Fireside corrosion and steamside oxidation of 9–12%Cr martensitic steels exposed for long term testing

Montgomery, Melanie; Jensen, Søren Aakjær; Rasmussen, Finn; Vilhelmsen, T.

doi:10.1179/174327809x419168

Cited by 22 publications

(21 citation statements)

References 16 publications

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“…Here the only difference is variation in heat flux around the tube resulting in different surface metal temperatures. This was also observed for HCM12 [3]. The increased temperature due to a thicker oxide, results in a higher localised temperature at the oxidemetal interface thus increasing the oxidation rate.…”

Section: High Temperature Morphologysupporting

confidence: 65%

“…Wright [1] has cited that other workers observed iron oxides in the inner oxide for 2.5%Cr steel. The formation or iron rich oxide within the inner oxide has been also observed for T92 but after shorter exposure times of 50,000 h [3].…”

Section: High Temperature Morphologymentioning

confidence: 66%

“…Cr rich oxide was observed as striations within the oxide parallel to the oxide -metal interface. This has been observed in laboratory tests for 12%Cr steels [7] and power plant exposure for 9 and 12%Cr steel [3,11]. The explanation is described in detail by [4,7]: first chromium rich spinel is preferentially formed at the metaloxide interface leading to chromium depletion of the underlying metal.…”

Section: High Temperature Morphologymentioning

confidence: 74%

“…Spallation of the oxide can also cause serious problems with blockage of tubes and is especially relevant for austenitic steels [2] but could also apply to ferritic steels exposed for long times. It was previously observed that oxidation rates for the 12%Cr HCM12 and the corresponding oxide microstructure changed when exposures were over 40,000 h [3]. It was discussed in this paper whether the increased tungsten in this alloy is a contributory factor to the increased oxidation rate which produced a thicker inner oxide.…”

Section: Introductionmentioning

confidence: 79%

“…For X20CrMoV121 it has been shown that the outer magnetite and haematite grows by Fe ion diffusion outwards and the inner oxide grows from diffusion of oxygen bearing species inwards [4], such as transport of OH À species into the oxides [3]. This paper compares steamside oxides formed at two temperature ranges from plants with laboratory studies.…”

Section: Discussionmentioning

confidence: 99%

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Microscopical investigation of steamside oxide on X20CrMoV121 superheater tubes

Montgomery

Hansson

Vilhelmsen

et al. 2012

Materials at High Temperatures

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X20CrMoV121 is a 12%Cr martensitic steel which has been used in power plants in Europe for many decades. Superheater tubes exposed for various durations up to 135,000 h in power plants in Denmark at steam temperatures varying from 450 to 575 C were investigated. Light optical and scanning electron microscopy was used to investigate steamside oxide morphologies. At all temperatures there is a double layered oxide, however, the inner:outer oxide thickness is not always equal. At the lower steam temperature range of 5500 C, there is an internal oxidation zone at the oxidation front indicating that chromium is less mobile at these temperatures. At a higher steam temperature range of 540 -575 C the inner oxide consists of chromium rich and chromium poor oxide running parallel to the oxidation front indicating that the chromium is more mobile within the steel. Both types of morphology have been observed in the laboratory, however, the internal oxidation is observed up to 600 C and the chromium rich oxide striation are observed at 700 C.

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Section: High Temperature Morphologysupporting

confidence: 65%

Section: High Temperature Morphologymentioning

confidence: 66%

Section: High Temperature Morphologymentioning

confidence: 74%

Section: Introductionmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 99%

See 3 more Smart Citations

Microscopical investigation of steamside oxide on X20CrMoV121 superheater tubes

Montgomery

Hansson

Vilhelmsen

et al. 2012

Materials at High Temperatures

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Corrosion Behavior of Metallic Materials for Innovative Gasification Processes

Żurek

Hejrani

Müller

et al. 2014

Chemie Ingenieur Technik

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Corrosion Behavior of Metallic Materials for Innovative Gasification ProcessesMetallic materials for highly stressed oxygen nozzles and recovery boilers were studied in respect to their corrosion resistance in H 2 /H 2 O/H 2 S laboratory test gas. Screening tests using ferritic and austenitic steels and nickel-base alloys were carried out and from the results promising alloys selected and tested at various temperatures. With one exception, all alloys show bell-shape temperature dependence of the oxidation kinetics. Results from studies on model alloys will be used to derive optimised alloy compositions which exhibit protective oxide scale formation in the whole temperature range considered in the present studies. Keywords

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Steam oxidation of X20CrMoV121: Comparison of laboratory exposures and in situ exposure in power plants

Montgomery

Hansson

Vilhelmsen

et al. 2011

Materials & Corrosion

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X20CrMoV121 is a 12% Cr martensitic steel which has been used in power plants in Europe for many decades. Specimens have been removed from superheater tubes to investigate long-term exposure with respect to steam oxidation. These tubes have been exposed for various durations up to 135 000 h in power plants in Denmark at steam temperatures varying from 450-565 8C. This paper collates the data, compares oxide morphologies and assesses to what extent parabolic kinetics can be used to describe the oxidation rate. The steam oxidation behaviour has been investigated in the laboratory in an Ar-46%H 2 O mixture at 500, 600 and 700 8C for 336 h. It was observed that the morphology of the oxide layers was strongly influenced by temperature, and some of the same morphologies are also observed for power plant specimens. However, the temperatures at which they occur were different for plant and laboratory specimens, e.g. the presence of Cr rich bands within the oxide occurred at a lower temperature in the plant than in the laboratory. In addition there is a greater variety of oxide morphologies for long-term plant specimens compared to laboratory specimens.

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Fireside corrosion and steamside oxidation of 9–12%Cr martensitic steels exposed for long term testing

Cited by 22 publications

References 16 publications

Microscopical investigation of steamside oxide on X20CrMoV121 superheater tubes

Microscopical investigation of steamside oxide on X20CrMoV121 superheater tubes

Corrosion Behavior of Metallic Materials for Innovative Gasification Processes

Steam oxidation of X20CrMoV121: Comparison of laboratory exposures and in situ exposure in power plants

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