Selective Transport of Sulfur Dioxide through Polymer Membranes

Author: Kuehne, Donald L.

Year: 1979

Degree: Dissertation (Ph.D.)

Advisor: Friedlander, Sheldon K.

Committee Member: Unknown, Unknown

Option: Chemical Engineering

DOI: 10.7907/xkjs-zz88

Abstract

The purpose of this research was to identify and characterize polymeric materials which are selective to SO₂ for possible applications in the monitoring or control of SO₂ emissions from stationary sources. Preliminary studies indicated that polyacrylate and cellulose triacetate were very selective to SO₂. The SO₂ solubility of polyacrylate was 0.215 lb/lb (25°C, 1 atm), comparable to the SO₂ solubilities of sulfolane (tetrahydrothiophene-1,1-dioxide) and polyethylene glycol, two excellent SO₂ solvents.

To achieve the high SO₂ transport rates required for a membrane separation process, two techniques were investigated for preparing ultrathin films of these polymers. Polyacrylate films were cast on mercury, and cellulose triacetate films were formed on glass plates which were withdrawn at constant velocity from dilute polymer solutions. The glass plate technique was also used to make composite films consisting of a 0.2-0.5 μm layer of polyacrylate over a 0.002-0.005 μm layer of cellulose triacetate. All the films were placed on microporous filter materials for support.

The performance of the membranes was initially determined by measuring their permeability to pure N₂, CO₂, and SO₂. The N₂ and CO₂ permeabilities were nearly independent of pressure, but the SO₂ permeability increased rapidly with increasing pressure. The SO₂ permeation data were correlated with two- and three-parameter exponential models. The three-parameter model had the same functional form as the free volume theory and gave a better fit to the data than the two-parameter model. The SO₂ permeability was affected by previous conditioning of the membranes and time-dependent processes occurring in the polymer. There was evidence that some SO₂ molecules became immobilized in clusters within the membranes.

The composite membranes were also tested with binary mixtures of N₂ and SO₂ at 10 atm upstream pressure with a steady-state flow system. A typical membrane produced an enriched permeant stream of 2% SO₂ from 0.1% SO₂ upstream, 35% from 2%, and over 90% from 10%. N₂ permeation was enhanced by the presence of SO₂, but the presence of N2 inhibited SO₂ permeation at high SO₂ partial pressures. Interactions between N₂ and SO₂ made it difficult to accurately predict the permeation rates of the mixtures from data for the pure gases.

The composite membranes were superior in performance to the single-layer membranes and those developed by others for SO₂ separations; however, they were unable to meet the stringent design goals for combustion and smelter gas cleaning. The unique properties of the composite membranes do make them attractive for instrumentation and other specialty applications.

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