基础隔震高层建筑结构减震系数研究

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振动与冲击 ›› 2021, Vol. 40 ›› Issue (22) : 35-41.

论文

基础隔震高层建筑结构减震系数研究

赖正聪1,2，潘文1,2，白羽1,2，叶燎原2，张田庆3，贾毅1

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Seismic reduction coefficient of base-isolated high-rising building structures

LAI Zhengcong1,2，PAN Wen1,2，BAI Yu1,2，YE Liaoyuan2，ZHANG Tianqing3，JIA Yi1

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摘要

针对质量、刚度沿高度分布相对均匀的基础隔震高层建筑结构建立其等效梁模型，基于振型分解反应谱法对隔震及非隔震结构振型数、振型参与质量、地震剪力、力矩等关键指标进行探讨分析。给出了确定水平向减震系数指标的临界刚度比、临界周期比，进一步分析了该两个临界比值对减震系数的一般性控制规律。研究结论表明：1）当隔震后、前结构基本周期比大于1.3或上部结构整体等效刚度与隔震层水平等效刚度之比大于0.8时，可有效抑制高层剪力墙隔震结构高阶振型反应，仅需考虑基本振型对结构地震反应的贡献。2）结构隔震后、前的底部剪力比、力矩比与上部结构整体等效刚度与隔震层水平等效刚度之比、基本周期比有关，与质量、阻尼等参数无关。3）当小于临界刚度比或小于临界周期比时，底部力矩减震效果较剪力要差，应以隔震后、前结构底部力矩比作为减震效能评价指标，当大于临界刚度比或大于临界刚度比时，则应以底部剪力比作为评价指标。其中，、可按本文所给数值取用。所得相关研究成果可为相关理论研究及工程应用提供参考和依据。

Abstract

The equivalent beam model was established for the base-isolated high-rising building structure with relatively uniform mass and stiffness distribution along the height. Based on the method of vibration mode decomposition response spectrum, the key indexes of vibration mode number, vibration mode participation quality, seismic shear force and moment of the isolated and non-isolated structures were discussed and analyzed. The critical stiffness ratio and critical period ratio of the horizontal seismic reduction coefficient are given, and the general control law of the two critical ratios to the seismic reduction coefficient is further analyzed. The study concluded that: 1) When the basic period ratio >1.3 or equivalent stiffness ratio >0.8, the high-order vibration mode response of the isolation structure can be effectively suppressed, and the influence of the basic mode on the seismic response of the structure can only be considered. 2) The base shear ratio and moment ratio of the structure after and before being isolated are related to the ratio of the overall equivalent stiffness of the superstructure to the horizontal equivalent stiffness of the isolation layer as well with the basic period ratio, and have nothing to do with the parameters such as mass and damping. 3) When < or < , the base moment reduction effect is worse than the shear force, so the bottom moment ratio should be the control index; otherwise, the base shear force ratio should be the control index when > or > . The values of and can be determined in accordance with the data given in this paper. The related research results can provide reference and basis for related further theoretical research and engineering application.

导出引用

赖正聪1,2，潘文1,2，白羽1,2，叶燎原2，张田庆3，贾毅1. 基础隔震高层建筑结构减震系数研究[J]. 振动与冲击, 2021, 40(22): 35-41

LAI Zhengcong1,2，PAN Wen1,2，BAI Yu1,2，YE Liaoyuan2，ZHANG Tianqing3，JIA Yi1. Seismic reduction coefficient of base-isolated high-rising building structures[J]. Journal of Vibration and Shock, 2021, 40(22): 35-41

参考文献

[1] 何文福,刘文光,张颖等.高层隔震结构地震反应振动台试验分析[J]. 振动与冲击,2008,27（8）：97-101.
(HE Wenfu, LIU Wenguang, ZHANG Ying. Experimental study on high rise isolated structure[J].Journal of Vibration and Shock,2008,27（8）：97-101. ( in Chinese))
[2] 赖正聪,潘文,白羽等.基础隔震在高烈度区大高宽比剪力墙结构中的应用与试验研究[J].建筑结构学报,2017,38(9): 62-73.
(LAI Zhengcong, PAN Wen, BAI Yu. Application and experimental investigation on base-isolated shear-wall structure with large height-width ratio in high seismic intensity regions [J].Journal of Building Structures, 2017,38 (9): 62-73. ( in Chinese))
[3] ZHOU Fulin, TAN Ping, XIAN Qiaoling, HUANG Xiangyun, YANG Zheng. Research and Application of Seismic Isolation System for Building Structures[J]. Journal of Architecture and Civil Engineering, 2006,23(2):1-8.
[4] GB 50011-2010建筑抗震设计规范[S].北京:中国建筑工业
出版社，2010.
(GB 50011-2010 Code for seismic design of buildings[S]. Beijing: China Architecture & Building Press,2010. (in Chinese) )
[5] 郭佩佩. 隔震结构水平向减震系数取值方法与支墩设计技术研究[D].山东大学,2013:36-78.
(GUO Peipei. Study on the method of determining the horizontal damping coefficient of isolated structures and the technique of pier design [D]. Shandong University, 2013:36-78. ( in Chinese))
[6] 祁皑,林于东.改进的基础隔震结构地震作用简化计算方法[J].地震工程与工程振动, 2006(01):152-157.
(QI Ai, LIN Yudong. An improved simplified method for seismic action design of base-isolation buildings [J]. Earthquake Engineering and Engineering Vibration, 2006 (01):152-157. ( in Chinese))
[7] Sarun Chimamphant, Kazuhiko Kasai. Comparative response and performance of base‐isolated and fixed‐base structures[J].Earthquake Engineering & Structural Dynamics，2016, 45(1):5-27.
[8] 魏泽. 隔震设计减震系数法与直接设计法的对比分析研究[D].广州大学,2019.
(WEI Ze. Comparative analysis on Isolated Design of Damping Coefficient method and Direct design method [D]. GuangZhou Uni. , 2019. (in Chinese))
[9] 赖正聪,潘文,白羽,叶燎原.翻转动能对基础隔震剪力墙结构高宽比限值的影响分析[J].振动与冲击,2019,38(5):146-154.
(LAI Zhengcong，PAN Wen，BAI Yu，YE Liaoyuan. Analysis on the Influence of Swinging Vibration Energy to Height-width Limit Ratio of Base-isolated Shear-wall Structure[J]. Journal of Vibration and Shock, 2019,38(5):146-154. (in Chinese))
[10] 包世华.新编高层建筑结构[M].北京,中国水利水电出版社,2001.
(BAO Shihua. High-rised Building Structure[M].Beijing, China Water Power Press Press,2001. ( in Chinese))
[11] Anil K. Chopra. Dynamics of Structures: Theory and Applications to Earthquake Engineering [M]. Englewood Cliffs, NJ, Pearson Education: 2001:476-495.
[12] 刘延柱,陈文良,陈立群.振动力学[M].北京,高等教育出版社，2005.
(LIU Yanzhu, CHEN Wenliang, CHEN Liqun. Mechanics of Vibration[M]. Beijing, Higher Education Press, 2005. (in Chinese))
[13] Dionysius M. Siringoringo, Yozo Fujino. Seismic response analyses of an asymmetric base‐isolated building during the 2011 Great East Japan (Tohoku) Earthquake. 2015, 22(1):71- 90.
[14] 商昊江,祁皑.高层隔震结构减震机理探讨[J].振动与冲击 ,2012,31(4):17-24.
(SHANG Haojiang , QI Ai. Isolation mechanism of high-rise isolation structure[J].Journal of Vibration and Shock, 2012,31(4): 17-24. ( in Chinese))
[15] 王学庆,赵明.高层剪力墙隔震结构动力特性简化计算方法[J]. 振动与冲击,2016,35（15）：127-133.
(WANG Xueqing, ZHAO Ming. A simplified calculation method for dynamic characteristics of high-rise shear-wall isolated buildings[J].Journal of Vibration and Shock, 2016,35（15）：127-133. ( in Chinese)