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Seismic performance of isolation system of rolling friction with springs

Seismic performance of isolation system of rolling friction with springs
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摘要 In order to study an isolation system of rolling friction with springs, computer programs were compiled to evaluate the seismic performance based on its movement characteristics. Through the programs, the influences of various seismic performance factors, e.g., rolling friction coefficient, spring constant, were systematically investigated. Results show that by increasing the rolling friction coefficient, the structural relative displacement due to seismic load effectively decreases, while the structural response magnitude varies mainly depending on the correlations between the following factors: the spring constant, the earthquake intensity, and the rolling friction coefficient. Furthermore, increasing the spring constant can decrease the structural relative displacement, as well as residual displacement, however, it increases the structural response magnitude. Finally, based on the analyses of various seismic performance factors subjected to the scenario earthquakes, optimized theoretical seismic performance can be achieved by reasonably combining the spring constant and the rolling friction coefficient. In order to study an isolation system of rolling friction with springs, computer programs were compiled to evaluate the seismic performance based on its movement characteristics. Through the programs, the influences of various seismic performance factors, e.g., rolling friction coefficient, spring constant, were systematically investigated. Results show that by increasing the rolling friction coefficient, the structural relative displacement due to seismic load effectively decreases, while the structural response magnitude varies mainly depending on the correlations between the following factors: the spring constant, the earthquake intensity, and the rolling friction coefficient. Furthermore, increasing the spring constant can decrease the structural relative displacement, as well as residual displacement, however, it increases the structural response magnitude. Finally, based on the analyses of various seismic performance factors subjected to the scenario earthquakes, optimized theoretical seismic performance can be achieved by reasonably combining the spring constant and the rolling friction coefficient.
作者 魏标 戴公连 文颖 夏烨
机构地区 School of Civil Engineering Department of Civil and Environment Engineering
出处 《Journal of Central South University》 SCIE EI CAS 2014年第4期1518-1525,共8页 中南大学学报(英文版)
基金 Project(51308549)supported by the National Natural Science Foundation,China
关键词 滚动摩擦系数 抗震性能 弹簧 隔震体系 结构响应 相对位移 地震载荷 计算机程序 structure seismic isolation rolling friction spring
分类号 O313.5 [理学—一般力学与力学基础]
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  • 1史红福,樊剑,李黎.滚动基础隔震机构的动力分析[J].振动与冲击,2005,24(6):91-94. 被引量:5
  • 2S. Fujita, Y. Morikawa, I. Shimoda, S. Nagata and H. Shimosaka, Isolation system for equipment using friction pendulum bearings (lst report, Shaking tests and response analysis on isolated equipment), Trans. Jpn. Soc Mech. Eng. (Series C) 59 557 (1993)11-16 (in Japanese with English abstract).
  • 3S. Ueda, M. Akimoto, T. Enomoto and T. Fujita, Study of roller type seismic isolation device for works of art, Trans. Jpn. Soc. Mech. Eng. (Series C) 71 (703) (2005) 807-812 (in Japanese with English abstract).
  • 4S. Fujita, H. Yamamoto, N. Kitagawa and H. Kurabayashi, Research and development of the friction pendulum isolation device with poly-curvature: Investigation of Isolation performance on shake test and response analysis using vending machine model), Trans. Jpn. Soc. Mech. Eng. (Series C) 69 (684) (2003) 1990-1996 (in Japanese with English abstract).
  • 5S. Aoki, T. Otaka, Y. Nakanishi, T. Nishimura, M. Inagaki and M. Kanazawa, Reduction method of seismic response with friction bearing, in: Proceedings of the Japan Society of Mechanical Engineers (Kanto), No. 060-1,485-486, 2006 (in Japanese with English abstract).
  • 6Priestley M J N, Seible F,Calvi E M. Seismic design and retrofit of bridges [M]. New York: John Wiley Sons, 1996.
  • 7Fan F G, Ahmadi G, Mostaghel N, et al. Performance analysis of aseismic base isolation systems for a multi- story building [J]. Soil Dynamics and Earthquake Engineering, 1991,10 (3) : 152-171.
  • 8Ou Y C, Song J W, Lee G C. A parametric study of seismic behavior of roller seismic isolation bearings for highway bridges [J]. Earthquake Engineering and Structure Dynamics, 2010,39: 541-559.
  • 9Lee G C,Ou Y C,Niu T C,et al. Characterization of a roller seismic isolation bearing with supplemental energy dissipation for highway bridges [J]. Journal of Structural Engineering, 2010,136(5) : 502-510.
  • 10Jangid R S, Londhe Y B. Effectiveness of elliptical rolling rods for base isolation [J]. Journal of Structural Engineering, 1998,124(4) : 469-472.

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Journal of Central South University
2014年 第4期

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