大型渡槽结构考虑流固耦合的动力建模研究
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摘要
该文依据符拉索夫(Volasov)和豪斯纳尔(Housner)理论建立考虑槽内水体与槽身动力相互作用以及槽身剪力滞后影响的渡槽薄壁结构横向动力分析模型,由能量变分原理推导出渡槽薄壁梁段单元刚度矩阵及质量矩阵表达式,通过数值算例验证了该模型的正确性;利用该模型对某大型渡槽进行了多种工况的频率计算,结果表明:大型渡槽在无水和设计水位时的振动频率有所变化;该文模型是考虑渡槽槽内水体横向流固动力相互作用的实用动力分析模型。
Based on the theory of Volasov and Housner,the shell-bar aqueduct dynamical analysis modal with fluid-structure coupling and shear lag is established.The element stiffness and the mass matrix of the aqueduct are derived by an energy principle.The analytical solution formulas are deduced in the cases of no water and the design water level in aqueduct.By using the modal the frequencies in several cases are calculated and compared.The result shows that the frequencies are changed in the two cases.The modal in this paper is simple and practical for dynamic analysis of the fluid-structure coupling aqueduct.
Based on the theory of Volasov and Housner,the shell-bar aqueduct dynamical analysis modal with fluid-structure coupling and shear lag is established.The element stiffness and the mass matrix of the aqueduct are derived by an energy principle.The analytical solution formulas are deduced in the cases of no water and the design water level in aqueduct.By using the modal the frequencies in several cases are calculated and compared.The result shows that the frequencies are changed in the two cases.The modal in this paper is simple and practical for dynamic analysis of the fluid-structure coupling aqueduct.
引文
[1]Li Yuchun,Lou Menglin.Evaluation of vertical seismic re-sponse for a large-scale beam-supported aqueduct[J].Earth-quake Engineering and Structural Dynamics,2003,32:1-14.
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[2]Chen W,haroun M A,Liu F.Large amplitude liquid slosh-ing in seismically excited tanks[J].Earthquake Engineeringand Structural Dynamics,1996,25:653-669.
[3]李遇春,楼梦麟.渡槽中流体非线性晃动的边界元模拟[J].地震工程与工程振动,2000,20(2):51-56.
[4]OKAMOTO T,Kawahara M.Two-dimensional sloshing anal-ysis by Lagrangian finite element method[J].Int.J.Numer.Methods Fluids,1990,11:453-478.
[5]居荣初,曾心传.弹性结构与液体的耦联振动理论[M].北京:地震出版社,1983:115-154.
[6]徐建国.大型渡槽结构抗震分析方法及其应用[D].大连:大连理工大学土木水利学院,2005.21-30.
[7]韦成龙,曾庆元.薄壁曲线箱梁考虑翘曲、畸变和剪滞效应的空间分析[J].土木工程学报,2000,33(6):81-86.
[8]倪元增,钱寅泉.弹性薄壁梁桥分析[M].北京:人民交通出版社,2000:77-89.
[9]李遇春.大型高墩渡槽的横向动力特性分析[J].武汉水利电力大学学报,1998(4):56-63.
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