HIGH-PERFORMANCE CALCULATING METHODS AND TECHNOLOGIES OF SIMULATION OF NANOPOROUS SYSTEMS WITH FEEDBACK FOR ADSORPTION GAS CLEANING
DOI:
https://doi.org/10.31713/vt320196Keywords:
high-performance computations, nanoporous feedback systems, adsorption and desorption of gases, Langmuir adsorption equilibrium function, Heaviside operational method, Laplace integral transformationAbstract
The problem of modeling non isothermal adsorption and desorption innanoporous catalysts for nonlinear adsorption equilibrium of theLangmuir type in nanoporous zeolite systems is considered. Highlydispersed high-performance methods and computational technologymodels of non-isothermal adsorption and desorption in nanoporouscatalysts for non-linear adsorbed gas classes in nanoporous zeolitesystems. Turn around and move forward and encourage more nonlinear adsorption in the framework of the molecular theory ofadsorption and in the middle of the second component. On the basis ofthese, new, non-linear mathematical models are encouraged, whichinclude balancing adsorption / desorption systems with modalities ofthe nano- and macroflows, dispersion forces of the Lenard-Jones gas, and high-speed gas flow. Realization of effective schemes oflinearization of nonlinear models based on the Landau approachshould be placed in a series of Langmuir functions at a temperaturetransition point near a small parameter. Prompted by higheranalytical and numerical analysis of mathematical models using theoperational method of Heaviside, the algorithm is more efficient, and itis possible to significantly increase the efficiency of the process.The results of computational experiments of space-hourlyconcentration distributions of adsorbate in the gas phase and in thephase of micropores of the adsorbent in the deposits in thetemperature and the speed of the gas flow are presented.References
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Petryk M., Leclerc S., Canet D., Sergienko I. V., Deineka V. S., Fraissard J. The Competitive Diffusion of
Gases in a zeolite bed: NMR and Slice Procedure, Modelling and Identification of Parameters. The Journal of Physical Chemistry C. ACS. 2015. 119 (47). 26519–26525.
Sergienko I. V., Petryk M. R., Leclerk S., Fraissard J. High productivity methods of identification of competitive diffusion parameters in heterogeneous media of nanoporous particles. Cybernetics and Systems
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Matematychne modeliuvannia teploperenosu ta adsorbtsii vuhlevodniv v nanoporystykh tseolitnykh katalizatorakh system neitralizatsii vidpratsovanykh haziv / Petryk M. R., Khimich O. M., Boiko I. V., Mykhalyk D. M., Petryk M. M., Kovbashyn V. I. Natsionalna akademiia nauk Ukrainy In-t kibernetyky im. V.M. Hlushkova, 2017. 280 c.
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Prudnikov A. P., Brichkov Yu. A. Marychev O. I. Integrals and series. Additional chapters, Nauka,
Moscow, 1986. 800 p.
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