occurence of shock diamonds. T...
The impact of burned gases on flame stabilization is analyzed under the conditions of a laboratory j...
Three-dimensional direct numerical simulations of turbulent lifted hydrogen jet flames in heated cof...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/76420/1/AIAA-2009-239-170.pd
Direct numerical simulation (DNS) of the near-field of a three-dimensional spatially-developing turb...
Flame stabilisation in (highly) preheated mixture is common in several industrial applications. When...
The flame index concept for large eddy simulation developed by Domingo et al. [P. Domingo, L. Vervis...
This PhD study is focused on the large eddy simulation (LES) and on the modelisation of supersonic c...
The unsteady evolution of lifted methane–air jet flames following spark ignition is computed using L...
Accurate modeling of the transient structure of reacting diesel jets is important as transient featu...
Direct numerical simulation (DNS) of the near field of a three-dimensional spatially developing turb...
The main aim of this article is to provide a theoretical understanding of the physics of supersonic ...
A turbulent lifted slot-jet flame is studied using direct numerical simulation (DNS). A single step ...
In this work, the large eddy simulation (LES) technique is employed to computationally model a lifte...
Large eddy simulation (LES) results are presented for a premixed methane/air turbulent flame arising...
A turbulent lifted slot-jet flame is studied using direct numerical simulation (DNS). A one- step ch...
The impact of burned gases on flame stabilization is analyzed under the conditions of a laboratory j...
Three-dimensional direct numerical simulations of turbulent lifted hydrogen jet flames in heated cof...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/76420/1/AIAA-2009-239-170.pd
Direct numerical simulation (DNS) of the near-field of a three-dimensional spatially-developing turb...
Flame stabilisation in (highly) preheated mixture is common in several industrial applications. When...
The flame index concept for large eddy simulation developed by Domingo et al. [P. Domingo, L. Vervis...
This PhD study is focused on the large eddy simulation (LES) and on the modelisation of supersonic c...
The unsteady evolution of lifted methane–air jet flames following spark ignition is computed using L...
Accurate modeling of the transient structure of reacting diesel jets is important as transient featu...
Direct numerical simulation (DNS) of the near field of a three-dimensional spatially developing turb...
The main aim of this article is to provide a theoretical understanding of the physics of supersonic ...
A turbulent lifted slot-jet flame is studied using direct numerical simulation (DNS). A single step ...
In this work, the large eddy simulation (LES) technique is employed to computationally model a lifte...
Large eddy simulation (LES) results are presented for a premixed methane/air turbulent flame arising...
A turbulent lifted slot-jet flame is studied using direct numerical simulation (DNS). A one- step ch...
The impact of burned gases on flame stabilization is analyzed under the conditions of a laboratory j...
Three-dimensional direct numerical simulations of turbulent lifted hydrogen jet flames in heated cof...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/76420/1/AIAA-2009-239-170.pd