Advertisement

Managing the Ageing Degradation of Concealed Safety Relevant Cooling Water Piping in European S/KWU LWRs

  • Martin WideraEmail author
  • Gerd Ahlers
  • Bernd Gruhne
  • Thomas Wermelinger
Conference paper
Part of the The Minerals, Metals & Materials Series book series (MMMS)

Abstract

Safety relevant cooling water piping is designed to transport excess heat both from the reactor core and the fuel pool under all operational and emergency conditions. Plain carbon steels are used, with or without different types of protective coating systems. Outside of the reactor building, such piping is often buried or concealed, which also gives additional protection against damage. Relevant ageing mechanisms are shallow pit corrosion and microbiological induced corrosion (MIC). While these ageing mechanisms can lead to localized leaks and limited loss of cooling water, neither the mechanical integrity nor the cooling ability of the systems are compromised. The extent and ageing management of the mechanisms are described, based on more than 30 years of operating experience. This includes NDT results and post service examinations after retrofits. Based on this positive operational experience, two different NDT concepts are recommended to manage the long time operational ageing.

Keywords

EU TPR WENRA Ageing management KTA 1403 S/KWU LWR Cooling water piping Concealed piping Buried piping Carbon steel Cement mortar lining Shallow pit corrosion MIC NDT Operating experience 

Notes

Acknowledgements

Special thanks of the authors are going both to AREVA Germany Materials Laboratory and to the ordering German NPP for giving permission to use their photographs.

References

  1. 1.
  2. 2.
    Topical Peer Review 2017, Ageing Management, Technical Specification for the National Assessment Reports, RHWG Report to WENRA, 21. December 2016. www.wenra.org, www.ensreg.eu
  3. 3.
    KTA 1403 (2010–11), Alterungsmanagement von Kernkraftwerken (Ageing Management in Nuclear Power Plants), www.kta-gs.de
  4. 4.
    Alterungsüberwachung, Richtlinie für die schweizerischen Kernanlagen, ENSI-B01/d, Ausgabe August 2011, www.ensi.ch
  5. 5.
    Verouderingsbeheer voor kernenergiecentrales, Veiligheidsrichtlijn NVR.NS-G-2.12, Jan 2011, Ministerie van Economische Zaken, Landbouw en Innovatie, Den Haag, (2011)Google Scholar
  6. 6.
    IAEA Safety Standards, Ageing Management for Nuclear Power Plants, Safety Guide No. NS-G-2.12, Wien, (2009). www.iaea.org
  7. 7.
    P. Barreiro et al., Nutzen des Alterungsmanagements in deutschen Kernkraftwerken. VGB PowerTech 5, 26–32 (2013)Google Scholar
  8. 8.
    VGB Kühlwasserrichtlinie – Wasserbehandlung und Werkstoffeinsatz in Kühlwassersystemen (VGB-R 455 P), Zweite überarbeitete Ausgabe 05/2000, VGB PowerTech Service GmbH, EssenGoogle Scholar
  9. 9.
    Rahmenspezifikation Basissicherheit, 24.05.1979, 2nd Appendix in: RSK-Leitlinien für DWR, 09/79, In: RSK-Leitlinien für Druckwasserreaktoren, 11/96, www.rskonline.de
  10. 10.
    GRS-Bericht A-3634, Betriebserfahrungen mit Komponenten der sicherheitstechnisch wichtigen Nebenkühlwassersysteme in deutschen Anlagen mit DWR und SWR, Gesellschaft für Anlagen- und Reaktorsicherheit GmbH, Köln, Februar 2012. www.grs.de
  11. 11.
    KTA 3211.4 (2013–11), Druck- und aktivitätsführende Komponenten von Systemen außerhalb des Primärkreises, Teil 4: Wiederkehrende Prüfungen und Betriebsüberwachung, (Pressure and Activity Retaining Components of Systems Outside the Primary Circuit—Part 4: Inservice Inspections and Operational Monitoring), www.kta-gs.de

Copyright information

© The Minerals, Metals & Materials Society 2019

Authors and Affiliations

  • Martin Widera
    • 1
    Email author
  • Gerd Ahlers
    • 2
  • Bernd Gruhne
    • 3
  • Thomas Wermelinger
    • 4
  1. 1.RWE Power AGEssenGermany
  2. 2.PreussenElektra GmbHHannoverGermany
  3. 3.EnBW Kernkraft GmbH Kernkraftwerk NeckarwestheimNeckarwestheimGermany
  4. 4.Kernkraftwerk Gösgen-Däniken AGDänikenSwitzerland

Personalised recommendations