Implications of the laminar flamelet model in premixed turbulent combustion

The method of activation energy asymptotics is used to describe the behavior and characteristics of adiabatic laminar flamelets involving counterflowing reactants and products as they arise in premixed turbulent flames. For moderate and low rates of strain the results are analogous to those obtained

A model is described which permits the incorporation of complex hydrocarbon chemistry into a detailed flow field prediction for turbulent nonpremixed combustion. The microscopic element in the turbulent ensemble is taken to be a stretched laminar flamelet, drawn from a library of such flamelets in w

A laminar flamelet model is applied to turbulent, recirculating premixed combustion in a jet-stirred conical reactor. The complete statistical description of the thermochemistry is obtained from a one point probability density function (pdf) and detailed chemical kinetic laminar flame structure. The

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This work reports one-dimensional predictions of methane/air fuel combustion in inert porous media using four combustion models: full mechanism (FM, 49 species and 227 elemental reactions), skeletal mechanism (SM, 26 species and 77 elemental reactions), 4-step reduced mechanism (4RM, 9 species) and