Skeletal Reaction Models for Methane Combustion
Abstract
A local-sensitivity-analysis technique is employed to generate new skeletal reaction models for methane combustion from the foundational fuel chemistry model (FFCM-1). The sensitivities of the thermo-chemical variables with respect to the reaction rates are computed via the forced-optimally time dependent (f-OTD) methodology. In this methodology, the large sensitivity matrix containing all local sensitivities is modeled as a product of two low-rank time-dependent matrices. The evolution equations of these matrices are derived from the governing equations of the system. The modeled sensitivities are computed for the auto-ignition of methane at atmospheric and high pressures with different sets of initial temperatures, and equivalence ratios. These sensitivities are then analyzed to rank the most important (sensitive) species. A series of skeletal models with different number of species and levels of accuracy in reproducing the FFCM-1 results are suggested. The performances of the generated models are compared against FFCM-1 in predicting the ignition delay, the laminar flame speed, and the flame extinction. The results of this comparative assessment suggest the skeletal models with 24 and more species generate the FFCM-1 results with an excellent accuracy.
Keywords
Cite
@article{arxiv.2201.11038,
title = {Skeletal Reaction Models for Methane Combustion},
author = {Yinmin Liu and Hessam Babaee and Peyman Givi and Harsha Chelliah and Daniel Livescu and Arash Nouri},
journal= {arXiv preprint arXiv:2201.11038},
year = {2023}
}
Comments
16 pages, 8 figures