Abstract:
A numerical simulation of propane pyrolysis process in a flowing chemical reactor was
performed in this work. In this case, chemical transformations are carried out due to external heating of the reaction zone. The velocity of gas motion in explored flows is much
less then sound velocity in gas mixture, which motivates using the Navier–Stokes equations in approximation of low Mach numbers for describing the processes under study.
The construction of a difference scheme is based on the use of the integro-interpolation
method. To solve the equations of chemical kinetics, we used a specialized explicit second-order accuracy scheme with low computational complexity. To describe the chemical transformations of propane pyrolysis, the well-known kinetic scheme was used,
which includes 30 elementary stages. However, in the work, for more accurate description of the process, the activation energy of one of the reaction stages was specified. The
propane pyrolysis process was numerically simulated taking into account viscosity, diffusion and thermal conductivity for various temperatures of heating elements. The obtained results on propane conversion are compared with experimental data and other
known numerical results for solving the problem under consideration. It is concluded that
the developed numerical algorithm gives high reliability of the obtained results and can
be applied in practice for modeling the processes under study.
Citation:
I. M. Gubaydullin, R. V. Zhalnin, V. F. Masyagin, E. E. Peskova, V. F. Tishkin, “Numerical simulation of propane pyrolysis in a flow chemical reactor under the influence of constant external heating”, Mat. Model., 32:9 (2020), 119–130; Math. Models Comput. Simul., 13:3 (2021), 437–444
\Bibitem{GubZhaMas20}
\by I.~M.~Gubaydullin, R.~V.~Zhalnin, V.~F.~Masyagin, E.~E.~Peskova, V.~F.~Tishkin
\paper Numerical simulation of propane pyrolysis in a flow chemical reactor under the influence of constant external heating
\jour Mat. Model.
\yr 2020
\vol 32
\issue 9
\pages 119--130
\mathnet{http://mi.mathnet.ru/mm4217}
\crossref{https://doi.org/10.20948/mm-2020-09-08}
\transl
\jour Math. Models Comput. Simul.
\yr 2021
\vol 13
\issue 3
\pages 437--444
\crossref{https://doi.org/10.1134/S2070048221030078}
Linking options:
https://www.mathnet.ru/eng/mm4217
https://www.mathnet.ru/eng/mm/v32/i9/p119
This publication is cited in the following 9 articles:
E. E. Peskova, O. S. Yazovtseva, “Application of the Explicitly Iterative Scheme to Simulating Subsonic Reacting Gas Flows”, Comput. Math. and Math. Phys., 64:2 (2024), 326
E. E. Peskova, O. S. Yazovtseva, E. Yu. Makarova, N. A. Tingaeva, Communications in Computer and Information Science, 1914, Mathematical Modeling and Supercomputer Technologies, 2024, 112
E. E. Peskova, V. N. Snytnikov, “Numerical Study of the Conversion of Methane Mixtures under the Influence of Laser Radiation”, Theor Found Chem Eng, 2024
E. E. Peskova, O. S. Yazovtseva, “Issledovanie primeneniya yavno-iteratsionnoi skhemy k modelirovaniyu dozvukovykh reagiruyuschikh gazovykh potokov”, Žurnal vyčislitelʹnoj matematiki i matematičeskoj fiziki, 64:2 (2024), 350
Elizaveta Peskova, Communications in Computer and Information Science, 1868, Parallel Computational Technologies, 2023, 323
I. M. Gubaydullin, E. E. Peskova, O. S. Yazovtseva, A. N. Zagoruiko, “Numerical Simulation of Oxidative Regeneration of a Spherical Catalyst Grain”, Math Models Comput Simul, 15:3 (2023), 485
V. N. Snytnikov, E. E. Peskova, O. P. Stoyanovskaya, “Mathematical model of a two-temperature medium of gassolid nanoparticles with laser methane pyrolysis”, Math. Models Comput. Simul., 15:5 (2023), 877–893
I. M. Gubaydullin, E. E. Peskova, O. S. Yazovtseva, A. N. Zagoruiko, “Numerical simulation of oxidative regeneration of a spherical catalyst grain”, Matem. Mod., 34:11 (2022), 48–66
E E Peskova, “Numerical modeling of subsonic axisymmetric reacting gas flows”, J. Phys.: Conf. Ser., 2057:1 (2021), 012071
Citation in format AMSBIB
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