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http://dx.doi.org/10.5000/EESK.2015.19.6.265

Application of Probabilistic Tsunami Hazard Analysis for the Nuclear Power Plant Site  

Rhee, Hyun-Me (Department of Earth Systems and Environmental Science, Chonnam National University)
Kim, Min Kyu (Integrated Safety Assessment Division, Kora Atomic Energy Research Institute (KAERI))
Sheen, Dong-Hoon (Department of Earth Systems and Environmental Science, Chonnam National University)
Choi, In-Kil (Integrated Safety Assessment Division, Kora Atomic Energy Research Institute (KAERI))
Publication Information
Journal of the Earthquake Engineering Society of Korea / v.19, no.6, 2015 , pp. 265-271 More about this Journal
Abstract
The tsunami hazard analysis is performed for testing the application of probabilistic tsunami hazard analysis to nuclear power plant sites in the Korean Peninsula. Tsunami hazard analysis is based on the seismic hazard analysis. Probabilistic method is adopted for considering the uncertainties caused by insufficient information of tsunamigenic fault sources. Logic tree approach is used. Uljin nuclear power plant (NPP) site is selected for this study. The tsunamigenic fault sources in the western part of Japan (East Sea) are used for this study because those are well known fault sources in the East Sea and had several records of tsunami hazards. We have performed numerical simulations of tsunami propagation for those fault sources in the previous study. Therefore we use the wave parameters obtained from the previous study. We follow the method of probabilistic tsunami hazard analysis (PTHA) suggested by the atomic energy society of Japan (AESJ). Annual exceedance probabilities for wave height level are calculated for the site by using the information about the recurrence interval, the magnitude range, the wave parameters, the truncation of lognormal distribution of wave height, and the deviation based on the difference between simulation and record. Effects of each parameters on tsunami hazard are tested by the sensitivity analysis, which shows that the recurrence interval and the deviation dominantly affects the annual exceedance probability and the wave heigh level, respectively.
Keywords
Tsunami; Nuclear power plant (NPP); Logic tree; Probabilistic tsunami hazard analysis (PTHA);
Citations & Related Records
Times Cited By KSCI : 6  (Citation Analysis)
연도 인용수 순위
1 Geist EL. Parsons T. Probabilistic analysis of tsunami hazards. Natural Hazards. 2006; 37: 277-314.   DOI
2 Korea Atomic Energy Research Institute. Probabilistic seismic hazard analysis procedure and application for nuclear power plant sites. KAERI/TR-4633/2012, Daejeon, Korea; c2012.
3 Rhee HM, Seo JM, Sheen DH, Choi IK. Probabilistic seismic hazard analysis on Metropolitan cities and counties in Korea. Journal of the Geological Society of Korea. 2012 Jun; 48(3):259-273.
4 Rhee HM, Kim MK, Sheen DH, Choi IK. Analysis of uniform hazard spectra for Metropolis in the Korean Peninsula, Earthquake Engineering Society of Korea. 2013 March; 17(2):71-77.   DOI   ScienceOn
5 Korea Electric Power Research Institute. Improvement of uncertainty in probabilistic seismic hazard analysis, TM.96NJ21.M1998.236, Daejeon, Korea; c1998.
6 Korea Atomic Energy Research Institute. Sensitivity of input parameters in the PSHA for NPP sites. KAERI/TR-3931/2009, Daejeon, Korea; c2009.
7 Seo JM, Rhee HM, Choi IK. A study on the best estimate of seismicity parameter b-value and its application for the seismic hazard analysis of the Korean Peninsula. Earthquake Engineering Society of Korea. 2010 Feb; 14(1):35-42.   DOI   ScienceOn
8 Rhee HM, Seo JM, Choi IK. A study on the uncertainty of seismic hazard in the PSHA for a Korean NPP site. 10th Korea-Japan Probabilistic Safety Assessment workshop; 2009 May 18-20; Jeju, Korea.
9 Choi BH, Efim P, Woo SB, Lee JW, Mun JY. Simulation of tsunami in the east sea using dynamically-interfaced multi-grid model. Earthquake Engineering Society of Korea. 2003 Feb;7(1):41-55.   DOI   ScienceOn
10 Yoon SB, Lim CH. Active dispersion-correction scheme of 2-D finite element model for simulation of tsunami propagation. Korean Society on Coastal and Ocean Engineers. 2005 Mar;17(1):1-8.
11 Choi BH, Efim P, Lee JS, Woo SB. Estimation of tsunami risk zoning on the coasts adjacent to the east sea from hypothetical earthquakes. Earthquake Engineering Society of Korea. 2002 Oct;6(5):1-17.
12 Lee H, Lee DS. Revaluation of tsunami risk at the site of Ulchin nuclear power plant. Korean Society on Coastal and Ocean Engineers. 2002 Mar;14(1):1-7.
13 Thio HK, Somerville P, Ichinose G. Probabilistic analysis of strong ground motion and tsunami hazars in Southeast Asia. Journal of Earthquake and Tsunami. 2007 Jun; 1(2): 1-19.   DOI
14 Annaka T, Satake K, Sakakiyama T, Yanagisawa K, Shuto N. Logic-tree approach for probabilistic tsunami hazard analysis and its applications to the Japanes coasts. Pure and Applied Geophysics. 2007; 164: 577-592.   DOI
15 Sakai T, Takeda T, Soraoka H, Yanagisawa K. Proceeding of International Conference on Nuclear Engineering 14th; 2006 Jul 17-20; Miami, Frorida, USA; ASME; c2006.
16 Atomic Energy Society of Japan. Implementation standard concerning the tsunami probabilistic risk assessment of nuclear power plant: 2011, AESJ-SC-RK004E:2011, NISSEI EBLO INC., Tokyo, Japan; c2013.
17 Rhee HM, Kim MK, Seo JM, Sheen DH, Choi IK. Estimation of wave parameters for probabilistic tsunami hazard analysis considering the fault sources in the Western part of Japan, Earthquake Engineering Society of Korea. 2014 May; 18(3):151-160.   DOI   ScienceOn