A number of piping components in the secondary system of nuclear power plants are exposed to aging mechanisms such as FAC (Flow-Accelerated Corrosion), cavitation, flashing, SPE (Solid Particle Erosion), LDIE (Liquid Droplet Impingement Erosion), etc. Those mechanisms may lead to thinning, leak, or rupture of the components. Due to the pipe ruptures caused by wall thinning in Surry unit 2 of USA in 1986 and in Mihama unit 3 of Japan in 1994, the pipe wall thinning management has emerged as one of the most important issues in nuclear power plants. To manage the pipe wall thinning in the secondary system, Korea has used a foreign program since 1996. As using the foreign country’s program for long term, it was necessary to improve from the perspective of the users. Accordingly, KEPCO-E & C has started to develop the 3D-based pipe wall thinning management program (ToSPACE, Total Solution for Piping And Component Engineering management) from eight years ago, and the development was successful. This paper describes the major functions included in ToSPACE program, such as 3D-based DB (Database) buildup, development of FAC and erosion evaluation theories, UT (Ultra-sonic Test) data reliability analysis, field connection with 3D, automatic establishment of long-term inspection plan, etc. ToSPACE program was developed to allow site engineers performing the selection of inspection quantity at each refueling outage, UT data reliability analysis, UT evaluation, determination of next inspection timing, identification of the inspecting and replacing components in 3D drawings, etc., to access easily.
References
[1]
EPRI (2004) Recommendations for Controlling Cavitation, Flashing, Liquid Droplet Impingement, and Solid Particle Erosion in Nuclear Power Plant Piping Systems. TR-1011231.
[2]
Hwang, K.M. (2013) Cause Analysis for the Wall Thinning and Leakage of a Small Bore Piping Downstream of an Orifice. Corrosion Science and Technology, 12, 227-232. https://doi.org/10.14773/cst.2013.12.5.227
[3]
Cengel. Y.A. and Cimbala, J.M. (2005) Fluid Mechanics Fundamentals & Applications. McGraw-Hill, New York.
[4]
Idelchik, I.E. (2005) Handbook of Hydraulic Resistance. Jaico Publishing House, Mumbai.
[5]
EPRI (2012) CHECWORKSTM Steam/Feedwater Application (SFA) Version 4.0. TR-1025251.
[6]
Qiu, G., Mansour, C. and Trevin, S. (2013) BRT-CICEROTM Development at EdF: A brief History of Operating Feedback. R&D Programs and Software Improvement, FAC 2013, Avegnon France.
[7]
Kastner, W., Erve, M., Henzel, N. and Stellwag, B. (1990) Calculation Code for Erosion Corrosion Induced Wall Thinning in Piping Systems. Nuclear Engineering and Design, 119, 431-438. https://doi.org/10.1016/0029-5493(90)90182-W
[8]
Keck, R.G. and Griffith, P. (1987) Prediction and Mitigation of Erosive-Corrosive Wear in Secondary Piping Systems of Nuclear Power Plants. Massachusetts Institute of Technology, NUREG/CR-5007, 1-15.
[9]
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
[10]
Hwang, K.M., Lee, C.G., Bhang, K.J. and Yim, Y.S. (2011) A Study on the Design of a Pipe Affected by Liquid Droplet Impingement Erosion. Journal of Mechanical Science and Technology, B, 35, 1097-1103.
[11]
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, B, 7, 1-14. https://doi.org/10.4236/wjnst.2017.71001
[12]
Levy, A.V. (1995) Solid Particle Erosion and Erosion-Corrosion of Materials. ASM International, Materials Park, Ohio.
[13]
Lee, C.K. (2012) Solid Particle Erosion Analytical Approach for Nuclear Power Plants. Corrosion and Protection, B, 10-11, 26-31.
[14]
Yun, H., Hwang, K.M. and Lee, C.K. (2013) Development of Safety Factors for the UT Data Analysis Method in Plant Piping. World Journal of Nuclear Science and Technology, 3, 143-149. https://doi.org/10.4236/wjnst.2013.34024
