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Meccanica

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31-10-2017

Development and theoretically evaluation of an STF–SF isolator for seismic protection of structures

Authors: Minghai Wei, Gang Hu, Lixiao Li, Haitao Liu

Published in: Meccanica | Issue 4-5/2018

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Abstract

This study deals with the mechanical behavior of a shear thickening fluid–sliding friction (STF–SF) isolator, and investigates the feasibility of its application in anti-seismic engineering from a theoretical perspective. The STF–SF isolator is composed of a conventional sliding friction (SF) material and a smart shear thickening fluid (STF) material. When the excitation energy is small, the SF material keeps the structure static or only has a small vibration. However, when the excitation energy is large, the STF material results a huge damping force and dissipation of the external energy, eventually reducing the relative motion between the base and the upper structure. To better understand this phenomenon, a mechanistic study of the STF–SF isolator is proceeded by an analytical model which is derived from flow momentum equations. After that, the seismic protective effect of the STF–SF isolator is evaluated at harmonic excitation with different accelerations through a single degree of freedom (SDOF) structure. Furthermore, the effects of layer gap, layer number and friction coefficient of the STF–SF isolator on the seismic protective effect are investigated. The results show that the STF–SF isolator can significantly decrease both the displacement response and the acceleration response of the SDOF structure. This theoretical study indicates the STF–SF isolator can be used in anti-seismic engineering.

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Skinner RI, Robinson WH, McVerry GH (1993) An introduction to seismic isolation. Wiley, New York

Kelly JM (1999) The role of damping in seismic isolation. Earthq Eng Struct Dyn 28:1717–1720CrossRef

Abdalla JA, Petrovski JT, Mohamedzein EA (2008) Vibration characteristics of a far field earthquake and its shaking effects on Dubai emerging skyscrapers. In: The 14th world conference on earthquake engineering, Beijing, China

Satish N, Sriram N, Erik J (2008) Structural control benchmark problem: phase II-nonlinear smart base-isolated building subjected to near-fault earthquakes. Struct Control Health Monit 15:653–656CrossRef

Jangid RS, Kelly JM (2010) Base isolation for near-fault motion. Earthq Eng Struct Dyn 30:691–707CrossRef

Mazza F, Vulcano A (2012) Effects of near-fault ground motions on the nonlinear dynamic response of base-isolated r.c. framed buildings. Earthq Eng Struct Dyn 41:211–232CrossRef

Shih M-C, Wang T-Y (2008) Active control of electro-rheological fluid embedded pneumatic vibration isolator. Integr Comput Aided Eng 15:267–276

Li Y, Li J, Tian T, Li W (2013) A highly adjustable magnetorheological elastomer base isolator for applications of real-time adaptive control. Smart Mater Struct 22:095020ADSCrossRef

Yang J, Sun S, Tian T, Li W, Du H, Alici G, Nakano M (2016) Development of a novel multi-layer MRE isolator for suppression of building vibrations under seismic events. Mech Syst Singal Process 70–71:811–820CrossRef

10.

Mekaouche A, Chapelle F, Balandraud X (2016) Using shape memory alloys to obtain variable compliance maps of a flexible structure: concept and modeling. Meccanica 51:1287–1299CrossRef

11.

Oh H-U, Onoda J, Minesugi K (2004) Semiactive isolator with liquid-crystal type ER fluid for momentum-wheel vibration isolation. J Vib Acoust 126:272–277CrossRef

12.

Stelzer GJ, Schulz MJ, Kim J, Allemang RJ (2003) A magnetorheological semi-active isolator to reduce noise and vibration transmissibility in automobiles. J Intell Mater Syst Struct 14:743–765CrossRef

13.

York D, Wang X, Gordaninejad F (2007) A new MR fluid-elastomer vibration isolator. J Intell Mater Syst Struct 18:1221–1225CrossRef

14.

Wang W, Song Y (2012) Nonlinear vibration semi-active control of automotive steering using magneto-rheological damper. Meccanica 47:2027–2039MathSciNetCrossRefMATH

15.

Yu Y, Li Y, Li J (2015) Parameter identification and sensitivity analysis of an improved LuGre friction model for magnetorheological elastomer base isolator. Meccanica 50:2691–2707CrossRef

16.

Nurul AAW, Mazlan SA, Kamaruddin S, Nik INI, Choi SB, Amirul HRS (2016) Fabrication and investigation on field-dependent properties of natural rubber based magneto-rheological elastomer isolator. Smart Mater Struct 25:107002ADSCrossRef

17.

Yu Y, Li Y, Li J, Gu X (2016) A hysteresis model for dynamic behaviour of magnetorheological elastomer base isolator. Smart Mater Struct 25:055029ADSCrossRef

18.

Attanasi G, Auricchio F, Fenves GL (2009) Feasibility assessment of an innovative isolation bearing system with shape memory alloys. J Earthq Eng 13:18–39CrossRef

19.

Jeong H-K, Han J-H, Youn S-H, Lee J (2014) Frequency tunable vibration and shock isolator using shape memory alloy wire actuator. J Intell Mater Syst Struct 25:908–919CrossRef

20.

Mondal PD, Ghosh AD, Chakraborty S (2017) Control of underground blast induced building vibration by shape-memory-alloy rubber bearing (SMARB). Struct Control Health Monit. https://doi.org/10.1002/stc.1983

21.

Gur S, Mishra SK, Chakraborty S (2014) Performance assessment of buildings isolated by shape-memory-alloy rubber bearing: comparison with elastomeric bearing under near-fault earthquakes. Struct Control Health Monit 21:449–465CrossRef

22.

Lee BW, Kim CG (2012) Computational analysis of shear thickening fluid impregnated fabrics subjected to ballistic impacts. Adv Compos Mater 21:177–192CrossRef

23.

Waitukaitis SR, Jaeger HM (2012) Impact-activated solidification of dense suspensions via dynamic jamming fronts. Nature 487:205–209ADSCrossRef

24.

Pinto F, Meo M (2016) Design and manufacturing of a novel shear thickening fluid composite (STFC) with enhanced out-of-plane properties and damage suppression. Appl Compos Mater 24:1–18

25.

Majumdar A, Butola BS, Srivastava A, Bhattacharjee D, Biswas I, Laha A, Arora S, Ghosh A (2016) Improving the impact resistance of p-aramid fabrics by sequential impregnation with shear thickening fluid. Fiber Polym 17:199–204CrossRef

26.

Park JL, Yoon BI, Paik JG, Kang TJ (2012) Ballistic performance of p-aramid fabrics impregnated with shear thickening fluid; Part II—effect of fabric count and shot location. Text Res J 82:542–557CrossRef

27.

Wei M, Hu G, Jin L, Lin K, Zou D (2016) Forced vibration of a shear thickening fluid sandwich beam. Smart Mater Struct 25:055041ADSCrossRef

28.

Iyer SS, Vedad-Ghavami R, Lee H, Liger M, Kavehpour HP, Candler RN (2013) Nonlinear damping for vibration isolation of microsystems using shear thickening fluid. Appl Phys Lett 102:251902ADSCrossRef

29.

Fischer C, Braun SA, Bourban PE, Michaud V, Plummer CJG, Manson JAE (2006) Dynamic properties of sandwich structures with integrated shear-thickening fluids. Smart Mater Struct 15:1467–1475ADSCrossRef

30.

Jiang WF, Gong XL, Xuan SH, Jiang WQ, Ye F, Li XF, Liu TX (2013) Stress pulse attenuation in shear thickening fluid. Appl Phys Lett 102:101901ADSCrossRef

31.

Lee YS, Wetzel ED, Wagner NJ (2003) The ballistic impact characteristics of Kevlar (R) woven fabrics impregnated with a colloidal shear thickening fluid. J Mater Sci 38:2825–2833ADSCrossRef

32.

Park Y, Kim Y, Baluch AH, Kim C-G (2015) Numerical simulation and empirical comparison of the high velocity impact of STF impregnated Kevlar fabric using friction effects. Compos Struct 125:520–529CrossRef

33.

Fischer C, Bennani A, Michaud V, Jacquelin E, Manson JAE (2010) Structural damping of model sandwich structures using tailored shear thickening fluid compositions. Smart Mater Struct 19:035017ADSCrossRef

34.

Zhang XZ, Li WH, Gong XL (2008) The rheology of shear thickening fluid (STF) and the dynamic performance of an STF-filled damper. Smart Mater Struct 17:035027ADSCrossRef

35.

Zhou H, Yan LX, Jiang WQ, Xuan SH, Gong XL (2014) Shear thickening fluid–based energy-free damper: design and dynamic characteristics. J Intell Mater Syst Struct 27:1–13

36.

Yeh FY, Chang KC, Chen TW, Yu CH (2014) The dynamic performance of a shear thickening fluid viscous damper. J Chin Inst Eng 37:983–994CrossRef

37.

Mostaghel N, Davis T (1997) Representations of Coulomb friction for dynamic analysis. Earthq Eng Struct Dyn 26:541–548CrossRef

38.

Ismail M, Casas JR (2016) Evaluation and refinement of closely spaced buildings’ performance under near-fault ground motions. Struct Infrastruct Eng 12:21–44CrossRef

39.

China Standard, GB 20688.3-2006 (2006) Rubber bearing-Part 3: Elastomeric seismic-protection isolators of buildings., Beijing

40.

Standard China (2006) JT/T 663-2006. Series of elastomeric pad bearings for highway bridges, Beijing

41.

Standard China (2010) GB 50011-2010. Code for seismic design of buildings, Beijing

Title: Development and theoretically evaluation of an STF–SF isolator for seismic protection of structures
Authors: Minghai Wei
Gang Hu
Lixiao Li
Haitao Liu
Publication date: 31-10-2017
Publisher: Springer Netherlands
Published in: Meccanica / Issue 4-5/2018
Print ISSN: 0025-6455
Electronic ISSN: 1572-9648
DOI: https://doi.org/10.1007/s11012-017-0785-z

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