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http://dx.doi.org/10.12989/eas.2012.3.6.821

New three-layer-type hysteretic damper system and its damping capacity  

Kim, Hyeong Gook (Department of Urban and Environmental Engineering, Kyoto University)
Yoshitomi, Shinta (Department of Architecture and Architectural Engineering, Graduate School of Engineering, Kyoto University)
Tsuji, Masaaki (Department of Architecture and Architectural Engineering, Graduate School of Engineering, Kyoto University)
Takewaki, Izuru (Department of Architecture and Architectural Engineering, Graduate School of Engineering, Kyoto University)
Publication Information
Earthquakes and Structures / v.3, no.6, 2012 , pp. 821-838 More about this Journal
Abstract
This paper proposes a new three-layer pillar-type hysteretic damper system for residential houses. The proposed vibration control system has braces, upper and lower frames and a damper unit including hysteretic dampers. The proposed vibration control system supplements the weaknesses of the previously proposed post-tensioning vibration control system in the damping efficiency and cumbersomeness of introducing a post-tension. The structural variables employed in the damper design are the stiffness ratio ${\kappa}$, the ductility ratio ${\mu}_a$, and the ratio ${\beta}$ of the damper's shear force to the maximum resistance. The hysteretic dampers are designed so that they exhibit the targeted damping capacity at a specified response amplitude. Element tests of hysteretic dampers are carried out to examine the mechanical property and to compare its restoring-force characteristic with that of the analytical model. Analytical studies using an equivalent linearization method and time-history response analysis are performed to investigate the damping performance of the proposed vibration control system. Free vibration tests using a full-scale model are conducted in order to verify the damping capacity and reliability of the proposed vibration control system. In this paper, the damping capacity of the proposed system is estimated by the logarithmic decrement method for the response amplitudes. The accuracy of the analytical models is evaluated through the comparison of the test results with those of analytical studies.
Keywords
pillar-type hysteretic damper system; stiffness ratio; ductility ratio; damper's shear force; free vibration test; geometrical nonlinearity; logarithmic decrement method;
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  • Reference
1 Aiken, I.D., Nims, D.K., Whittaker, A.S. and Kelly, J.M. (1993), "Testing of passive energy dissipation systems", Earthq. Spectra, 9(3), 335-370.   DOI   ScienceOn
2 Apostolakis, G. and Dargush, G.F. (2010), "Optimal seismic design of moment-resisting steel frames with hysteretic passive devices", Earthq. Eng. Struct. D., 39(4), 355-376.
3 Benavent-Climent, A. (2011), "An energy-based method for seismic retrofit of existing frames using hysteretic dampers", Soil Dyn. Earthq. Eng., 31(10), 1385-1396.   DOI   ScienceOn
4 Chan, R.W.K. and Albermani, F. (2008), "Experimental study of steel slit damper for passive energy dissipation", Eng. Struct., 30(4), 1058-1066.   DOI   ScienceOn
5 Christopoulos, C. and Filiatrault, A. (2006), Principle of passive supplemental damping and seismic isolation, IUSS Press, University of Pavia, Italy.
6 Hanson, R.D. and Soong, T.T. (2001), Seismic design with supplemental energy dissipation devices, EERI, Oakland, CA.
7 Housner, G.W., Bergman, L.A., Caughey, T.K., Chassiakos, A.G., Claus, R.O., Masri, S.F., Skelton, R.E., Soong, T.T., Spencer, B.F. and Yao, J.T.P. (1997), "Special issue, Structural control : past, present, and future", J. Eng. Mech.-ASCE, 123(9), 897-971.   DOI
8 Inoue, K. and Kuwahara, S. (1998), "Optimum strength ratio of hysteretic damper", Earthq. Eng. Struct. D., 27(6), 577-588.   DOI   ScienceOn
9 Kozo System (2011), General-purpose elastic-plastic analysis program for arbitrary-shaped three-dimensional frames (SNAP), Tokyo.
10 Kim, H.G., Yoshitomi, S., Tsuji, M. and Takewaki, I. (2011), "Development of pillar-type hysteretic damper system composed of three layers and evaluation of its damping capacity", Proc. of The ASEM11+ Congress, Seoul, Korea, 1110-1124.
11 Kim, J.K. and Seo, Y.L. (2004), "Seismic design of low-rise steel frames with buckling-restrained braces", Eng. Struct., 26(5), 543-551.   DOI   ScienceOn
12 Li, H.N. and Li, G. (2007), "Experimental study of structure with "dual function" metallic dampers", Eng. Struct., 29(8), 1917-1928.   DOI   ScienceOn
13 Moreschi, L.M. and Singh, M.P. (2003), "Design of yielding metallic and friction dampers for optimal seismic performance", Earthq. Eng. Struct. D., 32(8), 1291-1311.   DOI   ScienceOn
14 Nakashima, M., Saburi, K. and Tsuji, B. (1996), "Energy input and dissipation behavior of structures with hysteretic dampers", Earthq. Eng. Struct. D., 25(5), 483-496.   DOI
15 Oh, S.H., Kim, Y.J. and Ryu, H.S. (2008), "Seismic performance of steel structures with slit dampers", Eng. Struct., 31(9), 1997-2008.
16 Skinner, R.I., Kelly, J.M. and Heine, A.J. (1975), "Hysteretic dampers for earthquake-resistant structures", Earthq. Eng. Struct. D., 3(3), 287-296.
17 Takewaki, I. (2009), Building control with passive dampers: -Optimal performance-based design for earthquakes-, John Wiley & Sons Ltd. (Asia).
18 Tani, T., Yoshitomi, S., Tsuji, M. and Takewaki, I. (2009), "High-performance control of wind-induced vibration of high-rise building via innovative high-hardness rubber damper", Struct. Des. Tall Spec., 18(7), 705-728.   DOI   ScienceOn
19 Tsuji, M., Fujuwara, Y., Murata, S., Kim, H.G., Yoshitomi, S. and Takewaki, I. (2010), "Post-tensioning damper system for micro-vibration reduction in residential houses: Analysis of effective deformation ratio by a simplified model", J. Struct. Eng.-AIJ, 56B (in Japanese).
20 Yamaguchi, H. and El-Abd, A.M. (2003), "Effect of earthquake energy input characteristics on hysteretic damper efficiency", Earthq. Eng. Struct. D., 32(6), 827-843.   DOI   ScienceOn