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Modeling of the TOSQAN test facility with the lumped parameter code COCOSYS

  • E. Babilas , E. Urbonavicius und S. Rimkevicius
Veröffentlicht/Copyright: 26. März 2013
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Kerntechnik
Aus der Zeitschrift Kerntechnik Band 71 Heft 5-6

Abstract

Hydrogen distribution in the containment during severe accidents is an important safety issue of nuclear power plants operation. The detailed knowledge of the containment thermal-hydraulics is necessary for reliable predictions of pressure, temperature and gas distribution in the containment of the NPP during postulated accidents. For this purposes, the study of the International Standard Problem (ISP 47) has been started in 1999 with the test facilities TOSQAN, MISTRA and ThAI. The paper presents the COCOSYS nodalisation of the TOSQAN test facility. The results are analysed and compared with the experimental values.

Kurzfassung

Die Verteilung des Wasserstoffs im Containment während eines schweren Unfalls ist ein wichtiges Sicherheitsproblem beim Betrieb von Kernkraftwerken. Die detaillierte Kenntnis der Thermohydraulik des Containments ist notwendig für zuverlässige Prognosen des Drucks, der Temperatur und der Gasverteilung im Containment des Kernkraftwerks wärend eines Unfalls. Deshalb wurde 1999 mit der Untersuchung des Internationalen Standardproblems (ISP 47) mit Hilfe der Testanlagen TOSQAN, MISTRA und ThAI begonnen. Die vorliegende Arbeit stellt die COCOSYS-Nodalisation der Versuchsanlage TOSQAN vor. Die Ergebnisse werden analysiert und mit experimentellen Werten verglichen.

References

1Pershagen, B.: Light water reactor safety, 198910.1016/B978-0-08-035915-1.50009-6Suche in Google Scholar

2State of the Art Report on Containment Thermalhydraulics and Hydrogen Distribution, June 1999, OECD, NEA/CSNI/R (99) 16Suche in Google Scholar

3Huttermann, B.; Klein-Hessling, W: COCOSYS validation on HDR hydrogen distribution tests E11.1, E11.2 and E11.4, Eurosafe, 2002Suche in Google Scholar

4Specification of international standard problem on containment thermal-hydraulics, ISP-47, Step 1: TOSQAN – MISTRA. Revision 1, July, 2002Suche in Google Scholar

5Klein-Hessling, W.: Cocosys 1.2 Program Reference, 1998Suche in Google Scholar

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8Babilas, E.; Urbonavicius, E.; Rimkevicius, S.: Investigation of hydrogen distribution in Ignalina NPP ALS with COCOSYS code, Energetika, Nr. 1, pp. 915, 2005Suche in Google Scholar

9Urbonavicius, E.; Rimkevicius, S.: COCOSYS code validation against measured data during unintended single main safety valve opening at Ignalina NPP, Nuclear Engineering and Design, Nr. 232, pp. 173183, 200410.1016/j.nucengdes.2004.06.002Suche in Google Scholar

Received: 2006-4-19
Published Online: 2013-03-26
Published in Print: 2006-11-01

© 2006, Carl Hanser Verlag, München

Artikel in diesem Heft

  1. Contents/Inhalt
  2. Contents
  3. Summaries/Kurzfassungen
  4. Summaries
  5. Technical Contributions/Fachbeiträge
  6. Minor actinide burning in a CANDU thorium reactor
  7. Modeling of the TOSQAN test facility with the lumped parameter code COCOSYS
  8. Thermal-hydraulic modeling of the onset of flow instability in MTR reactors
  9. 10.3139/124.100302
  10. 10.3139/124.100304
  11. Radiation transfer in inhomogeneous exponential media
  12. Neutron transport problems for extremely anisotropic scattering
  13. Milne problem for isotropic and linearly anisotropic scattering for specular and diffuse reflecting boundary conditions solved with the HN method
  14. ICDE-results on complete common cause failures in the light of results obtained with the POS model
  15. Modelling of the cumulative behaviour of Caesium and Strontium activities in nuclear fuel
  16. Analytical study of the closure flow inside the ETRR-2 core chimney
  17. Minimizing radiation exposure for the reactor staff during the dismantling of a TRIGA research reactor
https://doi.org/10.3139/124.100300

Artikel in diesem Heft

  1. Contents/Inhalt
  2. Contents
  3. Summaries/Kurzfassungen
  4. Summaries
  5. Technical Contributions/Fachbeiträge
  6. Minor actinide burning in a CANDU thorium reactor
  7. Modeling of the TOSQAN test facility with the lumped parameter code COCOSYS
  8. Thermal-hydraulic modeling of the onset of flow instability in MTR reactors
  9. 10.3139/124.100302
  10. 10.3139/124.100304
  11. Radiation transfer in inhomogeneous exponential media
  12. Neutron transport problems for extremely anisotropic scattering
  13. Milne problem for isotropic and linearly anisotropic scattering for specular and diffuse reflecting boundary conditions solved with the HN method
  14. ICDE-results on complete common cause failures in the light of results obtained with the POS model
  15. Modelling of the cumulative behaviour of Caesium and Strontium activities in nuclear fuel
  16. Analytical study of the closure flow inside the ETRR-2 core chimney
  17. Minimizing radiation exposure for the reactor staff during the dismantling of a TRIGA research reactor
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