RELAP5 code posttest analyses were performed on ROSA/LSTF experiments that simulated PWR 0.2% vessel bottom small-break loss-of-coolant accidents with different accident management (AM) measures under assumptions of noncondensable gas inflow and total failure of high-pressure injection system. Depressurization of and auxiliary feedwater (AFW) injection into the secondary-side of both steam generators (SGs) as the AM measures were taken 10 min after a safety injection signal. The primary depressurization rate of 55 K/h caused rather slow primary depressurization being obstructed by the gas accumulation in the SG U-tubes after the completion of accumulator coolant injection. Core temperature excursion thus took place by core boil-off before the actuation of low-pressure injection (LPI) system. The fast primary depressurization by fully opening the relief valves in both SGs with continuous AFW injection led to long-term core cooling by the LPI actuation even under the gas accumulation in the SG U-tubes. The code indicated remaining problems in the predictions of break flow rate during two-phase flow discharge period and primary pressure after the gas inflow. Influences of the primary depressurization rate with continuous AFW injection onto the long-term core cooling were clarified by the sensitivity analyses.

References

1 USNRC, Leakage from Reactor Pressure Vessel Lower Head Penetrations and Reactor Coolant Pressure Boundary Integrity, Bulletin 2003-02, OMB Control 3150-0012, 2003.
Google Scholar
2 Fletcher C. D. and Bolander M. A., Analysis of instrument tube ruptures in the Zion-1 pressurized water reactor, Nuclear Technology. (1988) 81, no. 1, 52–62, 2-s2.0-0023994433.
Google Scholar
3 Kukita Y., Asaka H., Nakamura H., and Tasaka K., Pressurized water reactor core instrument tube ruptures: experimental simulation at the ROSA-IV LSTF, Nuclear Engineering and Design. (1990) 120, no. 2-3, 249–257, https://doi.org/10.1016/0029-5493(90)90377-A, 2-s2.0-44949287364.
Google Scholar
4 Kukita Y., Tasaka K., Asaka H., Yonomoto T., and Kumamaru H., The effects of break location on PWR small break LOCA: experimental study at the ROSA-IV LSTF, Nuclear Engineering and Design. (1990) 122, no. 1–3, 255–262, https://doi.org/10.1016/0029-5493(90)90210-O, 2-s2.0-0347181027.
Google Scholar
5 The ROSA-V Group, ROSA-V large scale test facility (LSTF) system description for the third and fourth simulated fuel assemblies, JAERI-Tech, 2003, no. 2003-037, Japan Atomic Energy Research Institute, Ibaraki, Japan.
Google Scholar
6 Asaka H. and Kukita Y., Intentional depressurization of steam generator secondary side during a PWR small-break loss-of-coolant accident, Journal of Nuclear Science and Technology. (1995) 32, no. 2, 101–110, 2-s2.0-0029247680.
Google Scholar
7 Loomis G. G., Summary of the Semiscale program (1965–1986), USNRC Report, 1987, no. NUREG/CR-4945, EGG-2509.
Google Scholar
8 Addabbo C. and Annunziato A., The LOBI integral system test facility experimental programme, Science and Technology of Nuclear Installations. (2012) 2012, 16, 238019, https://doi.org/10.1155/2012/238019, 2-s2.0-84855327151.
10.1155/2012/238019
Google Scholar
9 Umminger K., Dennhardt L., Schollenberger S., and Schoen B., Integral test facility PKL: experimental PWR accident investigation, Science and Technology of Nuclear Installations. (2012) 2012, 16, 891056, https://doi.org/10.1155/2012/891056, 2-s2.0-84861074445.
10.1155/2012/891056
Web of Science® Google Scholar
10 Asaka H., Anoda Y., Kukita Y., and Ohtsu I., Secondary-side depressurization during PWR cold-leg small break LOCAs based on ROSA-V/LSTF experiments and analyses, Journal of Nuclear Science and Technology. (1998) 35, no. 12, 905–915, https://doi.org/10.1080/18811248.1998.9733963, 2-s2.0-0032273158.
CAS Web of Science® Google Scholar
11 Takeda T., Ohwada A., and Nakamura H., Measurement of non-condensable gas in a PWR small-break LOCA simulation test with LSTF for OECD/NEA ROSA Project and RELAP5 post-test analysis, Experimental Thermal and Fluid Science. (2013) 51, 112–121, https://doi.org/10.1016/j.expthermflusci.2013.07.007, 2-s2.0-84883271813.
CAS Web of Science® Google Scholar
12 Nakamura H., Watanabe T., Takeda T., Asaka H., Kondo M., Maruyama Y., Ohtsu I., and Suzuki M., RELAP5/MOD3 code verification through PWR pressure vessel small break loca tests in OECD/NEA ROSA project, Proceedings of the 16th International Conference on Nuclear Engineering (ICONE-16 ′08), May 2008, Orlando, Fla, USA, 659–668, 2-s2.0-70349153855.
Google Scholar
13 Nakamura H., Watanabe T., Takeda T., Maruyama Y., and Suzuki M., Overview of recent efforts through ROSA/LSTF experiments, Nuclear Engineering and Technology. (2009) 41, no. 6, 753–764, https://doi.org/10.5516/NET.2009.41.6.753, 2-s2.0-70349268113.
Google Scholar
14 Asaka H. and Anoda Y., Study of accident management measures for prevention of severe core damage in ROSA-V program, Japanese Journal of Multiphase Flow. (2003) 17, no. 2, 116–125.
Google Scholar
15 Suzuki M., Takeda T., Asaka H., and Nakamura H., Experimental study on secondary depressurization action for PWR vessel bottom small break LOCA with HPI failure and gas inflow (ROSA-V/LSTF Test SB-PV-03), JAERI-Research 2005-014, 2005, Japan Atomic Energy Research Institute, Ibaraki, Japan.
Google Scholar
16 Suzuki M., Takeda T., Asaka H., and Nakamura H., An experimental study on effective depressurization actions for PWR vessel bottom break LOCA with HPI failure and gas inflow (ROSA-V/LSTF Test SB-PV-04), JAEA-Research, 2006, no. 2006-018, Japan Atomic Energy Agency, Ibaraki, Japan.
Google Scholar
17 Suzuki M., Takeda T., Asaka H., and Nakamura H., A study on timing of rapid depressurization action during PWR vessel bottom break LOCA with HPI failure and AIS-gas inflow (ROSA-V/LSTF test SB-PV-06), JAEA-Research-2007-037, 2007, Japan Atomic Energy Agency, Ibaraki, Japan.
Google Scholar
18 RELAP5 Code Development Team, RELAP5/MOD3 code manual, 1995, no. NUREG/CR-5535 (INEL-95/0174), Idaho National Engineering Laboratory.
Google Scholar
19 Suzuki M., Takeda T., Asaka H., and Nakamura H., Effects of secondary depressurization on core cooling in PWR vessel bottom small break LOCA experiments with HPI failure and gas inflow, Journal of Nuclear Science and Technology. (2006) 43, no. 1, 55–64, https://doi.org/10.3327/jnst.43.55, 2-s2.0-32444446066.
Google Scholar
20 Takeda T., Watanabe T., and Nakamura H., Effectiveness of AM measures for long-term core cooling during PWR vessel bottom small-break LOCA based on RELAP5 analyses of ROSA/LSTF experiment, Proceedings of the 9th International Topical Meeting on Nuclear Thermal-Hydraulics, Operation and Safety (NUTHOS-9 ′12), September 2012, Kaohsiung, Taiwan.
Google Scholar
21 Zuber N., Problems in modeling small break LOCA, USNRC Report NUREG-0724, 1980.
Google Scholar
22 Kumamaru H. and Tasaka K., Recalculation of simulated post-scram core power decay curve for use in ROSA-IV/LSTF experiments on PWR small-break LOCAs and transients, 1990, no. JAERI-M 90-142, Japan Atomic Energy Research Institute, Ibaraki, Japan.
Google Scholar
23 Asaka H., Kukita Y., Yonomoto T., Koizumi Y., and Tasaka K., Results of 0.5% cold-leg small-break LOCA experiments at ROSA-IV/LSTF: effect of break orientation, Experimental Thermal and Fluid Science. (1990) 3, no. 6, 588–596, https://doi.org/10.1016/0894-1777(90)90075-I, 2-s2.0-0025519264.
CAS Web of Science® Google Scholar
24 Fauske H. K., The discharge of saturated water through tubes, Chemical Engineering and Progress Symposium Series. (1965) 61, no. 59, 210–216.
Google Scholar
25 Ardron K. H. and Furness R. A., A study of the critical flow models used in reactor blowdown analysis, Nuclear Engineering and Design. (1976) 39, no. 2-3, 257–266, https://doi.org/10.1016/0029-5493(76)90074-1, 2-s2.0-0017218819.
Web of Science® Google Scholar
26 Sallet D. W., Thermal hydraulics of valves for nuclear applications, Nuclear Science and Engineering. (1984) 88, no. 3, 220–244, 2-s2.0-0021529367.
10.13182/NSE84-A18579
Google Scholar
27 Susyadi and Yonomoto T., Analysis on non uniform flow in steam generator during steady state natural circulation cooling, JAERI- Research, 2005, no. 2005-011, Japan Atomic Energy Research Institute, Ibaraki, Japan.
Google Scholar
28 Takeda T., Asaka H., and Nakamura H., RELAP5 analysis of OECD/NEA ROSA project experiment simulating a PWR loss-of-feedwater transient with high-power natural circulation, Science and Technology of Nuclear Installations. (2012) 2012, 15, 957285, https://doi.org/10.1155/2012/957285, 2-s2.0-84859712374.
10.1155/2012/957285
Web of Science® Google Scholar
29 Shah M. M., A general correlation for heat transfer during film condensation inside pipes, International Journal of Heat and Mass Transfer. (1979) 22, no. 4, 547–556, https://doi.org/10.1016/0017-9310(79)90058-9, 2-s2.0-0018454368.
Google Scholar
30 Nusselt W. A., The surface condensation of water vapor, Zeitschrift des Vereines Deutscher Ingenieure. (1916) 60, 541–546.
Google Scholar
31 Vierow K. M. and E Schrock V., Condensation in a natural circulation loop with non-condensable gases part I—heat transfer, Proceedings of International Conference on Multiphase Flows, September 1991, Ibaraki, Japan.
Google Scholar
32 Wilson G. E. and Boyack B. E., The role of the PIRT process in experiments, code development and code applications associated with reactor safety analysis, Nuclear Engineering and Design. (1998) 186, no. 1-2, 23–37, https://doi.org/10.1016/S0029-5493(98)00216-7, 2-s2.0-0032205848.
Google Scholar
33 Boyack B. E. and Ward L. W., Validation test matrix for the consolidated TRAC (TRAC-M) code, Proceedings of the International Meeting on Best Estimate Methods in Nuclear Installation Safety Analysis (BE ′00), November 2000, Washington, Wash, USA.
Google Scholar
34 Yamaguchi A., Mizokami S., Kudo Y., and Hotta A., Uncertainty and conservatism in safety evaluations based on a BEPU approach, Proceedings of the 13th International Topical Meeting on Nuclear Reactor Thermal Hydraulics (NURETH-13 ′09), September-October 2009, Ishikawa, Japan.
Google Scholar

Citing Literature

All articles

RELAP5 Analyses of ROSA/LSTF Experiments on AM Measures during PWR Vessel Bottom Small-Break LOCAs with Gas Inflow

Abstract

References

Citing Literature

Figures

References

Information

About Wiley Online Library

Help & Support

Opportunities

Connect with Wiley

RELAP5 Analyses of ROSA/LSTF Experiments on AM Measures during PWR Vessel Bottom Small-Break LOCAs with Gas Inflow

Abstract

References

Citing Literature

Figures

References

Related

Information