Add to ORKGA dynamic adaptive chemistry(DAC) is developed based on the path flux analysis(PFA) model reduction approach to increase drastically the computation efficiency of combustion modeling with large, detailed kinetic mechanism. This new method is applied to the simulation of homogeneous ignition and unsteady flame propagation of n-decane/air mixtures. The comparison between results predicted by dynamic adaptive chemistry and those by detailed chemistry shows that this method can accurately reproduce the species time histories and ignition delay times. Compared to the detailed mechanism, there are much smaller numbers of active species and reactions with DAC method. The effects of the mechanism size and criteria of model reduction in path flux an...
The current paper focuses on the numerical simulation of the Delft jet in hot co-flow (DJHC) burner,...
In this paper, an automatic method for reducing chemical mechanisms during run time based on the qua...
In reacting flow simulations, detailed chemical kinetics for practical fuels is important for accura...
A new error controlled dynamic adaptive chemistry (EC-DAC) scheme is developed and validated for ign...
An integrated dynamic adaptive chemistry and hybrid multi-timescale (HMTS-DAC) method is developed b...
Despite the onset of peta-scale computing, simulations of reacting flows with detailed chemistry is ...
To overcome the major challenge of reactive flow simulation for chemical kinetics dominated flame dy...
Using detailed mechanisms to include chemical kinetics in computational fluid dynamics simulations i...
Using detailed mechanisms to include chemical kinetics in computational fluid dynamics simulations i...
Detailed chemical kinetics is important for high-fidelity reacting flow simulations. The major chall...
Three approaches toward efficient and predictive turbulent combustion modeling are investigated in t...
Large-scale high-fidelity numerical simulation with detailed chemistry is an important approach to t...
The demands for extending the limiting operation conditions and enhancing the combustion efficiency ...
The Dynamic Adaptive Chemistry (DAC) technique is extended in this work to multidimensional simulati...
The current paper focuses on the numerical simulation of the Delft jet in hot co-flow (DJHC) burner,...
In this paper, an automatic method for reducing chemical mechanisms during run time based on the qua...
In reacting flow simulations, detailed chemical kinetics for practical fuels is important for accura...
A new error controlled dynamic adaptive chemistry (EC-DAC) scheme is developed and validated for ign...
An integrated dynamic adaptive chemistry and hybrid multi-timescale (HMTS-DAC) method is developed b...
Despite the onset of peta-scale computing, simulations of reacting flows with detailed chemistry is ...
To overcome the major challenge of reactive flow simulation for chemical kinetics dominated flame dy...
Using detailed mechanisms to include chemical kinetics in computational fluid dynamics simulations i...
Using detailed mechanisms to include chemical kinetics in computational fluid dynamics simulations i...
Detailed chemical kinetics is important for high-fidelity reacting flow simulations. The major chall...
Three approaches toward efficient and predictive turbulent combustion modeling are investigated in t...
Large-scale high-fidelity numerical simulation with detailed chemistry is an important approach to t...
The demands for extending the limiting operation conditions and enhancing the combustion efficiency ...
The Dynamic Adaptive Chemistry (DAC) technique is extended in this work to multidimensional simulati...
The current paper focuses on the numerical simulation of the Delft jet in hot co-flow (DJHC) burner,...
In this paper, an automatic method for reducing chemical mechanisms during run time based on the qua...
In reacting flow simulations, detailed chemical kinetics for practical fuels is important for accura...