High-Pressure Aging of Asymmetric Torlon® Hollow Fibers for Helium Separation from Natural Gas

Membrane separation for helium extraction from natural gas gained increased interest recently. Several vendors offer membrane elements for helium extraction, although data on their performance and operating experience are unpublished. The aim of this work was to obtain and study the separation perfo...

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Bibliographic Details
Published inFibers Vol. 6; no. 4; p. 83
Main Authors Dibrov, George, Ivanov, Mikhail, Semyashkin, Mikhail, Sudin, Vladislav, Kagramanov, Georgy
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.12.2018
Subjects
Aging
Aging (natural)
Asymmetry
Binary mixtures
Ethanol
Flow velocity
Gas membrane separation
gas separation
Gases
Helium
Hollow fiber membranes
Membrane separation
Methane
Natural gas
Nitrogen
Permeability
Polyamide resins
Polyamide-imides
Polyimideamides
polymeric hollow-fiber membranes
Polymers
Reluctance
Scanning electron microscopy
Selectivity
Solvents
Temperature
Thickness
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Summary:Membrane separation for helium extraction from natural gas gained increased interest recently. Several vendors offer membrane elements for helium extraction, although data on their performance and operating experience are unpublished. The aim of this work was to obtain and study the separation performance of asymmetric hollow-fiber membrane element from commercial polyamide-imide Torlon®, in conditions close to the industrial process of helium extraction from natural gas. A membrane element with an active area of 0.177 m2, a helium permeance of 100 l(STP)/(m2·h·bar), and a selectivity α(He/CH4) = 340 was produced. This corresponds to a selective layer thickness of 82.3 nm, which was confirmed by SEM and resistance model calculations. The obtained membrane element was employed to decrease the concentration of helium in its binary mixture with methane from 0.4% to 0.05%. A relationship of separation characteristics from transmembrane pressure is also presented. At 70 bar and a stage cut of 2.7%, the feed flow rate was 0.16 m3(STP)/h, which yielded a helium permeate concentration of 14.7%. At 80 bar, a decrease in permeance to 60 l(STP)/(m2·h·bar) and in selectivity to 240 was observed. It was shown that the main reason for aging was the increased support resistance, due to a partial compaction of pores with a radius of less than 15 nm.
ISSN:2079-6439
2079-6439
DOI:10.3390/fib6040083