KCl-Induced High Temperature Corrosion of the Austenitic Stainless Steel 304L – The Influence of SO2

S. Karlsson; J. Pettersson; J.E. Svensson; L.G. Johansson

doi:10.4028/www.scientific.net/MSF.696.224

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HomeMaterials Science ForumMaterials Science Forum Vol. 696KCl-Induced High Temperature Corrosion of the...

KCl-Induced High Temperature Corrosion of the Austenitic Stainless Steel 304L – The Influence of SO₂

Abstract:

The effect of SO₂ on the oxidation of alloy 304L in O₂+H₂O and O₂+H₂O+KCl environment has been investigated at 600°C. Exposure time was 1-168 hours. The exposed samples were analyzed by SEM/EDX, XRD and IC. In dry O₂, a protective and chromium-rich corundum-type oxide forms. In the presence of H₂O(g), chromium is volatilized in the form of CrO₂(OH)₂(g). The corresponding chromium depletion of the protective oxide triggers a partial loss of protective properties resulting in the formation of oxide islands on the alloy grain centers. The oxide islands consist of an outward growing hematite layer and an inward growing FeCrNi spinel layer. By coating the samples with KCl the chromia depletion of the protective oxide dramatically increases due to the formation of K₂CrO₄. This leads to breakaway corrosion, a rapidly growing scale forming all over the surface. The resulting thick scale has a similar structure as the oxide islands formed in the absence of KCl. The addition of 300 ppm SO₂ to the O₂+H₂O and O₂+H₂O+KCl environments results in a drastic reduction of corrosion rate. In O₂+H₂O environment the effect of SO₂ is attributed to the formation of a thin sulphate film on the oxide surface that impedes chromium volatilization and decreases the rate of oxygen reduction on the oxide surface. In O₂+H₂O+KCl environment the corrosion mitigating effect of SO₂ is mainly attributed to the rapid conversion of KCl to K₂SO₄. In contrast to KCl, K₂SO₄ does not deplete the protective oxide in chromium by forming K₂CrO₄.

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Periodical:

Materials Science Forum (Volume 696)

Pages:

224-229

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.696.224

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Online since:

September 2011

Authors:

S. Karlsson, J. Pettersson, J.E. Svensson, L.G. Johansson

Keywords:

304L, Alkali, Breakaway Corrosion, Chromate, Oxidation, Sulphur

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