This paper presents an analysis of the inuence of mathematical models of chemical transformation on the ignition of methane-oxygen mixtures. The results of the analysis show that, despite the widespread use of methane combustion processes for practical purposes and a fairly large number of publications, the development of kinetic schemes for methane combustion is still relevant. Using the example of solving the problem of determining the induction period of ignition of a methane-oxygen mixture in an adiabatic reactor, various kinetic schemes for methane ignition were tested in the work: two one-stage, one threestage schemes and a scheme consisting of 156 reactions. It is shown that the most accurate description of the experimental data on the delay times of an adiabatic explosion can only be obtained using a more complex kinetics of methane oxidation, and the simplified kinetic mechanisms considered give overestimated temperatures of the mixture consisting of methane oxidation products.

mathematical modeling; combustion and explosion; induction period

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