High temperature corrosion behavior of alloys in reducing HCL and H2S containing atmospheres: Thermodynamical and experimental assessment
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In: Materials and Corrosion, Vol. 73.2022, No. 12, 03.08.2022, p. 1979-2003.
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TY - JOUR
T1 - High temperature corrosion behavior of alloys in reducing HCL and H2S containing atmospheres: Thermodynamical and experimental assessment
AU - Nimmervoll, Manuela
AU - Mori, Gregor Karl
AU - Bucher, Edith
AU - Hönig, Stefan
AU - Haubner, Roland
N1 - Publisher Copyright: © 2022 The Authors. Materials and Corrosion published by Wiley-VCH GmbH.
PY - 2022/8/3
Y1 - 2022/8/3
N2 - High-temperature corrosion mechanisms in reducing atmospheres containing HCl (3.8 vol%) and a varying amount of H 2S (0.02 –2 vol%) were developed for several alloys between 420°C and 680°C. These mechanisms are mainly based on practical observations and kinetic considerations—and less on thermodynamic data. This is due to the complexity of these mixed gas atmospheres, volatile corrosion products, and the ever-changing conditions within the corrosion layer, which made it not possible to predict and calculate the actual conditions in the corrosion zone. In this article, a detailed thermodynamic analysis of previously achieved corrosion mechanisms and experimental observations is presented. Correlations and deviations between thermodynamic calculations and practical findings are stated and discussed. The corrosion behavior of ferritic K90941, which performs worse than corrosion-resistant austenitic alloys, except for one test condition at 580°C in the atmosphere with 0.2 vol% H 2S, is explained and supported by thermodynamic data. By combining experiments with thermodynamics, corrosion mechanisms in reducing HCl and H2S-containing atmospheres are explained.
AB - High-temperature corrosion mechanisms in reducing atmospheres containing HCl (3.8 vol%) and a varying amount of H 2S (0.02 –2 vol%) were developed for several alloys between 420°C and 680°C. These mechanisms are mainly based on practical observations and kinetic considerations—and less on thermodynamic data. This is due to the complexity of these mixed gas atmospheres, volatile corrosion products, and the ever-changing conditions within the corrosion layer, which made it not possible to predict and calculate the actual conditions in the corrosion zone. In this article, a detailed thermodynamic analysis of previously achieved corrosion mechanisms and experimental observations is presented. Correlations and deviations between thermodynamic calculations and practical findings are stated and discussed. The corrosion behavior of ferritic K90941, which performs worse than corrosion-resistant austenitic alloys, except for one test condition at 580°C in the atmosphere with 0.2 vol% H 2S, is explained and supported by thermodynamic data. By combining experiments with thermodynamics, corrosion mechanisms in reducing HCl and H2S-containing atmospheres are explained.
UR - http://www.scopus.com/inward/record.url?scp=85135538053&partnerID=8YFLogxK
U2 - 10.1002/maco.202213329
DO - 10.1002/maco.202213329
M3 - Article
VL - 73.2022
SP - 1979
EP - 2003
JO - Materials and Corrosion
JF - Materials and Corrosion
SN - 0947-5117
IS - 12
ER -
