超大跨CFRP拉索斜拉桥力学性能分析
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摘要
随着桥梁技术的日益发展,大跨、超大跨桥梁的建设成为了当今桥梁发展的一个趋势。斜拉桥由于其跨越能力大的优点,越来越来越受到当今桥梁设计者的重视,尤其是新材料在超大跨斜拉桥桥中的应用研究,在国外已经成为一个研究热点。超大跨度斜拉桥结构柔性大,其几何非线性效应更为显著,成桥状态的静、动力特性变得更为复杂,因此,开展有关这一领域的研究十分重要。
本文首先系统地叙述了斜拉桥计算的有限位移理论,总结了影响斜拉桥几何非线性的三个因素:垂度效应、轴力与弯矩耦合产生的梁-柱效应以及大位移效应。论述了斜拉桥合理成桥状态的评定原则,简述了斜拉桥索力优化的三类方法。
其次,针对大跨径斜拉桥的结构特点,从主梁、主塔、斜拉索和边界条件等方面论述了斜拉桥有限元分析的建模方法:通过midas软件采用有限元法对主跨800m、1500mCFRP拉索和钢拉索斜拉桥进行了静力性能(包括恒荷载、车辆荷载、温度荷载)分析。
再次,论述了大跨径斜拉桥三维有限元分析法的基本原理;然后对比分析了主跨800m、1500m CFRP拉索和钢拉索斜拉桥的动自振特性。
最后,在综合考虑索一桥塔一桥面耦合的基础上,建立了索一桥塔一桥面耦合参数振动的非线性模型,并采用数值方法分析了初始扰动及阻尼等对拉索参数振动特性的影响。
With the development of bridge technology, the constructions of great and massive bridges become the trend of the time. As an obvious advantage, super span ability of cable-strayed bridge has been attracting more and more designer. The application of some new material in massive cable-strayed bridge becomes a hot topic among researchers abroad. The structure of massive strayed bridges is soft as well as geometric nonlinearity, which made the bridges stativity and dynamicity more complex. Therefore, researching in this field is very important.
Firstly, The thesis systematically describes the calculation of the finite displacement theory of cable-stayed bridge. Introducing its geometric nonlinearity influence by three factors:sag effect、axial force and bending moment produced by the coupling beam-column effect and displacement effect. Discussing the assessment principles of the stayed cable bridge. Breifly illustrate three categories of how to optimize the effort of cable-strayed bridges.
Secondly, aiming at the structure characteristics of the cable-strayed bridges, the thesis illustrates the modeling method of finite element method in different aspects, like main girder、main tower, cable, boundary condition and so on. The static performance (including the constant load, vehicle load, temperature load) of the 800m-span and 1500m-span cable-stayed bridge with CFRP cables and another one with steel cables are analyzed contrastively through the midas software.
Thirdly, the thesis discussing the basic theory of 3D finite elements in super cable-strayed bridges. The dynamic characteristics of the 800m-span and 1500m-span cable-stayed bridge with CFRP cables and another one with steel cables are analyzed contrastively。Finally,Considering with the sag, clination and geometry nonlinearity, a coupling parametric vibration model was built. By using this model, numerical results of CFRP cables and steel cables with the same condition are obtained, and the results demonstrate that the vibration is related with the ratio of initial disturbance and damping ratio。
本文首先系统地叙述了斜拉桥计算的有限位移理论,总结了影响斜拉桥几何非线性的三个因素:垂度效应、轴力与弯矩耦合产生的梁-柱效应以及大位移效应。论述了斜拉桥合理成桥状态的评定原则,简述了斜拉桥索力优化的三类方法。
其次,针对大跨径斜拉桥的结构特点,从主梁、主塔、斜拉索和边界条件等方面论述了斜拉桥有限元分析的建模方法:通过midas软件采用有限元法对主跨800m、1500mCFRP拉索和钢拉索斜拉桥进行了静力性能(包括恒荷载、车辆荷载、温度荷载)分析。
再次,论述了大跨径斜拉桥三维有限元分析法的基本原理;然后对比分析了主跨800m、1500m CFRP拉索和钢拉索斜拉桥的动自振特性。
最后,在综合考虑索一桥塔一桥面耦合的基础上,建立了索一桥塔一桥面耦合参数振动的非线性模型,并采用数值方法分析了初始扰动及阻尼等对拉索参数振动特性的影响。
With the development of bridge technology, the constructions of great and massive bridges become the trend of the time. As an obvious advantage, super span ability of cable-strayed bridge has been attracting more and more designer. The application of some new material in massive cable-strayed bridge becomes a hot topic among researchers abroad. The structure of massive strayed bridges is soft as well as geometric nonlinearity, which made the bridges stativity and dynamicity more complex. Therefore, researching in this field is very important.
Firstly, The thesis systematically describes the calculation of the finite displacement theory of cable-stayed bridge. Introducing its geometric nonlinearity influence by three factors:sag effect、axial force and bending moment produced by the coupling beam-column effect and displacement effect. Discussing the assessment principles of the stayed cable bridge. Breifly illustrate three categories of how to optimize the effort of cable-strayed bridges.
Secondly, aiming at the structure characteristics of the cable-strayed bridges, the thesis illustrates the modeling method of finite element method in different aspects, like main girder、main tower, cable, boundary condition and so on. The static performance (including the constant load, vehicle load, temperature load) of the 800m-span and 1500m-span cable-stayed bridge with CFRP cables and another one with steel cables are analyzed contrastively through the midas software.
Thirdly, the thesis discussing the basic theory of 3D finite elements in super cable-strayed bridges. The dynamic characteristics of the 800m-span and 1500m-span cable-stayed bridge with CFRP cables and another one with steel cables are analyzed contrastively。Finally,Considering with the sag, clination and geometry nonlinearity, a coupling parametric vibration model was built. By using this model, numerical results of CFRP cables and steel cables with the same condition are obtained, and the results demonstrate that the vibration is related with the ratio of initial disturbance and damping ratio。
引文
[1]吴榃.浅谈斜拉桥的发展现状及趋势[J].铁道建设.2004(4).19-23.
[2]肖冠英.大跨度斜拉桥计算分析研究[D].成都:西南交通大学.2008年
[3]王蓓.斜拉桥索振动及减振装置研究[D].西安:西安理工大学.2008年
[4]BAM BACH M R, ELCHAI AKANI M. PlasticM echanism Analysis of Steel SHS Strengthened with CFRP under Large Axial Deformation[J]. Thin walled Structures, 2007.45(2):159-170.
[5]华新.中等跨度斜拉桥抗震设计研究[D].上海:同济大学.2006年
[6]毕银博.超大跨径CFRP缆索悬索桥力学性能分析[D].西安:长安大学.2010年
[7]梅葵花.CFRP拉索斜拉桥的研究[D].南京:东南大学.2005年
[8]刘应才,刘飞凡..斜拉索垂度对大跨径斜拉桥的影响分析[J].徐州建筑职业技术学院学报.2009(1).23-25.
[9]辛克贵,刘钺强,杨国平.大跨度斜拉桥恒载非线性静力分析[J].清华大学学报(自然科学版).2002(6).818-821.
[10]华孝良,徐光辉.桥梁结构非线性分析[M].北京:人民交通出版社.1997年
[11]郑凯锋,陈宁,张晓翘.桥梁结构仿真分析技术研究[J].桥梁建设.1998(02)
[12]李正仁译.关于在直布罗陀海峡最窄处建造碳纤维增强复合材料的建议.国外桥梁,1990,(4):45-50
[13]项海帆.高等桥梁结构理论[M].北京:人民交通出版社.2002
[14]龚仁明.超大跨度斜拉桥方案设计.同济大学学报,1999,(2):229-233
[15]Charles E. Bakis, Antonio Nanni, Thomas E. Boothby. "FRP Prestressing for Highway Bridges-Volume Ⅲ". Federal Highway Administration.2000.2
[16]郭翠翠,王波,张华兵.斜拉桥索-塔-梁耦合参数振动[J].公路工程.2010,35(3).
[17]蔡国宏编译.斜拉桥的发展经验和展望[J].国外公路.1997(4):19-24.
[18]梅葵花,吕志涛.CFRP在超大跨悬索桥和斜拉桥中的应用前景[J].桥梁建设.2002,142(2):75-78
[19]吕志涛.新世纪混凝土结构对新材料的挑战[J].中国首届纤维增强塑料(FRP)混凝土结构学术交流会论文集.2000.6.北京.
[20]王伯惠.斜拉桥拉索静力计算[J].公路,2003.(6):1-8
[21]汪至刚.大跨度斜拉桥拉索的振动与控制[D].杭州:浙江大学.2000年
[22]顾明,刘慈军,罗国强等.斜拉索拉索的风(雨)激振及控制[J].上海力学.1998,(4):281-288
[23]王修勇,陈政清,倪一清.斜拉桥拉索风雨振观测及其控制[J].土木工程学报.2003
[24]汪至刚,孙炳楠.斜拉索的参数振动[J].土木工程学报.2002.(5):28-33.
[25]魏科.基于CR列式的斜拉桥几何非线性分析[D].西安:长安大学.2009年
[26]范立础.桥梁工程(下册)[M].北京:人民交通出版社.1990
[27]肖汝城,项海帆.斜拉桥索力优化的影响矩阵法[J].同济大学学报.1998,(3):234-240
[28]金增洪编译.斜拉桥的振动分析[J].国外公路,1996,(1):22-28
[29]陈铁冰.斜拉桥几何、材料非线性静力分析及其可靠度评估[D].上海:同济大学.2000年
[30]杜国华,姜林.斜拉桥的合理索力及其施工张拉力[J].桥梁建设,1989,(3):11-17
[31]王应良.大跨度斜拉桥考虑几何非线性的静、动力分析和钢箱梁的第二体系应力研究[D].西南交通大学,2000年
[32]亢战,钟万勰.斜拉桥参数共振问题的数值研究[J].土木工程学报.1998,4):14-22.
[33]王福俊.斜拉桥拉索参数振动及斜拉桥动力分析[D].成都:西南交通大学.2008年
[2]肖冠英.大跨度斜拉桥计算分析研究[D].成都:西南交通大学.2008年
[3]王蓓.斜拉桥索振动及减振装置研究[D].西安:西安理工大学.2008年
[4]BAM BACH M R, ELCHAI AKANI M. PlasticM echanism Analysis of Steel SHS Strengthened with CFRP under Large Axial Deformation[J]. Thin walled Structures, 2007.45(2):159-170.
[5]华新.中等跨度斜拉桥抗震设计研究[D].上海:同济大学.2006年
[6]毕银博.超大跨径CFRP缆索悬索桥力学性能分析[D].西安:长安大学.2010年
[7]梅葵花.CFRP拉索斜拉桥的研究[D].南京:东南大学.2005年
[8]刘应才,刘飞凡..斜拉索垂度对大跨径斜拉桥的影响分析[J].徐州建筑职业技术学院学报.2009(1).23-25.
[9]辛克贵,刘钺强,杨国平.大跨度斜拉桥恒载非线性静力分析[J].清华大学学报(自然科学版).2002(6).818-821.
[10]华孝良,徐光辉.桥梁结构非线性分析[M].北京:人民交通出版社.1997年
[11]郑凯锋,陈宁,张晓翘.桥梁结构仿真分析技术研究[J].桥梁建设.1998(02)
[12]李正仁译.关于在直布罗陀海峡最窄处建造碳纤维增强复合材料的建议.国外桥梁,1990,(4):45-50
[13]项海帆.高等桥梁结构理论[M].北京:人民交通出版社.2002
[14]龚仁明.超大跨度斜拉桥方案设计.同济大学学报,1999,(2):229-233
[15]Charles E. Bakis, Antonio Nanni, Thomas E. Boothby. "FRP Prestressing for Highway Bridges-Volume Ⅲ". Federal Highway Administration.2000.2
[16]郭翠翠,王波,张华兵.斜拉桥索-塔-梁耦合参数振动[J].公路工程.2010,35(3).
[17]蔡国宏编译.斜拉桥的发展经验和展望[J].国外公路.1997(4):19-24.
[18]梅葵花,吕志涛.CFRP在超大跨悬索桥和斜拉桥中的应用前景[J].桥梁建设.2002,142(2):75-78
[19]吕志涛.新世纪混凝土结构对新材料的挑战[J].中国首届纤维增强塑料(FRP)混凝土结构学术交流会论文集.2000.6.北京.
[20]王伯惠.斜拉桥拉索静力计算[J].公路,2003.(6):1-8
[21]汪至刚.大跨度斜拉桥拉索的振动与控制[D].杭州:浙江大学.2000年
[22]顾明,刘慈军,罗国强等.斜拉索拉索的风(雨)激振及控制[J].上海力学.1998,(4):281-288
[23]王修勇,陈政清,倪一清.斜拉桥拉索风雨振观测及其控制[J].土木工程学报.2003
[24]汪至刚,孙炳楠.斜拉索的参数振动[J].土木工程学报.2002.(5):28-33.
[25]魏科.基于CR列式的斜拉桥几何非线性分析[D].西安:长安大学.2009年
[26]范立础.桥梁工程(下册)[M].北京:人民交通出版社.1990
[27]肖汝城,项海帆.斜拉桥索力优化的影响矩阵法[J].同济大学学报.1998,(3):234-240
[28]金增洪编译.斜拉桥的振动分析[J].国外公路,1996,(1):22-28
[29]陈铁冰.斜拉桥几何、材料非线性静力分析及其可靠度评估[D].上海:同济大学.2000年
[30]杜国华,姜林.斜拉桥的合理索力及其施工张拉力[J].桥梁建设,1989,(3):11-17
[31]王应良.大跨度斜拉桥考虑几何非线性的静、动力分析和钢箱梁的第二体系应力研究[D].西南交通大学,2000年
[32]亢战,钟万勰.斜拉桥参数共振问题的数值研究[J].土木工程学报.1998,4):14-22.
[33]王福俊.斜拉桥拉索参数振动及斜拉桥动力分析[D].成都:西南交通大学.2008年