大坝—库水—地基系统动力耦合作用数值研究
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摘要
我国水能资源居世界之首,但分布不均,约80%集中在西部,主要是西南地区。但该区处于新构造运动强烈、地质环境极不稳定的高山峡谷区,为强烈地震和地质灾害高发区。目前在建和拟建一系列200米至300米级的高坝,如小湾、构皮滩、溪洛渡、白鹤滩、锦屏、糯扎渡、拉西瓦、乌东德、大岗山等战略性工程,都在这一地区,其规模巨大、地震烈度高。在这一地震高烈度区,抗震安全多为工程建设中的关键。5.12汶川大地震让人们更加清晰的认识到了这一点。
首先介绍了结构静力动力分析理论、流固耦合问题的有限元计算方法,从流固耦合的角度出发,对坝库相互作用的机理进行了研究,利用FORTRAN语言,编制了坝体-库水-地基耦合系统的有限元程序。
对某重力坝某坝段和某拱坝拱冠梁进行了计算,分析了有质量地基模型和无质量地基模型,探讨了现行规范中附加质量模型和考虑坝库相互作用的流固耦合模型,可以看出流固耦合模型与附加质量模型相比结构大部分部位的结果较小,但更能反映库水-坝体相互作用的实际情况。
利用大型有限元ADINA软件,基于ADINA软件建立坝库系统流固耦合模型,分别进行了模态分析、地震时程响应分析。以某拱坝为例,研究了库水位和库水压缩性对拱坝模态和自振频率等的影响。作为工程应用,以某拱坝工程为例,建立拱坝-库水-地基系统相互作用的动力耦合模型,对其进行了动力特性和地震响应的计算分析,得出了一些可供工程设计参考的有价值成果。
Hydropower resources in China ranks first in the world, but their distribution is uneven, about 80% concentrated in the west, mainly southwest. This area is a new strong tectonic movement and highly volatile geological environment mountain valley areas, which has a high incidence of strong earthquakes and geological hazards. At present, under construction and proposed a series of 200-300 m level high dams, such as Xiaowan, Goupitan, Xiluodu, Baihetan,Jingpin,Nuozhadu, Laxiwa, Wudongde, Dagangshan and so on.strategical project are all in these high earthquake intensity areas. Seismic safety is the key point in these high earthquake intensity areas, shocking earthquake which happened in Sichuan province China on May 12th in 2008 make people more clearly recognized this.
This paper describes dynamic analysis theory of structure, fluid-solid coupling problem of the finite element method. From the point of view of fluid-solid coupling, deep research has been made on the principle of the dam and reservoir interaction. Through using FORTRAN language, developed a finite element program of dam-water-foundation system interaction.
Calculate a gravity dam and an arch crown beam by the FORTRAN programme, Qualitatively analyze the quality foundation model and the massless foundation model, discuss the additional mass model of current specification and the fluid-solid coupling model basing on interaction theory, Compared to the additional mass model, we can see that the fluid-solid coupling mode has smaller results at most parts, which better reflects the actual dam-water interaction.
By using large-scale finite element software ADINA, establish dam-water system's fluid-solid coupling model, conducted modal analysis, seismic time-history response analysis, and then give an arch dam example, and study the arch dam's mode and self-vibration which is affected by the water level and the reservoir water compression. As an engineering application, establish dam-water-foundation system's fluid-solid coupling model through a arch dam, calculate the dynamic characteristics and seismic response of the arch dam, and obtained some valuable results for the engineering design.
首先介绍了结构静力动力分析理论、流固耦合问题的有限元计算方法,从流固耦合的角度出发,对坝库相互作用的机理进行了研究,利用FORTRAN语言,编制了坝体-库水-地基耦合系统的有限元程序。
对某重力坝某坝段和某拱坝拱冠梁进行了计算,分析了有质量地基模型和无质量地基模型,探讨了现行规范中附加质量模型和考虑坝库相互作用的流固耦合模型,可以看出流固耦合模型与附加质量模型相比结构大部分部位的结果较小,但更能反映库水-坝体相互作用的实际情况。
利用大型有限元ADINA软件,基于ADINA软件建立坝库系统流固耦合模型,分别进行了模态分析、地震时程响应分析。以某拱坝为例,研究了库水位和库水压缩性对拱坝模态和自振频率等的影响。作为工程应用,以某拱坝工程为例,建立拱坝-库水-地基系统相互作用的动力耦合模型,对其进行了动力特性和地震响应的计算分析,得出了一些可供工程设计参考的有价值成果。
Hydropower resources in China ranks first in the world, but their distribution is uneven, about 80% concentrated in the west, mainly southwest. This area is a new strong tectonic movement and highly volatile geological environment mountain valley areas, which has a high incidence of strong earthquakes and geological hazards. At present, under construction and proposed a series of 200-300 m level high dams, such as Xiaowan, Goupitan, Xiluodu, Baihetan,Jingpin,Nuozhadu, Laxiwa, Wudongde, Dagangshan and so on.strategical project are all in these high earthquake intensity areas. Seismic safety is the key point in these high earthquake intensity areas, shocking earthquake which happened in Sichuan province China on May 12th in 2008 make people more clearly recognized this.
This paper describes dynamic analysis theory of structure, fluid-solid coupling problem of the finite element method. From the point of view of fluid-solid coupling, deep research has been made on the principle of the dam and reservoir interaction. Through using FORTRAN language, developed a finite element program of dam-water-foundation system interaction.
Calculate a gravity dam and an arch crown beam by the FORTRAN programme, Qualitatively analyze the quality foundation model and the massless foundation model, discuss the additional mass model of current specification and the fluid-solid coupling model basing on interaction theory, Compared to the additional mass model, we can see that the fluid-solid coupling mode has smaller results at most parts, which better reflects the actual dam-water interaction.
By using large-scale finite element software ADINA, establish dam-water system's fluid-solid coupling model, conducted modal analysis, seismic time-history response analysis, and then give an arch dam example, and study the arch dam's mode and self-vibration which is affected by the water level and the reservoir water compression. As an engineering application, establish dam-water-foundation system's fluid-solid coupling model through a arch dam, calculate the dynamic characteristics and seismic response of the arch dam, and obtained some valuable results for the engineering design.
引文
[1]陈厚群.混凝土高坝强震震例分析和启迪[J]水利学报,2009,40(1):10-18.
[2]陈厚群.高拱坝抗震设计研究进展[J].中国水利,2000,27(9):62-68.
[3]潘家铮,何景.中国大坝50年[M].北京:中国水利水电出版社,2000:135-142.
[4]李攒,陈兴华,郑建波等.混凝土拱坝设计[M].北京:中国电力出版社,2000:551-557.
[5]林皋.汶川大地震中大坝震害与大坝抗震安全性分析[J].大连理工大学学报,2009:49(5):657-666.
[6]林建镛.水工建筑物[M].北京:水利水电出版社,2005:26-29.
[7]吴一红,谢省宗.水工结构流固耦合动力特性分析[J].水利学报,1995,1:27-34.
[8]王忠.坝-库相互作用及抗震技术研究[D].成都:四川大学,2001:14-16.
[9]杜修力,王进廷.拱坝-可压缩库水-地基地震波动反应分析方法[J].水利学报,2002,6(6):83-90.
[10]王进廷.高混凝土坝-可压缩库水-淤砂-地基系统地震反应分析研究[D].北京:中国水利水电科学研究院,2001:8-12.
[11]赵兰浩.考虑坝体-库水-地基相互作用的有横缝拱坝地震响应分析[D].南京:河海大学,2006:17-21.
[12]晏启祥.有横缝高拱坝的非线性地震响应分析[D].成都:四川大学,2002:10-13.
[13]张楚汉,王光纶.论拱坝抗震[J].地震工程与工程振动,1986:59-69.
[14]Westergaard.Water Pressures on Dams During Earthquakes [J].Trans.ASCE,1933,98:418-433.
[15]胡志强.考虑坝-基动力相互作用的有横缝拱坝地震响应分析[D].大连:大连理工大学,2003:10-13.
[16]张楚汉.高坝-水电站工程建设中的关键科学技术问题[J].贵州水力发电,2005,19(2):1-8.
[17]王进廷.高混凝土坝-可压缩库水-淤砂-地基系统地震反应分析研究[D].北京:中国水利水电科学研究院,2001:127-130.
[18]何发祥.拱坝动水压力及气幕隔震技术研究[D].成都:四川大学,2000:15-19.
[19]吴一红,李世琴,谢省宗.拱坝-库水-地基耦合系统坝身泄洪动力分析[J].水利学报,1996,(11):6-12.
[20]傅作新,王立新,章青.拱坝的动水压力和拱坝库水的相互作用分析[C].第三届全国地震工程会议论文集(Ⅲ),1990,1271-1276.
[21]陈厚群,章青.库水中淤沙对刚性坝的动水压力影响[J].河海大学学报(自然科学版),2000,28(4):72-76.
[22]杜修力,王进廷,张楚汉.淤积泥砂对垂直地运动作用时刚性坝面动压力的影响研究[J].水利学报,2003,(3):66-72.
[23]邢景棠,周盛,崔尔杰.流固耦合力学概述[J].力学进展,1997,27(1):19-38.
[24]钱令希,邱大洪.利用电模拟法计算挡水坝在满库时的自振频率[J].土木工程学报,1958,
(2).
[25]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,1983:222-226.
[26]王克成.水中圆柱体的振动问题[J].陕西机械学院学报,198l,(3):8-12.
[27]A.K.Chopra, EarthquakeAnalysis of Concrete Gravity Dams Including Dam-water-foundation Rock Interaction [J]. Earthquake Engineering and Structural Dynamics,1981,9:363-383.
[28]刘云贺,俞茂宏,王克成.流体-固体瞬态动力耦合有限元分析研究[J].水利学报,2002,(2):85-89.
[29]刘云贺,俞茂宏,陈厚群.流体固体动力耦合分析的有限元法[J].工程力学,2005,22(6):1-6.
[30]施景勋,林建华.重力坝与水-地基动力耦合系统地震反应的时域分析[J].工程力学,1994,11(3):99-107.
[31]徐艳杰,张楚汉,金峰.非线性拱坝-地基动力互相作用的FE-BE-IBE模型[J].清华大学学报(自然科学版),1998,38(11):99-103.
[32]L S Tjhen, G Y Yu.Application of BEM/FEM coupling procedure to dynamic fluid-structure interactionproblems [J].International Journal of Computational Engineering Science,2002,3 (4): 425-433.
[33]杜修力,王进廷.动水压力及其对坝体地震反应影响的研究进展[J].水利学报,2001,(7):13-21.
[34]K.J.Bathe, W.F.Hahn.On transient analysis of fluid-structure systems [J].Computers Structures.10, 1979:383-391.
[35]N. Akkas, H. h. Akay, C.Yilmaz. Applicability of general purpose finite element programs in solid-fluid interaction problems [J].Computers & Structures.10,1979:773-783.
[36]E.L.Wilson, M.Khalvati. Finite elements for dynamic analysis of fluid-solid systems [J] International journal For Numerical Methods In Engineering.19,1983:1657-1668.
[37]W.K.Liu, H.GChang. A method for computation for fluid-structure interaction [J].Computers & Structures.20,1985:311-320.
[38]Harn C.Chen, Robert L.Taylor.Vibration analysis of fluid-solid systems using finite element displacement formulation [J].International, journal For humerical Alethods In Engineering.29, 1990: 683-698.
[39]邢景堂.考虑自由面线性波的流固耦合动力分析的两个变分公式[J].航空学报,1988,9(11):A568-A571.
[40]邢景堂.线性流固耦合动力分析程序FSIAP92简介[J].航空学报,1992,13(9):A548-A551.
[4l]晏启祥,刘浩吾,夏春.基于改进的Wilson-θ法的流固耦合迭代算法[J].西南交通大学学报,2002,37(2):204-208.
[42]晏启样,刘浩吾,饶俊勇.用改进的Wilson-θ法分析流固耦合表面波的影响[J].四川大学学 报,2002,34(4):19-21.
[43]杜建国,林皋,谢清粮.一种新的求解坝面动水压力的半解析方法[J].振动与冲击,2009,28(3):31-35.
[44]傅作新,章青.水体压缩性对挡水结构自振特性的影响[J].河海大学学报,1994,22(6):1-7.
[45]迟世春,顾淦臣.考虑水体压缩性与不考虑水体压缩性坝水系统基频及振型的比较[J].华北水利水电学院学报,1995,16(1):10-15.
[46]高瑞强,宫必宁,郭建平.坝-水相互作用中水的压缩性影响研究[J].水利与建筑工程学报,2008,6(1):106-108.
[47]刘浩吾.混凝土坝动水压力与库水可压缩性效应[J].水利水电科技进展,2002,22(2):10-13.
[48]周继刚,张耀明,高述辕.迎水坝面地震动水压力的无奇异边界元分析[J].山东理工大学学报(自然科学版),2009,23(2):13-16.
[49]隆文非.高坝动水压力及气幕隔震机理研究[D].成都:四川大学,2005:19-23.
[50]Selby, Severn. An experiment assessment of add-mass of some plates Vibration in water[J].Earthquake Eng. Struct.Dyn,1972,1 (2):189-200.
[51]Tan, Han chen, Chopra, AnilK. Earthquake analysis of arch including dam-water-foundation rock interaction [J].Earthquake Engineering and Structural dynamics.24,1995:1453-1474.
[52]Porter, Craig S, Chopra, Anil K. Hydrodynamic effects in dynamic response of simple arch dams [J].Earthquake Engineering and Structural Dynamics.10,1982:417-431.
[53]A.K. Chopra. Earthquake response of gravity dams [J].Journal of Engineering Mechanics Division, ASCE,96 (EM4),1970:443-454.
[54]A.K Chopra. Hydrodynamic effects in earthquake response of arch dams [J]. Proceedings of China-US Workshop on Earthquake Behavior of Arch Dams, Beijing, China.1987:110-129.
[55]廖振鹏.工程波动理论导论(第二版)[M],北京:科学出版社,2001:10-15.
[56]赵兰浩,李同春,牛志伟.考虑库水可压缩性的高拱坝动力特性分析[J].水电能源科学,2008,26(3):68-70.
[57]杜庆华,吴有生,冯振兴.流固耦合振动问题的某些工程处理方法[J].固体力学学报,1988,9(1):49-61.
[58]晏启祥,刘浩吾,王忠.流固耦合系统库底边界对动水压力的影响[[J],西南交通大学学报,2002,37(3):246-249.
[59]邱流潮.挡水结构地震动水压力时域有限元分析[J].中国农村水利水电,2004,(1):79-81.
[60]陈厚群.高拱坝抗震设计研究进展[J].中国水利,1996(9),2000:63-65.
[6l]柴军瑞,刘浩吾.高拱坝研究新进展[J].水利水电科技进展,2001,(6):1-4.
[62]王海波,李德玉.拱坝抗震设计理论与实践[M].北京:中国水利水电出版社,2006:77-49.
[63]徐艳杰.横缝配筋的拱坝地震非线性模型与无限地基影响研究[D].清华大学,1999:8-10.
[64]刘晶波,李彬.三维粘弹性静-动力统-人工边界[J].中国科学E辑,2005,35(9):966-980.
[65]刘晶波,吕彦东.结构-地基动力相互作用问题分析的一种直接方法[J].土木工程学报,1998,31(3):55-64.
[66]刘晶波,王振字,杜修力,杜义欣.波动问题中的三维时域粘弹性人工边界[J].工程力学,200522(6):46-51.
[67]王勖成.有限单元法[M].北京:清华大学出版社,2003:10-13.
[68]李德玉.拱坝试载法静动力分析程序SDTLM88 [M].北京:中国水利水电科学研究院,1988:7-10.
[69]候顺载.拱坝静动力有限元程序ADAP-CH [M].北京:中国水利水电科学研究院,1988:7-10.
[70]涂劲.有缝界面的混凝土高坝-地基系统非线性地展波动反应分析[D].北京:中国水利水电科学研究院,1999:8-9.
[71]陈国荣.有限单元法原理及应用[M].北京:科学出版社,2009:3.
[72]孙金海.数学物理方程与特殊函数[M].北京:高等教育出版社,2004:1.
[73]江见鲸.工程结构计算机仿真分析[M].北京:清华大学出版社,1996:1-2.
[74]徐芝纶.弹性力学[M].北京:高等教育出版社,2002:139-141.
[75]徐士良.FORTRAN常用算法程序集[M].北京:清华大学出版社,1992:50-52.
[76]朱自强.应用计算流体力学[M].北京:北京航空航天大学出版社,1998:45-47.
[77]罗伯特L.威格尔.地震工程学[M].北京:科学出版社,1978:94-95.
[78]刘晶波,杜修力.结构动力学[M].北京:机械工业出版社,1978:132-133.
[79]傅作新.水工结构力学问题的分析与计算[M].南京:河海大学出版社,1993:11-12.
[80]王建军,李其汉,朱梓根等.自由液面大晃动的流固耦合数值分析方法研究进展[J],力学季刊,2001,22(4):447-454.
[81]张廷芳.计算流体力学[M].大连理工大学出版社,2007:365.
[82]ADINA R & D, Inc.Theory and Modeling Guide (Volume Ⅲ:ADINA CFD & FSI).2005:90.
[2]陈厚群.高拱坝抗震设计研究进展[J].中国水利,2000,27(9):62-68.
[3]潘家铮,何景.中国大坝50年[M].北京:中国水利水电出版社,2000:135-142.
[4]李攒,陈兴华,郑建波等.混凝土拱坝设计[M].北京:中国电力出版社,2000:551-557.
[5]林皋.汶川大地震中大坝震害与大坝抗震安全性分析[J].大连理工大学学报,2009:49(5):657-666.
[6]林建镛.水工建筑物[M].北京:水利水电出版社,2005:26-29.
[7]吴一红,谢省宗.水工结构流固耦合动力特性分析[J].水利学报,1995,1:27-34.
[8]王忠.坝-库相互作用及抗震技术研究[D].成都:四川大学,2001:14-16.
[9]杜修力,王进廷.拱坝-可压缩库水-地基地震波动反应分析方法[J].水利学报,2002,6(6):83-90.
[10]王进廷.高混凝土坝-可压缩库水-淤砂-地基系统地震反应分析研究[D].北京:中国水利水电科学研究院,2001:8-12.
[11]赵兰浩.考虑坝体-库水-地基相互作用的有横缝拱坝地震响应分析[D].南京:河海大学,2006:17-21.
[12]晏启祥.有横缝高拱坝的非线性地震响应分析[D].成都:四川大学,2002:10-13.
[13]张楚汉,王光纶.论拱坝抗震[J].地震工程与工程振动,1986:59-69.
[14]Westergaard.Water Pressures on Dams During Earthquakes [J].Trans.ASCE,1933,98:418-433.
[15]胡志强.考虑坝-基动力相互作用的有横缝拱坝地震响应分析[D].大连:大连理工大学,2003:10-13.
[16]张楚汉.高坝-水电站工程建设中的关键科学技术问题[J].贵州水力发电,2005,19(2):1-8.
[17]王进廷.高混凝土坝-可压缩库水-淤砂-地基系统地震反应分析研究[D].北京:中国水利水电科学研究院,2001:127-130.
[18]何发祥.拱坝动水压力及气幕隔震技术研究[D].成都:四川大学,2000:15-19.
[19]吴一红,李世琴,谢省宗.拱坝-库水-地基耦合系统坝身泄洪动力分析[J].水利学报,1996,(11):6-12.
[20]傅作新,王立新,章青.拱坝的动水压力和拱坝库水的相互作用分析[C].第三届全国地震工程会议论文集(Ⅲ),1990,1271-1276.
[21]陈厚群,章青.库水中淤沙对刚性坝的动水压力影响[J].河海大学学报(自然科学版),2000,28(4):72-76.
[22]杜修力,王进廷,张楚汉.淤积泥砂对垂直地运动作用时刚性坝面动压力的影响研究[J].水利学报,2003,(3):66-72.
[23]邢景棠,周盛,崔尔杰.流固耦合力学概述[J].力学进展,1997,27(1):19-38.
[24]钱令希,邱大洪.利用电模拟法计算挡水坝在满库时的自振频率[J].土木工程学报,1958,
(2).
[25]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,1983:222-226.
[26]王克成.水中圆柱体的振动问题[J].陕西机械学院学报,198l,(3):8-12.
[27]A.K.Chopra, EarthquakeAnalysis of Concrete Gravity Dams Including Dam-water-foundation Rock Interaction [J]. Earthquake Engineering and Structural Dynamics,1981,9:363-383.
[28]刘云贺,俞茂宏,王克成.流体-固体瞬态动力耦合有限元分析研究[J].水利学报,2002,(2):85-89.
[29]刘云贺,俞茂宏,陈厚群.流体固体动力耦合分析的有限元法[J].工程力学,2005,22(6):1-6.
[30]施景勋,林建华.重力坝与水-地基动力耦合系统地震反应的时域分析[J].工程力学,1994,11(3):99-107.
[31]徐艳杰,张楚汉,金峰.非线性拱坝-地基动力互相作用的FE-BE-IBE模型[J].清华大学学报(自然科学版),1998,38(11):99-103.
[32]L S Tjhen, G Y Yu.Application of BEM/FEM coupling procedure to dynamic fluid-structure interactionproblems [J].International Journal of Computational Engineering Science,2002,3 (4): 425-433.
[33]杜修力,王进廷.动水压力及其对坝体地震反应影响的研究进展[J].水利学报,2001,(7):13-21.
[34]K.J.Bathe, W.F.Hahn.On transient analysis of fluid-structure systems [J].Computers Structures.10, 1979:383-391.
[35]N. Akkas, H. h. Akay, C.Yilmaz. Applicability of general purpose finite element programs in solid-fluid interaction problems [J].Computers & Structures.10,1979:773-783.
[36]E.L.Wilson, M.Khalvati. Finite elements for dynamic analysis of fluid-solid systems [J] International journal For Numerical Methods In Engineering.19,1983:1657-1668.
[37]W.K.Liu, H.GChang. A method for computation for fluid-structure interaction [J].Computers & Structures.20,1985:311-320.
[38]Harn C.Chen, Robert L.Taylor.Vibration analysis of fluid-solid systems using finite element displacement formulation [J].International, journal For humerical Alethods In Engineering.29, 1990: 683-698.
[39]邢景堂.考虑自由面线性波的流固耦合动力分析的两个变分公式[J].航空学报,1988,9(11):A568-A571.
[40]邢景堂.线性流固耦合动力分析程序FSIAP92简介[J].航空学报,1992,13(9):A548-A551.
[4l]晏启祥,刘浩吾,夏春.基于改进的Wilson-θ法的流固耦合迭代算法[J].西南交通大学学报,2002,37(2):204-208.
[42]晏启样,刘浩吾,饶俊勇.用改进的Wilson-θ法分析流固耦合表面波的影响[J].四川大学学 报,2002,34(4):19-21.
[43]杜建国,林皋,谢清粮.一种新的求解坝面动水压力的半解析方法[J].振动与冲击,2009,28(3):31-35.
[44]傅作新,章青.水体压缩性对挡水结构自振特性的影响[J].河海大学学报,1994,22(6):1-7.
[45]迟世春,顾淦臣.考虑水体压缩性与不考虑水体压缩性坝水系统基频及振型的比较[J].华北水利水电学院学报,1995,16(1):10-15.
[46]高瑞强,宫必宁,郭建平.坝-水相互作用中水的压缩性影响研究[J].水利与建筑工程学报,2008,6(1):106-108.
[47]刘浩吾.混凝土坝动水压力与库水可压缩性效应[J].水利水电科技进展,2002,22(2):10-13.
[48]周继刚,张耀明,高述辕.迎水坝面地震动水压力的无奇异边界元分析[J].山东理工大学学报(自然科学版),2009,23(2):13-16.
[49]隆文非.高坝动水压力及气幕隔震机理研究[D].成都:四川大学,2005:19-23.
[50]Selby, Severn. An experiment assessment of add-mass of some plates Vibration in water[J].Earthquake Eng. Struct.Dyn,1972,1 (2):189-200.
[51]Tan, Han chen, Chopra, AnilK. Earthquake analysis of arch including dam-water-foundation rock interaction [J].Earthquake Engineering and Structural dynamics.24,1995:1453-1474.
[52]Porter, Craig S, Chopra, Anil K. Hydrodynamic effects in dynamic response of simple arch dams [J].Earthquake Engineering and Structural Dynamics.10,1982:417-431.
[53]A.K. Chopra. Earthquake response of gravity dams [J].Journal of Engineering Mechanics Division, ASCE,96 (EM4),1970:443-454.
[54]A.K Chopra. Hydrodynamic effects in earthquake response of arch dams [J]. Proceedings of China-US Workshop on Earthquake Behavior of Arch Dams, Beijing, China.1987:110-129.
[55]廖振鹏.工程波动理论导论(第二版)[M],北京:科学出版社,2001:10-15.
[56]赵兰浩,李同春,牛志伟.考虑库水可压缩性的高拱坝动力特性分析[J].水电能源科学,2008,26(3):68-70.
[57]杜庆华,吴有生,冯振兴.流固耦合振动问题的某些工程处理方法[J].固体力学学报,1988,9(1):49-61.
[58]晏启祥,刘浩吾,王忠.流固耦合系统库底边界对动水压力的影响[[J],西南交通大学学报,2002,37(3):246-249.
[59]邱流潮.挡水结构地震动水压力时域有限元分析[J].中国农村水利水电,2004,(1):79-81.
[60]陈厚群.高拱坝抗震设计研究进展[J].中国水利,1996(9),2000:63-65.
[6l]柴军瑞,刘浩吾.高拱坝研究新进展[J].水利水电科技进展,2001,(6):1-4.
[62]王海波,李德玉.拱坝抗震设计理论与实践[M].北京:中国水利水电出版社,2006:77-49.
[63]徐艳杰.横缝配筋的拱坝地震非线性模型与无限地基影响研究[D].清华大学,1999:8-10.
[64]刘晶波,李彬.三维粘弹性静-动力统-人工边界[J].中国科学E辑,2005,35(9):966-980.
[65]刘晶波,吕彦东.结构-地基动力相互作用问题分析的一种直接方法[J].土木工程学报,1998,31(3):55-64.
[66]刘晶波,王振字,杜修力,杜义欣.波动问题中的三维时域粘弹性人工边界[J].工程力学,200522(6):46-51.
[67]王勖成.有限单元法[M].北京:清华大学出版社,2003:10-13.
[68]李德玉.拱坝试载法静动力分析程序SDTLM88 [M].北京:中国水利水电科学研究院,1988:7-10.
[69]候顺载.拱坝静动力有限元程序ADAP-CH [M].北京:中国水利水电科学研究院,1988:7-10.
[70]涂劲.有缝界面的混凝土高坝-地基系统非线性地展波动反应分析[D].北京:中国水利水电科学研究院,1999:8-9.
[71]陈国荣.有限单元法原理及应用[M].北京:科学出版社,2009:3.
[72]孙金海.数学物理方程与特殊函数[M].北京:高等教育出版社,2004:1.
[73]江见鲸.工程结构计算机仿真分析[M].北京:清华大学出版社,1996:1-2.
[74]徐芝纶.弹性力学[M].北京:高等教育出版社,2002:139-141.
[75]徐士良.FORTRAN常用算法程序集[M].北京:清华大学出版社,1992:50-52.
[76]朱自强.应用计算流体力学[M].北京:北京航空航天大学出版社,1998:45-47.
[77]罗伯特L.威格尔.地震工程学[M].北京:科学出版社,1978:94-95.
[78]刘晶波,杜修力.结构动力学[M].北京:机械工业出版社,1978:132-133.
[79]傅作新.水工结构力学问题的分析与计算[M].南京:河海大学出版社,1993:11-12.
[80]王建军,李其汉,朱梓根等.自由液面大晃动的流固耦合数值分析方法研究进展[J],力学季刊,2001,22(4):447-454.
[81]张廷芳.计算流体力学[M].大连理工大学出版社,2007:365.
[82]ADINA R & D, Inc.Theory and Modeling Guide (Volume Ⅲ:ADINA CFD & FSI).2005:90.