The Effect of S and Mn on the High-temperature Oxidation and Scale Spallation Behavior of Low-carbon Steels

Early-stage oxidation behavior in air of low-carbon steels with and without S and Mn additions was investigated in terms of oxidation kinetics and scale spallation in a temperature range of 900 to 1150°C. S and Mn did not appear to affect the growth rate of oxide scales within the given oxidation ti...

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Published inISIJ International Vol. 49; no. 12; pp. 1938 - 1944
Main Authors Hayashi, Shigenari, Sekimoto, Takeshi, Honda, Kazuhiko, Kinoshita, Takeshi, Tanaka, Kazuaki, Ushioda, Kohsaku, Narita, Toshio, Ukai, Shigeharu
Format Journal Article
LanguageEnglish
Published Tokyo The Iron and Steel Institute of Japan 01.01.2009
Iron and Steel Institute of Japan
Subjects
Applied sciences
Corrosion
Corrosion environments
Exact sciences and technology
Fe–FeS eutectic reaction
hot-rolled steel
Metals. Metallurgy
S effect
scale spallation
Temperature
Low carbon steel
Forming
High temperature
scale spallation
S effect
Hot rolling
Eutectic
Carbon steel
Oxidation
Spallation
Fe-FeS eutectic reaction
High temperature corrosion
hot-rolled steel
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Summary:Early-stage oxidation behavior in air of low-carbon steels with and without S and Mn additions was investigated in terms of oxidation kinetics and scale spallation in a temperature range of 900 to 1150°C. S and Mn did not appear to affect the growth rate of oxide scales within the given oxidation time, ~30 min, however it was found that S significantly enhanced oxide scale spallation. Scale spallation occurred only on the S doped steels oxidized at temperatures more than 1000°C when the thickness of oxide scale exceeded about 120 μm. This scale spallation was confirmed to occur during cooling after the given oxidation time. GD-OES analysis revealed that a significant amount of S enrichment occurred at the oxide/steel interface, which was around 1 mass% on 100 ppm S steel after 120 s of oxidation at 1150°C. Such sulfur enrichment was speculated to be due to accumulation of rejected S from surface recession during the high-temperature oxidation. Observation of the steel surface after complete removal of the oxide scale by quenching the steels into liquid nitrogen clearly indicates the formation of eutectic Fe–FeS structure at scale/steel interface, resulting from a liquid phase formation above 1000°C. Formation of sulfide, and therefore a liquid phase at higher temperature, greatly affected oxide scale spallation.
ISSN:0915-1559
1347-5460
DOI:10.2355/isijinternational.49.1938