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http://dx.doi.org/10.1016/j.net.2021.09.031

Dynamic characteristics of combined isolation systems using rubber and wire isolators  

Lee, Seung-Jae (School of Architecture, Soongsil University)
Truong, Gia Toai (School of Architecture, Soongsil University)
Lee, Ji-Eon (School of Architecture, Soongsil University)
Park, Sang-Hyun (School of Architecture, Soongsil University)
Choi, Kyoung-Kyu (School of Architecture, Soongsil University)
Publication Information
Nuclear Engineering and Technology / v.54, no.3, 2022 , pp. 1071-1084 More about this Journal
Abstract
The present study aims to investigate the dynamic properties of a novel isolation system composed of separate rubber and wire isolators. The testing program comprised pure compressive, pure-shear, compressive-stress dependence, and shear-strain dependence tests that used full-scale test specimens according to ISO 22762-1. A total of 22 test specimens were fabricated and investigated. Among the tests, the pure compressive test was a destructive test that reached up to the failure stage, whereas the others were nondestructive tests before the failure stage. Similar to the pure-shear test, at each compressive-stress level in the compressive dependence test or at each shear-strain level in the shear-strain dependence test, the cyclic loading was conducted for three cycles. In the nondestructive tests, examination of the dynamic shear properties in the X-direction was independent of the Y-direction. The test results revealed that the increase in the shear strain increased the energy dissipation but decreased the damping ratio, whereas the increase in the compressive stress increased the damping ratio. In addition, a macro model was developed to simulate the load-displacement response of the isolation systems, and the prediction results were consistent with the experimental results.
Keywords
Dynamic properties; Isolation systems; Wire isolators; Rubber isolators; Compressive stress; Shear strain; Dependence test; Modeling;
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1 W.G. Liu, W.F. He, D.M. Feng, Q.R. Yang, Vertical stiffness and deformation analysis models of rubber isolators in compression and compression-shear states, J. Eng. Mech. 35 (9) (2009) 945-952.
2 T.V. Ngo, A. Dutta, S.K. Deb, Evaluation of horizontal stiffness of fibre-reinforced elastomeric isolators, Earthq. Eng. Struct. Dynam. 46 (11) (2017) 1747-1767.   DOI
3 W.H. Robinson, Lead-rubber hysteretic bearings suitable for protecting structures during earthquakes, Earthq. Eng. Struct. Dynam. 10 (1982) 593-604.   DOI
4 T. Nishi, S. Suzuki, M. Aoki, T. Sawada, S. Fukuda, International investigation of shear displacement capacity of various elastomeric seismic-protection isolators for buildings, J. Rubber Res. 22 (2019) 33-41.   DOI
5 E. Tubaldi, S.A. Mittoulis, H. Ahmadi, A. Muhr, A parametric study on the axial behavior of elastomeric isolators in multi-span bridges subjected to horizontal seismic excitations, Bull. Earthq. Eng. 14 (2016) 1285-1310.   DOI
6 M. Yamamoto, S. Minewaki, H. Yoneda, M. Higashino, Nonlinear behavior of high-damping rubber bearings under horizontal bidirectional loading: full-scale tests and analytical modeling, Earthq. Eng. Struct. Dynam. 41 (13) (2012) 1845-1860.   DOI
7 American Society of Civil Engineers, Minimum Design Loads and Associated Criteria for Buildings and Other Structures, American Society of Civil Engineering, Virginia, USA, 2017. ASCE/SEI 7-16.
8 K.N.G. Fuller, J. Gough, H.R. Ahmadi, Predicting the response of high damping rubber bearings using simplified models and finite element analysis, in: Proceedings of the International Atomic Energy Agency Meeting, vol. 50, also for Publication 1580 TARRC, Rubber Developments, St. Petersburg, Russia, 1996. No. 1/2, 1997.
9 N. Murota, T. Mori, An experimental study on scale effect in dynamic shear properties of high-damping rubber bearings, Front. Built Environ. 6 (2020) 37, https://doi.org/10.3389/fbuil.2020.00037.   DOI
10 V. Gonca, S. Polukoshko, Buckling stability of multilayered rubber-metal vibration isolator, Vibroeng. Procedia 3 (2014) 319-325.
11 D. Losanno, I.E.M. Sierra, M. Spizzuoco, J. Marulanda, P. Thomson, Experimental assessment and analytical modeling of novel fiber-reinforced isolators in unbounded configuration, Compos. Struct. 212 (2019) 66-82.   DOI
12 A. Purgstaller, P.Q. Gallo, S. Pampanin, K. Bergmeister, Seismic demands on nonstructural components anchored to concrete accounting for structure-fastener-nonstructural interaction (SFNI), Earthq. Eng. Struct. Dynam. 49 (6) (2020) 589-606.   DOI
13 P.S. Balaji, L. Moussa, M.E. Rahman, L.H. Ho, An analytical study on the static vertical stiffness of wire rope isolators, J. Mech. Sci. Technol. 30 (1) (2016a) 287-295.   DOI
14 International Organization for Standardization, Elastomeric Seismic-Protection Isolatorsd Part 1: Test Methods, ISO 22762-1, 2018 (Geneva, Switzerland).
15 P.S. Balaji, L. Moussa, M.E. Rahman, L.H. Ho, Static lateral stiffness of wire rope isolators, Mech. Base. Des. Struct. Mach. 44 (4) (2016b) 462-475.   DOI
16 W. Wei, Y. Yuan, A. Igarashi, P. Tan, H. Iemura, H.P. Zhu, A generalized rate-dependent constitutive law for elastomeric bearings, Construct. Build. Mater. 106 (2016) 693-699.   DOI
17 G.P. Warn, K.L. Ryan, A review of seismic isolation for buildings: historical development and research needs, Buildings 2 (3) (2012) 300-325.   DOI
18 H. Zhu, Z. Zhang, F. Zhou, H. Luo, X. Deng, Horizontal mechanical behavior of elastomeric bearings under eccentric vertical loading: full-scale tests and analytical modeling, Construct. Build. Mater. 125 (2016) 574-584.   DOI
19 P. Narjabadifam, P.L.Y. Tiong, R. Mousavi-Alanjagh, Effects of inherent structural characteristics on seismic performances of aseismically base-isolated buildings, Iran. J. Sci. Technol. Trans. Civil Eng. 44 (2019) 1385-1401.   DOI
20 F. Naeim, J.M. Kelly, Design of Seismic Isolated Structures: from Theory to Practice, first ed., John Wiley and Sons, Hoboken, NJ, USA, 1999.
21 N. Fallah, G. Zamiri, Multi-objective optimal design of sliding base isolation using genetic algorithm, Sci. Iran. 20 (1) (2013) 87-96.   DOI