基于Benchmark模型的抑制屈曲支撑耗能减振作用分析
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摘要
抑制屈曲支撑可在拉压循环荷载作用下均达到屈服,拉压承载力基本一致,滞回曲线稳定饱满,耗能能力强。基于Benchmark模型对安装抑制屈曲支撑的钢框架结构基于ANSYS的数值分析表明,抑制屈曲支撑不仅可使结构在小震时的抗侧刚度有所提高,同时在大震时通过其往复滞回变形发挥耗能减振作用,大大地降低了结构的地震响应,提高了结构的抗震性能。同时分析表明考虑高阶振型影响的能力谱分析方法是一种更为精确的分析方法。
BRBs are confirmed to have nearly the same yielding stress and ultimate strength under tension and compression.The BRBs can undergo fully-reversed axial yield cycles without loss of stiffness and strength,whose seismic energy dissipation ability is superior.Based on the numerical analysis of Benchmark building in ANSYS,when the steel frame is installed with BRBs,the stiffness of the steel frame will be improved under frequent earthquake.Under rare earthquake,the energy dissipation is completed by the hysteretic deformation of BRBs,the seismic responses of the structures will be greatly reduced and the seismic performance will be improved.When the higher vibration modes are considered,the capacity spectrum analysis method will be improved.
BRBs are confirmed to have nearly the same yielding stress and ultimate strength under tension and compression.The BRBs can undergo fully-reversed axial yield cycles without loss of stiffness and strength,whose seismic energy dissipation ability is superior.Based on the numerical analysis of Benchmark building in ANSYS,when the steel frame is installed with BRBs,the stiffness of the steel frame will be improved under frequent earthquake.Under rare earthquake,the energy dissipation is completed by the hysteretic deformation of BRBs,the seismic responses of the structures will be greatly reduced and the seismic performance will be improved.When the higher vibration modes are considered,the capacity spectrum analysis method will be improved.
引文
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[2]Xie Q.State of the art of buckling-restrained braces in Asia[J].Journal of Constructional Steel Research,2005,61(6):727?748.
[3]Black C J,Makris N N,Aiken I D.Component testing,seismic evaluation and characterization of buckling-restrained braces[J].Journal ofStructural Engineering,ASCE,2004,130(6):880-894.
[4]陈正诚.钢侧撑韧性斜撑构材之行为与应用(Ⅰ)[J].建筑钢结构进展,2005,7(5):26-32.
[5]陈正诚.钢侧撑韧性斜撑构材之行为与应用(Ⅱ)[J].建筑钢结构进展,2005,7(6):29-37.
[6]谢强,赵亮.屈曲约束支撑的研究进展及其在结构抗震加固中的应用[J].地震工程与工程振动,2006,26(3):100-103.
[7]Sabelli R,Mahin S,Chang C.Seismic demands on steel braced frame buildings with buckling-restrained Braces[J].Engineering Structures,2003,25(5):655-666.
[8]Fahnestock LA,Richard S,Ricles J M.Seismic response and performance of buckling-restrained braced frames[J].Journal of Structural Engi-neering,2007,133(9):1195-1204.
[9]Fahnestock LA,Ricles J M,Sause R.Experimental evaluation of a Large-scale buckling-restrained braced frame[J].Journal of Structural Engi-neering,2007,133(9):1205-1214.
[10]Tremblay R,Boulduc P,Neville R,et al.Seismic testing and performance of buckling-restrained bracing systems[J].Canadian Journal of CivilEngineering,2006,33(2):183-198.
[11]欧进萍.结构振动控制:主动、半主动和智能控制[M].北京:科学出版社,2003:490-510.
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