Large strain nonlinear model of lead rubber bearings for beyond design basis earthquakes

Abstract Studies on the application of the lead rubber bearing (LRB) isolation system to nuclear power plants are being carried out as one of the measures to improve seismic performance. Nuclear power plants with isolation systems require seismic probabilistic safety assessments, for which the seismic fragility of the structures, systems, and components needs be calculated, including for beyond design basis earthquakes. To this end, seismic response analyses are required, where it can be seen that the behaviors of the isolation system components govern the overall seismic response of an isolated plant. The numerical model of the LRB used in these seismic response analyses plays an important role, but in most cases, the extreme performance of the LRB has not been well studied. The current work therefore develops an extreme nonlinear numerical model that can express the seismic response of the LRB for beyond design basis earthquakes. A full-scale LRB was fabricated and dynamically tested with various input conditions, and test results confirmed that the developed numerical model better represents the behavior of the LRB over previous models. Subsequent seismic response analyses of isolated nuclear power plants using the model developed here are expected to provide more accurate results for seismic probabilistic safety assessments.

[1]  Andrew S. Whittaker,et al.  SEISMIC ISOLATION OF NUCLEAR POWER PLANTS , 2014 .

[2]  M. K. Kim,et al.  Seismic response of base isolated nuclear power plants considering impact to moat walls , 2018 .

[3]  Hyung-Jo Jung,et al.  Seismic fragility assessment of isolated structures by using stochastic response database , 2018 .

[4]  Hyung-Jo Jung,et al.  Seismic response distribution estimation for isolated structures using stochastic response database , 2015 .

[5]  Dimitrios Konstantinidis,et al.  Mechanics of Rubber Bearings for Seismic and Vibration Isolation , 2011 .

[6]  Farhad Behnamfar,et al.  A new elastomeric-sliding seismic isolation system , 2018 .

[7]  Helmut Krawinkler,et al.  Deterioration Modeling of Steel Components in Support of Collapse Prediction of Steel Moment Frames under Earthquake Loading , 2011 .

[8]  Andrew S. Whittaker,et al.  BIDIRECTIONAL MODELLING OF HIGH-DAMPING RUBBER BEARINGS , 2004 .

[9]  Jung-Wuk Hong,et al.  Effect of second hardening on floor response spectrum of a base-isolated nuclear power plant , 2017 .

[10]  Jeong-Hoi Koo,et al.  Modeling of Magneto-Rheological Elastomers for Harmonic Shear Deformation , 2012, IEEE Transactions on Magnetics.

[11]  Andrew S. Whittaker,et al.  Modeling strength degradation in lead–rubber bearings under earthquake shaking , 2010 .

[12]  Marco Domaneschi,et al.  The numerical computation of seismic fragility of base-isolated Nuclear Power Plants buildings , 2013 .

[13]  Xxyyzz Seismic Analysis of Safety-Related Nuclear Structures and Commentary on Standard for Seismic Analysis of Safety Related Nuclear Structures , 1987 .

[14]  Y. Wen Method for Random Vibration of Hysteretic Systems , 1976 .

[15]  Andrew S. Whittaker,et al.  An advanced numerical model of elastomeric seismic isolation bearings , 2014 .

[16]  Michael C. Constantinou,et al.  Nonlinear Dynamic Analysis of 3‐D‐Base‐Isolated Structures , 1991 .