Geodesic
Identification of the boundary condition in the diffusion model of the hydrodynamic flow in a chemical reactor
Vestnik Ûžno-Uralʹskogo gosudarstvennogo universiteta. Seriâ, Matematičeskoe modelirovanie i programmirovanie, Tome 17 (2024) no. 2, pp. 5-14 Cet article a éte moissonné depuis la source Math-Net.Ru

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The motion of a hydrodynamic flow in a chemical reactor described by a one-dimensional one-parameter diffusion model is considered. Within the framework of this model, the task is set to identify the boundary condition at the reactor outlet containing an unknown concentration of the reagent under study leaving the reactor in a stream. In this case, the law of change in the concentration of the reagent over time at the reactor inlet is additionally set. After the introduction of dimensionless variables, a discrete analogue of the transformed inverse problem in the form of a system of linear algebraic equations is constructed by the method of difference approximation. The discrete analogue of the additional condition is written as a functional and the solution of a system of linear algebraic equations is presented as a variational problem with local regularization. A special representation is proposed for the numerical solution of the constructed variational problem. As a result, the system of linear equations for each discrete value of a dimensionless time splits into two independent linear subsystems, each of which is solved independently of each other. As a result of minimizing the functional, an explicit formula was obtained for determining the approximate concentration of the reagent under study in the flow leaving the reactor at each discrete value of the dimensionless time. The proposed computational algorithm has been tested on the data of a model chemical reactor.
Keywords: chemical reactor, one-parameter diffusion model, Peclet parameter, boundary inverse problem, local regularization method. 
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     title = {Identification of the boundary condition in the diffusion model of the hydrodynamic flow in a chemical reactor},
     journal = {Vestnik \^U\v{z}no-Uralʹskogo gosudarstvennogo universiteta. Seri\^a, Matemati\v{c}eskoe modelirovanie i programmirovanie},
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Kh. M. Gamzaev; N. Kh. Bayramova. Identification of the boundary condition in the diffusion model of the hydrodynamic flow in a chemical reactor. Vestnik Ûžno-Uralʹskogo gosudarstvennogo universiteta. Seriâ, Matematičeskoe modelirovanie i programmirovanie, Tome 17 (2024) no. 2, pp. 5-14. http://geodesic.mathdoc.fr/item/VYURU_2024_17_2_a0/

[1] Kasatkin A.N., Basic Processes and Devices of Chemical Technology, Al'yans, M., 2004 (in Russian)

[2] Komissarov Yu.A., Gordeyev L.S., Vent D.P., Processes and Units of Equipment of Chemical Technology, Himiya, M., 2011 (in Russian)

[3] Kutepov A.M., Bondareva T.N., Berengarten M.B., General Chemical Technology, Akademkniga, M., 2007 (in Russian)

[4] Gumerov A.M., Simulation of Chemical Technological Processes, Izdatel'stvo Lan', M., 2014 (in Russian)

[5] Kafarov V.V., Glebov M.B., Mathematical Modeling of the Main Processes of Chemical Production, Vysshaya shkola, M., 1991 (in Russian)

[6] Usheva N.V., Moyzes O.E., Mityanina O.E., Kuzmenko E.A., Mathematical Modeling of Chemical Technological Processes, Polytechnical University Publishing, Tomsk, 2014 (in Russian)

[7] Zakgeim A.Yu., General Chemical Technology: Introduction to Modeling of Chemical Processes, Logos, M., 2009 (in Russian)

[8] Danckwerts P.V., Gas-Liquid Reactions, McGraw-Hill Book Corporation, New York, 1970

[9] Alifanov O.M., Inverse Heat Transfer Problems, Springer, Berlin, 2011

[10] Kabanikhin S.I., Inverse and Ill-Posed Problems, Walter de Gruyter, Berlin, 2011 | MR

[11] Samarskii A.A., Vabishchevich P.N., Numerical Methods for Solving Inverse Problems of Mathematical Physics, Walter De Gruyter, Berlin, 2008 | MR

[12] Hasanov A.H., Romanov V.G., Introduction to Inverse Problems for Differential Equations, Springer, Berlin, 2021 | MR | Zbl

[13] Kostin A.B., Prilepko A.I., “On Some Problems of Restoration of a Boundary Condition for a Parabolic Equation”, Differential Equations, 32:1 (1996), 113–122 | MR | Zbl

[14] Kozhanov A.I., “Inverse Problems for Determining Boundary Regimes for Some Equations of Sobolev type”, Bulletin of the South Ural State University. Series: Mathematical Modeling, Programming and Computer Software, 9:2 (2016), 37–45 | DOI | Zbl

[15] Prilepko A.I., Orlovsky D.G., Vasin I.A., Methods for Solving Inverse Problems in Mathematical Physics, Marcel Dekker, New York, 2000 | MR | Zbl

[16] Gamzaev Kh.M., “Inverse Problem of Pipeline Transport of Weakly-Compressible Fluids”, Journal of Engineering Physics and Thermophysics, 93:6 (2020), 1567–1573 | DOI

[17] Gamzaev Kh.M., “Identification of the Boundary Mode in One Thermal Problem Based on the Single-Phase Stefan Model”, Cybernetics and Systems Analysis, 59:2 (2023), 266–273 | DOI | MR

[18] Vasilev V.I., Ling-De Su, “Numerical Method for Solving Boundary Inverse Problem for One-Dimensional Parabolic Equation”, Mathematical Notes of NEFU, 24:2 (2017), 107–116 | DOI | MR

[19] Yaparova N.M., “Numerical Methods for Solving a Boundary Value Inverse Heat Conduction Problem”, Inverse Problems in Science and Engineering, 22:5 (2014), 832–847 | DOI | MR | Zbl