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Tishin, A. A., Gurkin, V. N., & Kurchatov, I. M. (2018). PSA-stage Features of the Hybrid Membrane-sorption Oxygen Concentrator. KnE Engineering, 3(6), 457–463. https://doi.org/10.18502/keg.v3i6.3027

https://doi.org/10.18502/keg.v3i6.3027

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authors

  • A A Tishin
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  • V N Gurkin
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  • I M Kurchatov
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Published Date

  • Oct 8, 2018

PSA-stage Features of the Hybrid Membrane-sorption Oxygen Concentrator

KnE Engineering / Breakthrough directions of scientific research at MEPhI: Development prospects within the Strategic Academic Units / Pages 457–463

Abstract

The paper considers the principle of the organization of the hybrid membranesorption oxygen concentrator and the work of the PSA stage of the hybrid system. The use of hybrid membrane-sorption gas separation systems can significantly reduce the energy consumption of plants, as well as to neutralize such disadvantages as contamination of the product flow by the products of abrasion of sorbents, through the use of highly selective polymer membrane, and the restriction on the oxygen concentration when using a single membrane stage, through its use after the PSA stage. In this paper, we propose an arrangement for the operation of the PSA stage of a hybrid system consisting of three adsorbers and providing a constant product flow of the PSA stage necessary to ensure continuous feed flow to the membrane stage of the system. Each of the adsorbers in this system passes through three main stages: filling, displacement (adsorption), and discharge (desorption). Moreover, the filling is not from the compressor, but part of the product flow of the displaced adsorber. The results of the operation of the system organized by the proposed method are compared with the results of the operation of modern gas separation systems on the market.


 


 


Keywords: Sorption, air separation, pressure-swing adsorption, PSA, hybrid technologies, oxygen concentrator, recycling, oxygen

References
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