Recently, damage caused by liquid droplet impingement erosion (LDIE) in addition to flow-accelerated corrosion (FAC) has frequently occurred in the secondary side steam piping of nuclear power plants, and the damage-occurring frequency is expected to increase as their operating years’ increase. In order to scrutinize its causes, therefore, an experimental study was conducted to understand how the behavior of LDIE-FAC multiple degradation changes when the piping of nuclear power plants is operated for a long time. Experimental results show that more magnetite was formed on the surface of the carbon steel specimen than on the low-alloy steel specimen, and that the rate of magnetite formation and extinction reached equilibrium due to the complex action of liquid droplet impingement erosion and flow-accelerated corrosion after a certain period of time. Furthermore, it was confirmed at the beginning of the experiment that A106 Gr.B specimen has more mass loss than A335 P22 specimen. After a certain period of time, however, the mass loss tends to be the opposite. This is presumed to have resulted from the magnetite formed on the surface playing a role in suppressing liquid droplet impingement erosion. In addition, it was confirmed that the amount of erosion linearly increases under the conditions in which the formation and extinction of magnetite reach equilibrium.
References
[1]
EPRI (2004) Recommendations for Controlling Cavitation, Flashing, Liquid Droplet Impingement, and Solid Particle Erosion in Nuclear Power Plant Piping Systems, 1011231. Final Report.
[2]
Hwang, K.M., Seo, H.K., Lee, C.K. and Nam, W.C. (2017) Development of a LDIE Prediction Theory in the Condition of Magnetite Formation on Secondary Side Piping in Nuclear Power Plants. World Journal of Nuclear Science and Technology, 7, 1-14. https://doi.org/10.4236/wjnst.2017.71001
[3]
Hattori, S. and Kakuichi, M. (2013) Effect of Impact Angle on Liquid Droplet Impingement Erosion. Wear, 298-299, 1-7. https://doi.org/10.1016/j.wear.2012.12.025
[4]
Heymann, F.J. (1969) High-Speed Impact between a Liquid Drop and a Solid Surface. Journal of Applied Physics, 40, 5113-5122. https://doi.org/10.1063/1.1657361
[5]
Li, R., Ninokata, H. and Mori, M. (2011) Parametric Investigation on the Effect Factors for Liquid Droplet Impingement Erosion. Proceedings of ASME-JSME-KSME 2011 Joint Fluids Engineering Conference, Shizuoka, Japan, 24-29 July 2011, 1347-1355.
https://doi.org/10.1115/AJK2011-03034
[6]
Hwang, K.M., Yun, H., Seo, H.K., Lee, G.Y. and Kim, K.W. (2019) Development of ToSPACE for Pipe Wall Thinning Management in Nuclear Power Plants. World Journal of Nuclear Science and Technology, 9, 1-15.
https://doi.org/10.4236/wjnst.2019.91001
[7]
ASTM G73-10 (2017) Standard Test Method for Liquid Impingement Erosion Using Rotating Apparatus.
[8]
Higashi, Y., Narabayashi, T., Shimazu, Y., Tsuji, M., Ohmori, M. and Tezuka, K. (2009) Study on Pipe Wastage Mechanism by Liquid Droplet Impingement Erosion. Proceedings of the 17th International Conference on Nuclear Engineering, Brussels, Belgium, 12-16 July 2009, 1021-1027. https://doi.org/10.1115/ICONE17-76029
