Abstract
The corrosion behavior of several heat-resistant steels and alloys, viz. T24, T91, Super 304H, and Haynes 282, in carbon dioxide environment at 600°C has been investigated. X-ray diffraction analysis, scanning electron microscopy, and glow-discharge optical emission spectrometry were employed to characterize the corrosion products. The results showed that the corrosion kinetics of the investigated materials followed a parabolic law. Super 304H and Haynes 282 exhibited superior corrosion resistance due to their higher Cr and Ni contents. Severe carburization of T91 was found because of the quick diffusion rate of carbon or carbon ion, which was detected underneath the oxide layers. In addition to internal carburization of metal, carbon was also found at the surface of samples.
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References
G. Angelino, J. Eng. Gas Turbines Power 90, 287 (1968).
P. Mathieu and R. Nihart, J. Eng. Gas Turbines Power 121, 116 (1999).
B.D. Iverson, T.M. Conboy, J.J. Pasch, and A.M. Kruizenga, Appl. Energy 111, 957 (2013).
J.E. Cha, T.H. Lee, J.H. Eoh, S.H. Seong, S. Kim, and D.E. Kim, Nucl. Eng. Technol. 41, 1025 (2009).
X. Wang, G. Xi, and Z. Wang, Proc. Inst. Mech. Eng. Part A J. Power 220, 589 (2006).
T.D. Nguyen, J. Zhang, and D.J. Young, Oxid. Met. 87, 541 (2017).
T.D. Nguyen, J. Zhang, and D.J. Young, Corros. Sci. 112, 110 (2016).
T.D. Nguyen, J. Zhang, and D.J. Young, Mater. High Temp. 32, 16 (2015).
D.J. Young and B.A. Pint, Oxid. Met. 66, 137 (2006).
B.A. Pint, R.G. Brese, and J.R. Keiser, Mater. Corros. 68, 151 (2017).
B.A. Pint and J.R. Keiser, JOM 67, 2615 (2015).
I.G. Wright, B.A. Pint, J.P. Shingledecker, and D. Thimsen, in ASME Paper #GT2013-94941, Presented at the International Gas Turbine & Aeroengine Congress & Exhibition (San Antonio, TX, 2013)
A. Pfennig and R. Bäßler, Corros. Sci. 51, 931 (2009).
F. Rouillard, F. Charton, and G. Moine, Corrosion 67, 095001 (2011).
G.R. Holcomb, C. Carney, and O.N. Dogan, Corros. Sci. 109, 22 (2016).
V. Firouzdor, K. Sridharan, G. Cao, M. Anderson, and T.R. Allen, Corros. Sci. 69, 281 (2013).
W.J. Quadakkers, T. Olszewski, J. Piron-Abellan, V. Shemet, and L. Singheiser, Mater. Sci. Forum 696, 194 (2011).
F. Rouillard, G. Moine, M. Tabarant, and J.C. Ruiz, Oxid. Met. 77, 57 (2012).
G. Cao, V. Firouzdor, K. Sridharan, M. Anderson, and T.R. Allen, Corros. Sci. 60, 246 (2012).
S.B. Newcomb and W.M. Stobbs, Oxid. Met. 26, 431 (1986).
T. Furukawa and F. Rouillard, Prog. Nucl. Energy 82, 136 (2015).
Y. Yang, L. Zhu, Q. Wang, and C. Zhu, Mater. Sci. Eng. A 608, 164 (2014).
Z. Liang, P.M. Singh, Q. Zhao, and Y. Wang, Oxid. Met. 84, 291 (2015).
J. Żurek, E. Wessel, L. Niewolak, F. Schmitz, T.U. Kern, and L. Singheiser, Corros. Sci. 46, 2301 (2004).
R. Viswanathan, J. Sarver, and J.M. Tanzosh, J. Mater. Eng. Perform. 15, 255 (2006).
Acknowledgements
This work is supported by the Collaborative Fund of China (No. 6141A02022501), the Postdoctoral Fund (2017M620451, 2018T111061), and the Shaanxi Province Postdoctoral Research Grant (2017BSHEDZZ41).
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Liang, Z., Yu, M., Gui, Y. et al. Corrosion Behavior of Heat-Resistant Materials in High-Temperature Carbon Dioxide Environment. JOM 70, 1464–1470 (2018). https://doi.org/10.1007/s11837-018-2975-0
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DOI: https://doi.org/10.1007/s11837-018-2975-0