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《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

卷:

27卷

期数:

2010年03期

页码:

59-64

栏目:

出版日期:

2010-09-20

文章信息/Info

Title:

Secondary Stress Analysis of Main Cable of Suspension Bridge Considering Bending Rigidity

作者:

聂利芳¹,沈锐利¹,唐茂林¹,沈旺²

1. 西南交通大学 桥梁工程系,四川 成都 610031; 2. 浙江省舟山连岛工程建设指挥部,浙江 舟山 316000

Author(s):

NIE Li-fang¹, SHEN Rui-li¹, TANG Mao-lin¹, SHEN Wang²

1. Department of Bridge Engineering, Southwest Jiaotong University, Chengdu 610031, Sichuan, China; 2. Zhejiang Provincial Construction Headquarters of Zhoushan Islands Link Project, Zhoushan 316000, Zhejiang, China

关键词:

悬索桥;  二次应力;  主缆;  抗弯刚度;  BNLAS

Keywords:

suspension bridge;  secondary stress;  main cable;  bending rigidity;  BNLAS

分类号:

U448.25

DOI:

-

文献标志码:

A

摘要:

为了研究悬索桥主缆考虑抗弯刚度引起的二次应力,以一座主跨为730 m的双塔单跨悬索桥为例,用索单元与空间梁单元组成的组合单元对主缆进行模拟,采用桥梁非线性分析软件BNLAS建立有限元模型,通过改变组合单元中梁单元的抗弯惯性矩,分析了抗弯刚度对主缆边跨和主跨二次应力的影响; 比较了加劲梁从跨中向桥塔方向吊装和从桥塔向跨中方向吊装2种不同吊装方案下的二次应力,研究吊装过程中二次应力的变化情况; 分析了恒载作用下悬索桥的二次应力随跨度的变化,并与有限元结果进行比较。结果表明:主缆抗弯惯性矩对二次应力影响很小; 吊装顺序对二次应力有较明显的影响; 恒载作用下跨度越小,二次应力越大。

Abstract:

In order to study the secondary stress of main cable of suspension bridge considering the bending rigidity, authors took a main-span of 730 m with twin-towers and single-span suspension bridge as example. The main cable was simulated with composite unit of cable unit and spatial beam unit. Then the finite element model was established by using bridge nonlinear analysis software BNLAS. The effects of bending rigidity on the main cable secondary stress of side-span and main-span were analyzed by way of changing the beam unit bending moment of inertia of composite unit. At the same time, the secondary stress was studied when the stiffening girder was lifted from bridge towers to the mid-span, as well as from the mid-span to bridge towers to research the secondary stress during the process of lifting. Finally, the secondary stresses with different levels of long-span suspension bridge under a variety of loads were analyzed theoretically, and compared with the finite element results. Results show that the effect of bending moment of main cable on secondary stress is very small, and the process of lifting has significant impact on secondary stress. The smaller the span is, the greater the secondary stress is under dead load state.

参考文献/References:

[1] 严国敏,周世忠.现代悬索桥[M].北京:人民交通出版社,2002. YAN Guo-min,ZHOU Shi-zhong.Modern Suspension Bridges[M].Beijing:China Communications Press,2002.
[2]雷俊卿,郑明珠,徐恭义.悬索桥设计[M].北京:人民交通出版社,2002. LEI Jun-qing,ZHENG Ming-zhu,XU Gong-yi.Design of Suspension Bridge[M].Beijing:China Communications Press,2002.
[3]李枝军,韩晓林,李爱群,等.悬索桥桥塔挂缆前后动态特性分析与测试[J].中国公路学报,2007,20(5):54-58. LI Zhi-jun,HAN Xiao-lin,LI Ai-qun,et al.Dynamic Analysis and Test of Bridge Tower of Suspension Bridge Before and After Cable Installed[J].China Journal of Highway and Transport,2007,20(5):54-58.
[4]程 进,肖汝诚.基于逆可靠度法的大跨悬索桥主缆安全系数评估[J].中国公路学报,2007,20(1):58-61. CHENG Jin,XIAO Ru-cheng.Main Cable Safety Factors Assessment of Long-span Suspension Bridges Based on Inverse Reliability Method[J].China Journal of Highway and Transport,2007,20(1):58-61.
[5]狄 谨,武 隽.自锚式悬索桥主缆线形计算方法[J].交通运输工程学报,2004,4(3):38-43. DI Jin,WU Jun.Calculation Methods for Cable Curve of Self-anchored Suspension Bridge[J].Journal of Traffic and Transportation Engineering,2004,4(3):38-43.
[6]吴建强,彭 武,何治学.KLD3700型跨缆吊机在润扬大桥悬索桥钢箱梁吊装施工中的应用[J].筑路机械与施工机械化,2005,25(1):38-41. WU Jian-qiang,PENG Wu,HE Zhi-xue.Application of KLD3700 Deck Erection Gantry in Runyang Suspension Bridge[J].Road Machinery & Construction Mechanization,2005,25(1):38-41.
[7]吉姆辛 N J.缆索支承桥梁——概念与设计[M].2版.金增洪,译.北京:人民交通出版社,2002. GIMSING N J.Cable Supported Bridges:Concept & Design[M].2nd ed.Translated by JIN Zeng-hong.Beijing:China Communications Press,2002.
[8]DANA A,ANDERSON A,RAPP G M.George Washington Bridge:Design of Superstructure[J].Trans ASCE,1932,97:97-163.
[9]WYATT T A.Secondary Stresses in Parallel Wire Suspension Cables[J].Trans ASCE,1963,128:37-59.
[10]林长川,许宏亮,罗喜恒.悬索桥主缆的二次应力[C]//中国土木工程学会桥梁及结构工程学会.中国土木工程学会桥梁及结构工程学会第11届年会论文集.北京:人民交通出版社,2006:392-397. LIN Chang-chuan,XU Hong-liang,LUO Xi-heng.The Main Cables Secondary Stress of Suspension Bridge[C]//Bridge and Structural Engineering Society of China Civil Engineering Society.Symposium of the 11th Annual Meeting of Bridge and Structural Engineering Society of China Civil Engineering Society.Beijing:China Communications Press,2006:392-397.
[11]张 伟,潘 方.悬索桥主缆的次应力分析[J].郑州大学学报:工学版,2005,26(4):29-33. ZHANG Wei,PAN Fang.Secondary Stress Analysis of the Main Cable of Suspension Bridges[J].Journal of Zhengzhou University:Engineering Science,2005,26(4):29-33.
[12]曲 婷,王焕定,曾 森,等.考虑主缆弯曲刚度后对悬索桥的影响[J].低温建筑技术,2009(7):35-37. QU Ting,WANG Huan-ding,ZENG Sen,et al.The Research of Influence on Suspension Bridges After Considering Bending Rigidity of Cable[J].Low Temperature Architecture Technology,2009(7):35-37.
[13]唐茂林.大跨度悬索桥空间几何非线性分析与软件开发[D].成都:西南交通大学,2003. TANG Mao-lin.3D Geometric Nonlinear Analysis of Long-span Suspension Bridge and Its Software Development[D].Chengdu:Southwest Jiaotong University,2003.
[14]罗迎社,喻小明.工程力学[M].北京:北京大学出版社,2006. LUO Ying-she,YU Xiao-ming.Engineering Mechanics[M].Beijing:Peking University Press,2006.
[15]钱冬生,陈仁福.大跨度悬索桥的设计与施工[M].成都:西南交通大学出版社,1999. QIAN Dong-sheng,CHEN Ren-fu.Design and Construction of Long-span Suspension Bridges[M].Chengdu:Southwest Jiaotong University Press,1999.

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备注/Memo

备注/Memo:

收稿日期:2010-07-05
基金项目:“十一五”国家科技支撑计划项目(2008BAG07B05)
作者简介:聂利芳(1986-),女,河南安阳人,工学硕士,E-mail:nilifa@163.com。

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更新日期/Last Update: 2010-09-20