黏滞阻尼器耗能减振工程应用设计方法研究
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摘要
本中文阐述了黏滞阻尼器的构造、力学模型以及其耗能减振的基本原理,并基于国际结构振动控制公共平台Benchmark模型,采用ANSYS和SAP2000有限元软件对其进行无控和有控地震反应分析,研究了黏滞阻尼器自身参数、设置形式、速度指、阻尼系数、位置和数量等因素对其控制效果的影响规律。结合国内外规范,给出LVD安装形式、各种参数、位置和数量的简化设计方法。利用本文提出的方法来进行LVD被动耗能减振分析和设计是方便可行的。新的抗震规范容许通过设置LVD耗能减振的方法适当降低主体结构的抗震构造措施,因此,今后阻尼器的应用是个必然的趋势。
This paper describes the conformation,the mechanical model and the passive energy dissipation basic principle of liquid viscous dampers.Benchmark common model is used as an analysis model,and the seismic response analysis with or without control is carried out using FEA with ANSYS and SAP2000.The influence of mass,stiffness and damping,configuration and brace,velocity exponent and damping coefficient,number and location of LVD are researched.The practical design method of LVD is summarized combining with present seismic code home and abroad.It is demonstrated from the simulation results that LVD can reduce the structure response effectively,and that aforementioned method is convenient and feasible.The new seismic design code is allowed to use passive energy dissipation method to reduce the seismic responses of main structure,and the application of LVD in structure is an inevitable trend in the future.
This paper describes the conformation,the mechanical model and the passive energy dissipation basic principle of liquid viscous dampers.Benchmark common model is used as an analysis model,and the seismic response analysis with or without control is carried out using FEA with ANSYS and SAP2000.The influence of mass,stiffness and damping,configuration and brace,velocity exponent and damping coefficient,number and location of LVD are researched.The practical design method of LVD is summarized combining with present seismic code home and abroad.It is demonstrated from the simulation results that LVD can reduce the structure response effectively,and that aforementioned method is convenient and feasible.The new seismic design code is allowed to use passive energy dissipation method to reduce the seismic responses of main structure,and the application of LVD in structure is an inevitable trend in the future.
引文
[1]欧进萍.结构振动控制:主动、半主动和智能控制[C]//北京:科学出版社,2003:490-510.
[2]陈政清,汪志昊.基于能量回收的土木工程结构振动控制[J].建筑科学与工程学报,2009,26(2):9-14.
[3]叶正强,李爱群,徐幼麟.工程结构粘滞流体阻尼器减振新技术及其应用[J].东南大学学报,2002,32(3):466-473.
[4]Constantinou MC,Symans MD.Experimental and analytical investigation of seismic response of structures with supplement fluid viscous dampers[R].NCEER Report-92-0032,State University of New York at Buffalo.
[5]GB50011-2010建筑抗震设计规范[S].北京:中国建筑工业出版社,2010.
[6]陈敏,邹银生,湛发益,等.基于顶点位移的被动消能结构加固设计[J].建筑科学与工程学报,2009,26(3):89-95.
[7]李波,梁兴文,熊二刚.附加改进肘型斜撑阻尼器体系结构的简化设计与分析[J].建筑科学与工程学报,2009,26(1):24-29.
[8]王立伟.黏滞阻尼器建筑结构应用实用设计方法的研究[D].哈尔滨:哈尔滨工业大学,2005,6:56-64.
[9]田石柱,王立伟,王大鹏.基于ANSYS软件benchmark模型耗能减振控制分析[J].地震工程与工程振动,2006,26(6):184-189.
[2]陈政清,汪志昊.基于能量回收的土木工程结构振动控制[J].建筑科学与工程学报,2009,26(2):9-14.
[3]叶正强,李爱群,徐幼麟.工程结构粘滞流体阻尼器减振新技术及其应用[J].东南大学学报,2002,32(3):466-473.
[4]Constantinou MC,Symans MD.Experimental and analytical investigation of seismic response of structures with supplement fluid viscous dampers[R].NCEER Report-92-0032,State University of New York at Buffalo.
[5]GB50011-2010建筑抗震设计规范[S].北京:中国建筑工业出版社,2010.
[6]陈敏,邹银生,湛发益,等.基于顶点位移的被动消能结构加固设计[J].建筑科学与工程学报,2009,26(3):89-95.
[7]李波,梁兴文,熊二刚.附加改进肘型斜撑阻尼器体系结构的简化设计与分析[J].建筑科学与工程学报,2009,26(1):24-29.
[8]王立伟.黏滞阻尼器建筑结构应用实用设计方法的研究[D].哈尔滨:哈尔滨工业大学,2005,6:56-64.
[9]田石柱,王立伟,王大鹏.基于ANSYS软件benchmark模型耗能减振控制分析[J].地震工程与工程振动,2006,26(6):184-189.
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