Influence of the Approach to Membrane Mass Transfer Characteristics Determination on the Process Simulation Results

Мұқаба

Дәйексөз келтіру

Толық мәтін

Ашық рұқсат Ашық рұқсат
Рұқсат жабық Рұқсат берілді
Рұқсат жабық Тек жазылушылар үшін

Аннотация

In this work, the dependence of the output characteristics determined in the simulation of the gas separation membrane process on the gas transport characteristics of the membrane specified as parameters of the membrane module model has been investigated. The study was carried out on a laboratory setup containing polyphenylene oxide hollow fibres. As a result of this integrated study, including theoretical and experimental approaches, it has been determined that when using the ideal gas transport characteristics obtained for pure gases to simulate the process, the error expressed in achievable concentration of the target component in the product stream ranges from 1.5 to 8.8% compared to the experimentally obtained values for the same module geometry and the same membrane area. This discrepancy can lead both to unattainable targets for the technological line and to an incorrect technical and economic evaluation of the process. Thus, the design of technological lines using mathematical modelling tools should be based on the “effective” gas transport characteristics of the material and/or product obtained for the components of real gas mixtures or simulating real gas mixtures.

Авторлар туралы

A. Atlaskin

Mendeleev Russian University of Chemical Technology

Хат алмасуға жауапты Автор.
Email: atlaskin.a.a@muctr.ru
Russia, 125047, Moscow, Miusskaya square, 9

S. Kryuchkov

Mendeleev Russian University of Chemical Technology

Email: atlaskin.a.a@muctr.ru
Russia, 125047, Moscow, Miusskaya square, 9

A. Stepakova

Mendeleev Russian University of Chemical Technology

Email: atlaskin.a.a@muctr.ru
Russia, 125047, Moscow, Miusskaya square, 9

I. Moiseenko

Mendeleev Russian University of Chemical Technology

Email: atlaskin.a.a@muctr.ru
Russia, 125047, Moscow, Miusskaya square, 9

N. Tsivkovsky

Mendeleev Russian University of Chemical Technology

Email: atlaskin.a.a@muctr.ru
Russia, 125047, Moscow, Miusskaya square, 9

K. Smorodin

Mendeleev Russian University of Chemical Technology

Email: atlaskin.a.a@muctr.ru
Russia, 125047, Moscow, Miusskaya square, 9

A. Petukhov

Mendeleev Russian University of Chemical Technology; Department of Chemistry, Lobachevsky State University of Nizhny Novgorod

Email: atlaskin.a.a@muctr.ru
Russia, 125047, Moscow, Miusskaya square, 9; Russia, 603022, Nizhny Novgorod, 23 Gagarin Avenue

M. Atlaskina

Mendeleev Russian University of Chemical Technology

Email: atlaskin.a.a@muctr.ru
Russia, 125047, Moscow, Miusskaya square, 9

I. Vorotyntsev

Mendeleev Russian University of Chemical Technology

Email: atlaskin.a.a@muctr.ru
Russia, 125047, Moscow, Miusskaya square, 9

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© А.А. Атласкин, С.С. Крючков, А.Н. Степакова, И.С. Моисеенко, Н.С. Цивковский, К.А. Смородин, А.Н. Петухов, М.Е. Атласкина, И.В. Воротынцев, 2023

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