|本期目录/Table of Contents|

[1]范 重,崔俊伟,王金金,等.地铁上盖层间隔震结构竖向地震响应[J].建筑科学与工程学报,2021,38(01):11-22.[doi:10.19815/j.jace.2020.11053]
 FAN Zhong,CUI Jun-wei,WANG Jin-jin,et al.Vertical Seismic Response of Subway Inter-story Isolated Superstructures[J].Journal of Architecture and Civil Engineering,2021,38(01):11-22.[doi:10.19815/j.jace.2020.11053]
点击复制

地铁上盖层间隔震结构竖向地震响应(PDF)
分享到:

《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

卷:
38卷
期数:
2021年01期
页码:
11-22
栏目:
出版日期:
2021-01-20

文章信息/Info

Title:
Vertical Seismic Response of Subway Inter-story Isolated Superstructures
文章编号:
1673-2049(2021)01-0011-12
作者:
范 重1崔俊伟2王金金1杨 开1高 嵩1刘先明1高银鹰3
(1. 中国建筑设计研究院,北京 100044; 2. 中国中元国际工程有限公司,北京 100089; 3. 北京市轨道交通建设管理有限公司,北京 100068)
Author(s):
FAN Zhong1 CUI Jun-wei2 WANG Jin-jin1 YANG Kai1 GAO Song1 LIU Xian-ming1 GAO Yin-ying3
(1. China Architecture Design & Research Group, Beijing 100044, China; 2. China IPPR International Engineering Co., Ltd, Beijing 100089, China; 3. Beijing Metro Construction Administration Corporation Ltd., Beijing 100068, China)
关键词:
地铁上盖结构 竖向地震 隔震 动力特性 地震响应
Keywords:
subway superstructure vertical earthquake seismic isolation dynamic characteristic earthquake response
分类号:
TU352.1
DOI:
10.19815/j.jace.2020.11053
文献标志码:
A
摘要:
为了考察地铁上盖大底盘-层间隔震塔楼在竖向地震作用下的响应,对大底盘-层间隔震塔楼竖向振型的特点、周期和振型质量参与系数进行了分析。在设防烈度竖向地震作用下,通过振型分解反应谱法和时程分析法考察大底盘-层间隔震塔楼结构的基底剪力、隔震垫反力和转换梁内力,研究塔楼高度、隔震层竖向刚度等参数对大底盘-层间隔震塔楼竖向地震响应的影响。结果表明:大底盘-层间隔震塔楼结构存在塔楼竖向主振型,随着塔楼高度增高,竖向主振型的周期和振型质量参与系数逐渐加大; 在设防烈度竖向地震作用下,塔楼底部竖向地震力与重力荷载代表值之比(垂重比)的平均值为0.35,比非隔震塔楼平均增大4.6%; 隔震垫竖向地震反力与重力荷载代表值下反力之比(反力比)的平均值为0.30; 大底盘转换梁竖向地震下弯矩与重力荷载代表值下弯矩之比(弯矩比)的平均值为0.31; 随着塔楼高度增大,垂重比、隔震垫竖向反力比以及转换梁弯矩比均相应减小。
Abstract:
In order to investigate the response of subway large base-inter-story isolated tower under vertical earthquake, the characteristics of vertical vibration mode, period and mode mass participation coefficient of the large base-inter-story isolated tower were analyzed. Under the vertical seismic action of fortification intensity, the base shear force, vertical seismic force of the isolated supports and the internal force of transfer girders of the large base-inter-story isolated towers were investigated by mode decomposition response spectrum method and time-history analysis method. At the same time, the influence of tower height and vertical stiffness of isolation layer on vertical seismic response of the large base-inter-story isolated tower were studied. The results show that there is a vertical dominant vibration mode in the large base-inter-story isolated tower structure. With the increase of tower height, the period and the mode mass participation coefficient of vertical main vibration mode gradually increase. Under precautionary intensity vertical earthquakes, the average value of the vertical seismic force-weight ratio between vertical seismic force at the bottom of the tower and gravity load representative value is 0.35, and the average increase value is 4.6% compared to non-isolated tower. The average value of the isolated supports' vertical seismic reaction-weight ratio between the vertical seismic reaction and the reaction under the gravity load representative value is 0.30, and the average value of the transfer girders bending moment ratio between bending moment under vertical earthquake and bending moment under gravity load representative value is 0.31. With the increase of tower height, the vertical seismic force-weight ratio, the vertical seismic reaction-weight ratio of the isolated supports and the bending moment ratio of transfer girders decrease correspondingly.

参考文献/References:

[1] SKINNER R I,ROBINSON W H,MCVERRY G H.An Introduction to Seismic Isolation[M].Chichbester:John Wiley & Sons Ltd,1993.
[2]KATSUHIDE M,HARUYUKI K,HITOSHI O,et al.Design of a Building with Seismic Isolation System at the Mid-story[J].Journal of Architecture & Building Science,1999,5(7):51-56.
[3]KOH T,KOBAYASHI M.Vibratory Characteristics and Earthquake Response of Mid-story Isolated Buildings[J].Memoirs of the Institute of Sciences & Technology Meiji University,2000,39:97-113.
[4]谭 平,周福霖.大平台多塔楼结构的隔震减震控制[J].广州大学学报:自然科学版,2007,6(5):77-82.
TAN Ping,ZHOU Fu-lin.Seismic Isolation and Response Control of Multi-tower Structure on a Large Platform [J].Journal of Guangzhou University:Natural Science Edition,2007,6(5):77-82.
[5]吴曼林,谭 平,唐述桥,等.大底盘多塔楼结构的隔震减震策略研究[J].广州大学学报:自然科学版,2010,9(2):83-89.
WU Man-lin,TAN Ping,TANG Shu-qiao,et al.Seismic Isolation Strategies for Multi-tower Structures with a Large Podium[J].Journal of Guangzhou University:Natural Science Edition,2010,9(2):83-89.
[6]丁永君,赵明阳,李进军.地铁上盖开发的层间隔震结构设计[J].建筑结构,2015,45(16):77-81.
DING Yong-jun,ZHAO Ming-yang,LI Jin-jun.Design of Story Isolation Structure on the Subway Platform[J].Building Structure,2015,45(16):77-81.
[7]范 重,崔俊伟,薛浩淳,等.地铁上盖结构隔震效果研究[C]//陆新征.第29届全国结构工程学术会议论文集(第Ⅰ册).北京:《工程力学》杂志社,2020:99-116.
FAN Zhong,CUI Jun-wei,XUE Hao-chun,et al.Study on the Isolation Effect of Subway Cover Structures[C]//LU Xin-zheng.Proceedings of the 29th National Conference on Structural Engineering(No.I).Beijing:Engineering Mechanics Press,2020:99-116.
[8]CLOUGH R W,PENZIEN J.Dynamics of Structures[M].2nd ed.New York:McGraw-Hill,1995.
[9]PARISE M,JIBSON R W.A Seismic Landslide Susceptibility Rating of Geologic Units Based on Analysis of Characteristics of Landslides Triggered by the 17 January,1994 Northridge,California Earthquake [J].Engineering Geology,2000,58(3/4):251-270.
[10]曾德民.橡胶隔震支座的刚度特征与隔震建筑的性能试验研究[D].北京:中国建筑科学研究院,2007.
ZENG De-min.Test and Analysis on Performance of Rubber Bearing and Seismically Isolated Building[D].Beijing:China Academy of Building Research,2007.
[11]朱玉华,吕西林,施卫星,等.多向地面运动作用时铅芯橡胶隔震房屋模型振动台试验研究[J].结构工程师,2001(1):34-38.
ZHU Yu-hua,LU Xi-lin,SHI Wei-xing,et al.Study on Shaking Table Tests of Model Building with Lead Rubber Bearing Under Multi-direction Component Input[J].Structural Engineers,2001(1):34-38.
[12]胡晓莹,朱玉华.基础隔震结构竖向地震反应试验研究[J].结构工程师,2012,28(4):122-127.
HU Xiao-ying,ZHU Yu-hua.Vertical Seismic Responses of Base Isolated Buildings[J].Structural Engineers,2012,28(4):122-127.
[13]党 育,霍凯成.多层隔震结构的竖向地震作用研究[J].地震工程与工程振动,2010,30(4):139-145.
DANG Yu,HUO Kai-cheng.Vertical Earthquake Responses of Multi-story Isolated Buildings[J].Earthquake Engineering and Engineering Dynamics,2010,30(4):139-145.
[14]齐 杰,孙建琴.多向地震动输入对高层隔震结构抗震性能影响[J].工程抗震与加固改造,2019,41(2):43-49,66.
QI Jie,SUN Jian-qin.Influence of Multi-directional Ground Motion Input on Seismic Performance of High-rise Isolated Structures[J] Earthquake Resistant Engineering and Retrofitting,2019,41(2):43-49,66.
[15]许伟志,王曙光,刘伟庆,等.大跨隔震结构竖向地震响应的振动台试验研究[J].建筑结构学报,2020,41(4):19-31.
XU Wei-zhi,WANG Shu-guang,LIU Wei-qing,et al.Shanking Table Test on Vertical Seismic Responses of Isolated Large-span Structure[J].Journal of Building Structures,2020,41(4):19-31.
[16]陈晓城.竖向地震作用下基础隔震结构的动力响应分析[D].广州:华南理工大学,2011.
CHEN Xiao-cheng.Dynamic Responses Analysis of the Structure with Base-isolation System Under the Action of Vertical Earthquake[D].Guangzhou:South China University of Technology,2011.
[17]GB 50011—2010,建筑抗震设计规范[S].
GB 50011—2010,Code for Seismic Design of Buildings[S].
[18]李宏男,李忠献,祁 皑,等.结构振动与控制[M].北京:中国建筑工业出版社,2005.
LI Hong-nan,LI Zhong-xian,QI Ai,et al.Structure Vibration and Control[M].Beijing:China Architecture & Building Press,2005.
[19]北京金土木信息技术有限公司,中国建筑标准设计研究院.ETABS中文版使用指南[M].北京:中国建筑工业出版社,2004.
Beijing Civil King Information Technology Co.,Ltd,China Institution of Building Standard Design & Research.ETABS Operating Guide in Chinese Version[M].Beijing:China Architecture & Building Press,2004.
[20]龙驭球,包世华,袁 驷.结构力学[M].3版.北京:高等教育出版社,2015.
LONG Yu-qiu,BAO Shi-hua,YUAN Si.Structural Mechanics[M].3rd ed.Beijing:Higher Education Press,2015.

相似文献/References:

备注/Memo

备注/Memo:
收稿日期:2020-11-21
基金项目:国家重点研发计划项目(2017YFC0703600)
作者简介:范 重(1959-),男,北京市人,教授级高级工程师,工学博士,E-mail:fanz@cadg.cn。
更新日期/Last Update: 2021-01-20