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Thermal Engineering

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01-08-2020 | METALS AND STRENGTH ANALYSIS

Application of Software Tools for Predicting the Corrosion-Erosion Rate to Ensure Integrity of Equipment and Piping of Power Units at Nuclear Power Stations

Authors: G. V. Tomarov, A. A. Shipkov

Published in: Thermal Engineering | Issue 8/2020

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Abstract

Basic principles are examined of the application of software tools (ST) for predicting the erosion-corrosion (EC) rate to ensure the integrity of equipment and piping of nuclear power station (NPS) power units. Methods for solving the erosion-corrosion problems encountered in NPS power units have been determined. Software tools that are used most widely throughout the world to solve erosion-corrosion problems in the nuclear power industry are reviewed. The specifics in the application abroad and in Russia are highlighted. Attention is given to the successful foreign experience in improving the corrosion-erosion resistance of piping and equipment based on the solution implemented in designing NPS power units. Information is presented on the development of Russian software tools and the results of their application to render the integrity of piping and equipment of NPS power units with a VVER reactor or fast breeder reactor due to numerical prediction and early detection of the maximum allowable erosion-corrosion metal thinning. The feasibility is substantiated of using the software tools in designing new NPS power units with a VVER-1200 reactor, assessing the residual service life, and prolonging the operation of existing NPSs. Examples are given of the ways for reduction in the erosion-corrosion rate of equipment components and piping of nuclear power units, for example, by controlling the intensity of the hydrodynamic component of erosion-corrosion and proper selection of the metal. It is demonstrated that the cost of power units with a VVER-1200 reactor (including export deliveries) can be reduced by a change-over to less erosion-corrosion resistant but relatively inexpensive steels. The prospects are noted on application in practice of STs to assess the carry over of iron-rich corrosion-erosion products into the working fluid of an NPS with a VVER-reactor. It is pointed out that, when changing over to operation of NPS power units at a super-rated power, this factor should be estimated using STs, and its effect on the wear rate and location of the zones wherein is the highest rate of thinning of the pipeline walls and equipment must be considered.

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J.-M. Willemenot, “WANO introduction,” in Proc. Int. Conf. on Flow Accelerated Corrosion 2016, Lille, France, May 24–27, 2016 (2016).

G. V. Tomarov, A. A. Shipkov, V. N. Lovchev, and D. F. Gutsev, “Methodology and measures for preventing unacceptable flow-accelerated corrosion thinning of pipelines and equipment of NPP power generating units,” Therm. Eng. 63, 730–737 (2016). https://doi.org/10.1134/S0040601516100104 CrossRef

B. Chexal, J. Horowitz, R. Jones, B. Dooley, C. Wood, M. Bouchacourt, F. Remy, F. Nordmann, and P. St Paul, Flow-Accelerated Corrosion in Power Plants, Electric Power Research Institute Report TR-106611 (Electric Power Research Inst., 1996).

B. Poulson, “Predicting and preventing flow accelerated corrosion in nuclear power plant,” Int. J. Nucl. Energy, 423295 (2014).

Y. Utanohara, Y. Nagaya, A. Nakamura, and M. Murase, “Influence of local flow field on flow accelerated corrosion downstream from an orifice,” J. Power Energy Syst. 6, 18–33 (2012). https://doi.org/10.1299/jpes.6.18 CrossRef

Nucl. Power Newsl. 11 (3) (2014).

O. A. Povarov, G. V. Tomarov, and V. N. Semenov, “Physical and chemical processes of geothermal fluid impact on metal of geothermal power plant equipment,” in Proc. World Geothermal Congr.-2000, Kyushu–Tohoku, Japan, May 28–June 10, 2000 (International Geothermal Association, Auckland, N. Z., 2000).

G. V. Tomarov, “The physicochemical processes and regularities of erosion-corrosion of the metal of the power equipment in two-phase flow,” Therm. Eng. 48, 761–770 (2001).

O. A. Povarov, G. V. Tomarov, and V. N. Zharov, “Erosion-corrosion of elements of saturated steam turbine units,” Teploenergetika, No. 12, 27–32 (1990).

10.

G. V. Tomarov, V. P. Povarov, A. A. Shipkov, A. F. Gromov, A. N. Kiselev, S. V. Shepelev, and A. V. Galanin, “Development and application of an information-analytic system on the problem of flow accelerated corrosion of pipeline elements in the secondary coolant circuit of VVER-440-based power units at the Novovoronezh nuclear power plant,” Therm. Eng. 62, 138–145 (2015). https://doi.org/10.1134/S0040601515020111 CrossRef

11.

G. V. Tomarov, A. A. Shipkov, T. N. Golubeva, and P. N. Greblov, “An investigation of the effect of hydrodynamics of flow on erosion-corrosion resistance of components of a feedwater control assembly used in power units of nuclear power plants equipped with RBMK-1000 reactors,” Therm. Eng. 60, 591–597 (2013). https://doi.org/10.1134/S0040601513080090 CrossRef

12.

A. Zander and B. Stellwag, “Calculation of the iron ingress into steam generators with the software program COMSY,” in Proc. Int. Conf. on Flow Accelerated Corrosion 2013, Avignon, France, 21–24 May 2013 (2013).

13.

I. Fumio and M. Ryo, Codes for Nuclear Power Generation Facilities—Rules on Pipe Wall Thinning Management for BWR Power Plants, JSME S NH1-2006 (Japan Society of Mechanical Engineers, 2006).

Title: Application of Software Tools for Predicting the Corrosion-Erosion Rate to Ensure Integrity of Equipment and Piping of Power Units at Nuclear Power Stations
Authors: G. V. Tomarov
A. A. Shipkov
Publication date: 01-08-2020
Publisher: Pleiades Publishing
Published in: Thermal Engineering / Issue 8/2020
Print ISSN: 0040-6015
Electronic ISSN: 1555-6301
DOI: https://doi.org/10.1134/S0040601520080054

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