通信铁塔动力效应分析
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摘要
为研究通信铁塔在风载荷与地震影响下的结构振动及其稳定,使用ANSYS有限元分析软件对通信铁塔的风荷载受力情况、地震反应和模态进行动力效应分析。结果表明:在正常大风工况下,铁塔基础作用力最大,铁塔的基础作用力是由风速大小控制的。随着通信铁塔高度的增加,结构的自振频率减小,结构刚度减小;通信铁塔的结构刚度较大,其基本周期均在5附近。铁塔的地震响应基础作用力均为上拔力,上拔力比在大风荷载下增加了15%。通过实测值与有限元模拟值进行比较,两者之间误差在可控范围内。
In order to study the vibration of communication towers under the influence of winds and earthquakes,ANSYS was used for dynamic effect analysis about wind load,earthquake response and modality of the towers.The results indicated that the foundation force of the towers reaches maximum in strong winds and is controlled by the wind velocity.With the increase of tower height,structural vibration frequency and stiffness decrease.The structural rigidity of towers is comparatively large,and the cycle is about 5 seconds.The foundation force of the towers induced by seismic response is uplift,which is 15% higher than that induced by strong wind.The calculated results given by the finite element simulation conform to the measured value in site.
In order to study the vibration of communication towers under the influence of winds and earthquakes,ANSYS was used for dynamic effect analysis about wind load,earthquake response and modality of the towers.The results indicated that the foundation force of the towers reaches maximum in strong winds and is controlled by the wind velocity.With the increase of tower height,structural vibration frequency and stiffness decrease.The structural rigidity of towers is comparatively large,and the cycle is about 5 seconds.The foundation force of the towers induced by seismic response is uplift,which is 15% higher than that induced by strong wind.The calculated results given by the finite element simulation conform to the measured value in site.
引文
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[12]邓志恒,潘峰,潘志明.刚连梁控制结构地震反应弹塑性动力时程分析[J].广西大学学报:自然科学版,2007,32(2):163-166.
[2]DAVENPORTA G.The spectrum of horizontal gustiness near groud in high winds[J].Royal Meteoral Soc,1961,87:194-211.
[3]徐旭,屈应辉,刘玉.两类建筑结构脉动风场的数值模拟[J].上海大学学报:自然科学版,2009,15(2):191-198.
[4]梁清香,戴保东,卢建军.地震对传输塔影响的研究[J].太原理工大学学报,2005,36(6):648-650.
[5]胡晓依.桅杆结构的风振可靠性及优化设计分析[D].上海:同济大学土木工程学院,2001.
[6]何水清,王善.结构可靠性分析与设计[M].北京:国防工业出版社,1993.
[7]林文泉,朱尔玉.不同斜撑方式对格构式异形铁塔的影响[J].北京交通大学学报,2005,29(4):54-56.
[8]张相庭.工程结构风荷载理论和抗风计算手册[M].上海:同济大学出版社,1990.
[9]蔡铭.高耸异型铁塔风荷载作用下结构的分析计算[J].钢结构,2005,20(81):32-34.
[10]李承铭,王国俭.复杂高层结构抗震性能分析[J].太原理工大学学报,2006,37(3):75-77.
[11]崔春义.三维复杂高层建筑抗震性能动力时程分析[J].广西大学学报:自然科学版,2009,34(3):305-309.
[12]邓志恒,潘峰,潘志明.刚连梁控制结构地震反应弹塑性动力时程分析[J].广西大学学报:自然科学版,2007,32(2):163-166.
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