[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/sss.2019.23.1.091

Real-time hybrid simulation of smart base-isolated raised floor systems for high-tech industry

Chen, Pei-Ching (Department of Civil and Construction Engineering, National Taiwan University of Science and Technology)
Hsu, Shiau-Ching (Department of Civil Engineering, National Taiwan University)
Zhong, You-Jin (Department of Civil Engineering, National Taiwan University)
Wang, Shiang-Jung (Department of Civil and Construction Engineering, National Taiwan University of Science and Technology)

Publication Information

Smart Structures and Systems / v.23, no.1, 2019 , pp. 91-106 More about this Journal

Abstract

Adopting sloped rolling-type isolation devices underneath a raised floor system has been proved as one of the most effective approaches to mitigate seismic responses of the protected equipment installed above. However, pounding against surrounding walls or other obstructions may occur if such a base-isolated raised floor system is subjected to long-period excitation, leading to adverse effects or even more severe damage. In this study, real-time hybrid simulation (RTHS) is adopted to assess the control performance of a smart base-isolated raised floor system as it is an efficient and cost-effective experimental method. It is composed of multiple sloped rolling-type isolation devices, a rigid steel platen, four magnetorheological (MR) dampers, and protected high-tech equipment. One of the MR dampers is physically tested in the laboratory while the remainders are numerically simulated. In order to consider the effect of input excitation characteristics on the isolation performance, the smart base-isolated raised floor system is assumed to be located at the roof of a building and the ground level. Four control algorithms are designed for the MR dampers including passive-on, switching, modified switching, and fuzzy logic control. Six artificial spectrum-compatible input excitations and three slope angles of the isolation devices are considered in the RTHS. Experimental results demonstrate that the incorporation of semi-active control into a base-isolated raised floor system is effective and feasible in practice for high-tech industry.

Keywords

raised floor system; sloped rolling-type isolation device; magnetorheological damper; semi-active control; real-time hybrid simulation;

Citations & Related Records

Times Cited By KSCI : 5 (Citation Analysis)

Reference
Cited By KSCI

1	AC156 (2010), Acceptance Criteria for Seismic Qualification by Shake-table Testing of Nonstructural Components and Systems. ICC Evaluation Service inc.
2	Bahar, A., Salavati-Khoshghalb, M. and Ejabati, S.M. (2018), "Seismic protection of smart base-isolated structures using negative stiffness device and regulated damping", Smart Struct. Syst., 21(3), 359-371. DOI
3	Chae, Y., Kazemibidokhti, K. and Ricles, J.M. (2013), "Adaptive time series compensator for delay compensation of servohydraulic actuator systems for real-time hybrid simulation", Earthq. Eng. Struct. D., 42(11), 1697-1715. DOI
4	Chai, J.F., Loh, C.H. and Sato, T. (2002), "Modeling of phase spectrum to simulate design ground motions", J. Chinese Inst. Engineers, 25(4), 447-459. DOI
5	Chen, P.C. and Tsai, K.C. (2013) "Dual compensation strategy for real-time hybrid testing", Earthq. Eng. Struct. D., 42(1), 1-23. DOI
6	Cho, S.W., Kim, B.W., Jung, H.J. and Lee, I.W. (2005) "Implementation of modal control for seismically excited structures using magnetorheological dampers", Journal of Engineering Mechanics (ASCE), 131(2), 177-184. DOI
7	Hayati, S. and Song, W. (2017) "An optimal discrete-time feedforward compensator for real-time hybrid simulation", Smart Struct. Syst., 20(4), 483-498. DOI
8	Darby, A.P., Williams, M.S. and Blakeborough, A. (2002), "Stability delay compensation for real-time substructure testing", J. Eng. Mech. - ASCE, 128(12), 1276 -1284. DOI
9	Dyke, S.J., Spencer, B.F., Sain, M.K. and Carlson, J.D. (1996) "Modeling and control of magnetorheological dampers for seismic response reduction", Smart Mater. Struct., 5(5), 565-575. DOI
10	Friedman, A., Dyke, S.J., Phillips, B.M., Ahn, R., Dong, B., Chae, Y., Castaneda, N., Jiang, Z., Zhang, J., Cha, Y., Ozdagli, A.I., Spencer, B.F., Ricles J.M., Christenson, R., Agrawal, A. and Sause, R. (2015), "Large-scale real-time hybrid simulation for evaluation of advanced damping system performance", J. Struct. Eng. - ASCE, 141(6), 04014150. DOI
11	Horiuchi, T., Inoue, M., Konno, T. and Namita, Y. (1999), "Realtime hybrid experimental system with actuator delay compensation and its application to a piping system with energy absorber", Earthq. Eng. Struct. D., 28(10), 1121-1141. DOI
12	Shao, X., Lindt, J., Bahmani, P., Pang, W., Ziaei, E., Symans, M., Tian, J. and Dao, T. (2014), "Real-time hybrid simulation of a multi-story wood shear wall with first-story experimental substructure incorporating a rate-dependent seismic energy dissipation device", Smart Struct. Syst., 14(6), 1031-1054. DOI
13	Javanbakht, M. and Amini, F. (2016), "Application of simple adaptive control to an mr damper-based control system for seismically excited nonlinear buildings", Smart Struct. Syst., 18(6), 1251-1267. DOI
14	Jung, R.Y., Shing, P.B., Stauffer, E. and Bradford, T. (2007), "Performance of a real-time pseudodynamic test system considering nonlinear structural response", Earthq. Eng. Struct. D., 36(12), 1785-1809. DOI
15	Liao, W.I., Chai, J.F., Loh, C.H. and Huang, S.H. (2013), "Seismic performance of raised floor system by shake-table excitations", Struct. Des. Tall Spec. Build., 22(10), 770-782. DOI
16	Mamdani, E.H. (1974), "Application of fuzzy algorithms for control of simple dynamic plant", Proceedings of the Institution of Electrical Engineers, 121(12), 1585-1588. DOI
17	Ramallo, J.C., Johnson, E.A. and Spencer, B.F. (2002), "Smart base isolation systems", J. Eng. Mech. - ASCE, 128(10), 1088-1099. DOI
18	Wang, S.J., Hwang, J.S., Chang, K.C., Shiau, C.Y., Lin, W.C., Tsai, M.S., Hong, J.X. and Yang, Y.H. (2014), "Sloped multiroller isolation devices for seismic protection of equipment and facilities", Earthq. Eng. Struct. D., 43(10),1443-1461. DOI
19	Wang, S.J., Yu, C.H., Lin, W.C., Hwang, J.S. and Chang, K.C. (2017), "A generalized analytical model for sloped rolling-type seismic isolators", Eng. Struct., 138, 434-446. DOI
20	Zhang, R., Phillips B.M., Taniguchi, S., Ikenaga, M. and Ikago, K. (2017) "Shake table real-time hybrid simulation techniques for the performance evaluation of buildings with inter-story isolation", Struct. Control Health Monit., 24(10), e1971. DOI
21	Zheng, L. and Li, Y.N. (2009), "Fuzzy-sliding mode control of a full car semi-active suspension systems with mr dampers", Smart Struct. Syst., 5(3), 261-277. DOI

3	(2020) Earthquakes and structures A versatile small-scale structural laboratory for novel experimental earthquake engineering / 18 (3) , 337
6	(2019) Earthquakes and structures A novel risk assessment approach for data center structures / 19 (6) , 471
1	(2019) Earthquakes and structures Early adjusting damping force for sloped rolling-type seismic isolators based on earthquake early warning information / 20 (1) , 39
1	(2019) Smart structures and systems Advancing real-time hybrid simulation for coupled nonlinear soil-isolator-structure system / 28 (1) , 105