Response of base‐isolated nuclear structures for design and beyond‐design basis earthquake shaking |
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| Authors: | Yin‐Nan Huang Andrew S Whittaker Robert P Kennedy Ronald L Mayes |
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| Institution: | 1. Department of Civil Engineering, National Taiwan University, , Taipei, 10617 Taiwan;2. Department of Civil, Structural and Environmental Engineering, University at Buffalo, State University of New York, , Buffalo, NY, 14260 USA;3. RPK Structural Mechanics Consulting Inc., , Escondido, CA, 92026 USA;4. Simpson Gumpertz & Heger Inc., , San Francisco, CA, 94105 USA |
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| Abstract: | The American Society of Civil Engineers (ASCE) 43‐05 presents two performance objectives for the design of nuclear structures, systems and components in nuclear facilities: (1) 1% probability of unacceptable performance for 100% design basis earthquake (DBE) shaking and (2) 10% probability of unacceptable performance for 150% DBE shaking. To aid in the revision of the ASCE 4‐98 procedures for the analysis and design of base‐isolated nuclear power plants and meet the intent of ASCE 43‐05, a series of nonlinear response‐history analyses was performed to study the impact of the variability in both earthquake ground motion and mechanical properties of isolation systems on the seismic responses of base‐isolated nuclear power plants. Computations were performed for three representative sites (rock and soil sites in the Central and Eastern United States and a rock site in the Western United States) and three types of isolators (lead rubber, Friction Pendulum and low‐damping rubber bearings) using realistic mechanical properties for the isolators. Estimates were made of (1) the ratio of the 99th percentile (90th percentile) response of isolation systems computed using a distribution of spectral demands and distributions of isolator mechanical properties to the median response of isolation systems computed using best‐estimate properties and 100% (150%) spectrum‐compatible DBE ground motions; (2) the number of sets of three‐component ground motions to be used for response‐history analysis to develop a reliable estimate of the median response of isolation systems. The results of this study provide the technical basis for the revision of ASCE Standard 4‐98. Copyright © 2012 John Wiley & Sons, Ltd. |
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| Keywords: | nuclear power plant base isolation design basis earthquake rubber bearing Friction Pendulum |
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