长周期结构相对位移反应谱研究
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摘要
在对长周期结构进行抗震设计时,或采用基于位移的性能设计方法进行结构设计时,或采用各种结构控制技术对结构进行减隔震设计时,需要用到相对位移反应谱,而目前各国规范给出的一般都是某种标准化的绝对加速度反应谱。本文指出了国内外目前在用的部分规范提出的长周期反应谱存在的问题,采用80条高通低截止频率(0.025 Hz~0.125 Hz)、加速度峰值≥0.10 g的水平向强震记录,计算了周期0~10 s、阻尼比0.10~0.40的相对位移反应谱,研究了位移谱的影响因素及控制参数,建立了考虑震源参数、地震动幅值特性、场地条件、谱控制参数、阻尼比调整系数的可供长周期结构设计使用的弹性相对位移谱,给出了实用化计算公式及地震动位移峰值。结果表明,相对位移谱卓越周期是控制位移谱谱值及形状的重要参数;本文研究得到的相对位移谱能较好地拟合实际相对位移谱。
Relative displacement response spectrum is not only essential in seismic design of a long-period structure but also in displacement-based seismic design and in structural control design.However,the spectrum specified by seismic codes is a normalized absolute acceleration spectrum.Problems existing in long-period range of relative displacement spectrum in codes were pointed out here.By selecting 80 high-pass filtered digital horizontal strong motion records(PGA(peak ground acceleration)≥0.10 g) with lower cut off frequency(0.025 Hz ~0.125 Hz),relative displacement spectrum was constructed with period range(0~10.0 s) and damping ratio range(0.10~0.40).Furthermore,spectral influence factors and control parameters were calculated and illustrated.Taking influence of hypocenter parameters,ground motion amplitude,site conditions,spectral control parameters and damping ratio adjustment factors on relative displacement spectrum into account,elastic relative displacement spectrum and relevant practical calculation formula for a long-period structure were proposed.Moreover,value of PGD(peak ground displacement) was given based on statistical analysis.The results revealed that predominant period is one of significant parameters controlling the value and shape of the relative displacement spectrum,and the relative displacement spectrum established here is capable of fitting real displacement spectrum.
Relative displacement response spectrum is not only essential in seismic design of a long-period structure but also in displacement-based seismic design and in structural control design.However,the spectrum specified by seismic codes is a normalized absolute acceleration spectrum.Problems existing in long-period range of relative displacement spectrum in codes were pointed out here.By selecting 80 high-pass filtered digital horizontal strong motion records(PGA(peak ground acceleration)≥0.10 g) with lower cut off frequency(0.025 Hz ~0.125 Hz),relative displacement spectrum was constructed with period range(0~10.0 s) and damping ratio range(0.10~0.40).Furthermore,spectral influence factors and control parameters were calculated and illustrated.Taking influence of hypocenter parameters,ground motion amplitude,site conditions,spectral control parameters and damping ratio adjustment factors on relative displacement spectrum into account,elastic relative displacement spectrum and relevant practical calculation formula for a long-period structure were proposed.Moreover,value of PGD(peak ground displacement) was given based on statistical analysis.The results revealed that predominant period is one of significant parameters controlling the value and shape of the relative displacement spectrum,and the relative displacement spectrum established here is capable of fitting real displacement spectrum.
引文
[1]钱稼茹,罗文斌.静力弹塑性分析:基于性能/位移抗震设计的分析工具[J].建筑结构,2000,30(6):23-26.
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[3]王亚勇.关于设计反应谱、时程法和能量方法的探讨[J].建筑结构学报,2000,21(1):21-28.
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[10]翁大根,徐植信.对上海市抗震设计反应谱及时程曲线的认识[J].地震工程与工程振动,2001,21(1):79-83.
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[12]王君杰,范立础.规范反应谱长周期部分修正方法的探讨[J].土木工程学报,1998,31(6):49-55.
[13]Faccioli E,Roberto P,Julien R.Displacement spectra forlong periods[J].Earthquake Spectra,2004,20(2):347-376.
[14]Tolis S,Faccioli E.Displacement design spectra[J].Journal of Earthquake Engineering,1999(3):107-125.
[15]周雍年,周正华,于海英.设计反应谱长周期区段的研究[J].地震工程与工程振动,2004,24(2):15-18.
[16]GB50011-2001建筑抗震设计规范[S].北京:中国建筑工业出版社,2001.
[17]上海市工程建设规范:建筑抗震设计规程(DGJ08-9-2003)[S].北京:中国建筑工业出版社,2003.
[18]European Committee for Standardization.Eurocode 8:Designof structures for earthquake resistance(EN 1998-1:2004).
[19]王广军.建筑抗震设计规范手册(中册)[M].北京:中国建筑科学研究院,1990:295-299.
[20]曹加良.高层隔震结构基于反应谱理论的地震响应预测研究[D].广州:广州大学土木工程学院,2009:17-69.
[21]周锡元,齐微,徐平,等.震级、震中距和场地条件对反应谱特性影响的统计分析[J].北京工业大学学报,2006,32(2):97-103.
[2]王亚勇.我国2000年抗震设计模式规范基本问题研究综述[J].建筑结构学报,1999,21(1):2-4.
[3]王亚勇.关于设计反应谱、时程法和能量方法的探讨[J].建筑结构学报,2000,21(1):21-28.
[4]李琪.基于位移模式结构抗震设计方法研究[D].南京:河海大学土木工程学院,2005.
[5]Chopra AK.Dynamics of Structures:Theory and applicationsto earthquake engineering[M].New Jersey:Prentice-HallInc,2004.
[6]曹加良,刘文光,何文福.基础隔震结构反应谱拟谱与真谱差异研究[J].世界地震工程,2009,25(2):76-80.
[7]谢礼立,周雍年,胡成祥,等.地震动反应谱的长周期特性[J].地震工程与工程振动,1990,10(1):1-20.
[8]翁大根,徐植信.上海地区抗震设计谱研究[J].同济大学学报,1993,21(1):9-16.
[9]俞言祥,胡聿贤.关于上海市《建筑抗震设计规程》中长周期设计反应谱的讨论[J].地震工程与工程振动,2000,20(1):27-20.
[10]翁大根,徐植信.对上海市抗震设计反应谱及时程曲线的认识[J].地震工程与工程振动,2001,21(1):79-83.
[11]施卫星,李正升,汪大绥.基础隔震位移反应谱及其应用[J].同济大学学报,2000,28(1):29-32.
[12]王君杰,范立础.规范反应谱长周期部分修正方法的探讨[J].土木工程学报,1998,31(6):49-55.
[13]Faccioli E,Roberto P,Julien R.Displacement spectra forlong periods[J].Earthquake Spectra,2004,20(2):347-376.
[14]Tolis S,Faccioli E.Displacement design spectra[J].Journal of Earthquake Engineering,1999(3):107-125.
[15]周雍年,周正华,于海英.设计反应谱长周期区段的研究[J].地震工程与工程振动,2004,24(2):15-18.
[16]GB50011-2001建筑抗震设计规范[S].北京:中国建筑工业出版社,2001.
[17]上海市工程建设规范:建筑抗震设计规程(DGJ08-9-2003)[S].北京:中国建筑工业出版社,2003.
[18]European Committee for Standardization.Eurocode 8:Designof structures for earthquake resistance(EN 1998-1:2004).
[19]王广军.建筑抗震设计规范手册(中册)[M].北京:中国建筑科学研究院,1990:295-299.
[20]曹加良.高层隔震结构基于反应谱理论的地震响应预测研究[D].广州:广州大学土木工程学院,2009:17-69.
[21]周锡元,齐微,徐平,等.震级、震中距和场地条件对反应谱特性影响的统计分析[J].北京工业大学学报,2006,32(2):97-103.
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