地震动和断层作用下埋地管道破坏的流固耦合分析
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摘要
在考虑流固耦合和地震荷载作用的情况下,应用ADINA(Automatic Dynamic Incremental Nonlinear Analysis)中流固耦合分析求解器ADINA-FSI,建立了地下管道破坏分析的有限元模型,介绍了建模和计算过程,地震荷载加载和断层活动约束的实现,以及模型参数选择等。依据计算结果,分析了管内介质及流速等参数对管道破坏的影响。管道内输送介质密度和流速越大,管道越易破坏,故在埋地管道设计中应充分考虑管内介质的密度与流速。针对计算结果,提出了几点认识和建议。
Finite element model of buried pipeline damage under fluid structure interaction (FSI) and earthquake loads is constructed through the application of ADINA-FSI. Modeling and model solution are introduced, earthquake loads and displacement loads of faults movement are applied, and parameters of the model are defined through model preferences. According to the calculated results, the influence of density and velocity of fluid on the damage of buried pipeline is analyzed. With the increase of density and velocity of the fluid in pipe, the damage to pipeline becomes worse. Therefore, density and velocity of the fluid in pipe should be generally considered when buried pipe is designed. Finally, some advice for the design and protection of buried pipeline is proposed.
Finite element model of buried pipeline damage under fluid structure interaction (FSI) and earthquake loads is constructed through the application of ADINA-FSI. Modeling and model solution are introduced, earthquake loads and displacement loads of faults movement are applied, and parameters of the model are defined through model preferences. According to the calculated results, the influence of density and velocity of fluid on the damage of buried pipeline is analyzed. With the increase of density and velocity of the fluid in pipe, the damage to pipeline becomes worse. Therefore, density and velocity of the fluid in pipe should be generally considered when buried pipe is designed. Finally, some advice for the design and protection of buried pipeline is proposed.
引文
冯振宇,赵凤群,1999.固-液耦合Timoshenko管道的稳定性分析.应用力学学报,16(3):47—52.
郭恩栋,余世舟,吴伟,2006.地下管道工程震害分析.地震工程与工程振动,26(3):180—183.
黄宏伟,胡昕,2003.顶管施工力学效应的数值模拟分析.岩石力学与工程学报,22(3):400—406.
李大勇,吕爱钟,曾庆军,2004.内撑式基坑工程周围地下管线的性状分析.岩石力学与工程学报,23(4):682—687.
王世忠,王茹,1992.三维管道固液耦合振动分析.哈尔滨工业大学学报,24(4):43—49.
王世忠,刘玉兰,黄文虎,1998.输送流体管道的固-液耦合动力学研究.应用数学和力学,19(11):987—993.
王世忠,于石声,赵阳,2002.流体输送管道的固-液耦合特性.哈尔滨工业大学学报,34(2):141—144.
魏纲,徐日庆,黄斌,2005.长距离顶管管道的失稳分析.岩石力学与工程学报,24(8):1427—1432.
余振翼,魏纲,2004.顶管施工对相邻平行地下管线位移影响因素分析.岩土力学,25(3):441—445.
张智勇,沈荣瀛,2000.充液直管管系中的固-液耦合振动响应分析.振动工程学报,13(3):455—461.
张智勇,沈荣瀛,王强,2001.充液管道系统的模态分析.固体力学学报,22(2):143—149.
朱庆杰,刘英利,蒋录珍等,2006.管土摩擦和管径对埋地管道破坏的影响.地震工程与工程振动,26(3):197—199.
Bathe K.J.and Hahn W.,1978.On Transient Analysis of Fluid-Structure Systems.J.Computers and Structures,10(2):383—391.
郭恩栋,余世舟,吴伟,2006.地下管道工程震害分析.地震工程与工程振动,26(3):180—183.
黄宏伟,胡昕,2003.顶管施工力学效应的数值模拟分析.岩石力学与工程学报,22(3):400—406.
李大勇,吕爱钟,曾庆军,2004.内撑式基坑工程周围地下管线的性状分析.岩石力学与工程学报,23(4):682—687.
王世忠,王茹,1992.三维管道固液耦合振动分析.哈尔滨工业大学学报,24(4):43—49.
王世忠,刘玉兰,黄文虎,1998.输送流体管道的固-液耦合动力学研究.应用数学和力学,19(11):987—993.
王世忠,于石声,赵阳,2002.流体输送管道的固-液耦合特性.哈尔滨工业大学学报,34(2):141—144.
魏纲,徐日庆,黄斌,2005.长距离顶管管道的失稳分析.岩石力学与工程学报,24(8):1427—1432.
余振翼,魏纲,2004.顶管施工对相邻平行地下管线位移影响因素分析.岩土力学,25(3):441—445.
张智勇,沈荣瀛,2000.充液直管管系中的固-液耦合振动响应分析.振动工程学报,13(3):455—461.
张智勇,沈荣瀛,王强,2001.充液管道系统的模态分析.固体力学学报,22(2):143—149.
朱庆杰,刘英利,蒋录珍等,2006.管土摩擦和管径对埋地管道破坏的影响.地震工程与工程振动,26(3):197—199.
Bathe K.J.and Hahn W.,1978.On Transient Analysis of Fluid-Structure Systems.J.Computers and Structures,10(2):383—391.
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