钢管混凝土拱桥拱肋刚度设计取值分析

韦建刚; 陈宝春

钢管混凝土拱桥拱肋刚度设计取值分析

福州大学土木工程学院, 福建福州 350002

基金项目:

福建省重大科技项目 2003F007

福建省科技厅项目 JA07014

详细信息

作者简介:
韦建刚(1971-), 男, 广西上思人, 福州大学副研究员, 博士, 从事桥梁工程研究

中图分类号: U442.5
计量
- 文章访问数: 211
- HTML全文浏览量: 56
- PDF下载量: 427
- 被引次数: 0
出版历程
- 收稿日期: 2007-10-21
- 刊出日期: 2008-04-25

Analysis on rib rigidity of concrete filled steel tubular arch bridge

School of Civil Engineering, Fuzhou University, Fuzhou 350002, Fujian, China

More Information

Author Bio:
Wei Jian-gang(1971-), male, PhD, associate researcher, +86-591-87892620, weijg@fzu.edu.cn

摘要

摘要: 为了解桁式钢管混凝土拱肋弦管设计刚度对拱桥受力性能计算结果的影响, 以一座钢管混凝土多肢桁式拱桥为实例, 建立了有限元模型, 进行了弦管截面设计刚度取值的参数分析, 在对已建钢管混凝土桁式拱桥的截面构成进行调查的基础上, 提出了桁式拱桥截面设计刚度取值建议, 即根据不同的计算要求, 混凝土截面刚度折减系数取1.0或0.4。分析结果显示, 按照该建议, 截面的内力计算值为实测值的1.2~1.5倍, 变形计算值为实测值的1.5~1.9倍。可见, 此取值建议可以保证桁式钢管混凝土拱桥的设计具有一定的安全储备。
- 桥梁工程 /
- 钢管混凝土拱桥 /
- 拱肋 /
- 设计刚度
Abstract: In order to study the effect of tube rigidity on the mechanical character of truss CFST(concrete filled steel tubular)arch bridge, a true arch bridge was taken as sample, and the parameter analysis for the rigidity was carried out by using finite element model.Based on the investigation of section composition for arch rib, a suggestion was presented to calculate tube rigidity, in which the rigidity reduced factor of concrete was adopted as 1.0 or 0.4 for different calculation demands.Analysis result indicates that for internal force, the rate of calculation value to reality value is between 1.2 and 1.5, for deformation the rate is between 1.5 and 1.9.So, the suggestion can secure some safety reserve for the design of truss CFST arch bridge.
- bridge engineering /
- concrete filled steel tubular arch bridge /
- arch rib /
- design rigidity

HTML全文

图 1 有限元模型

Figure 1. Finite element model

下载: 全尺寸图片幻灯片

图 2 弦管内力随抗弯刚度变化的趋势

Figure 2. Changing tendences of inner forces for tube with flexural rigidity

下载: 全尺寸图片幻灯片

图 3 弦管内力随抗压刚度变化的趋势

Figure 3. Changing tendences of inner forces for tube with compressive rigidity

下载: 全尺寸图片幻灯片

图 4 拱肋应力随抗弯刚度变化的趋势

Figure 4. Changing tendences of rib stresses with flexural rigidity

下载: 全尺寸图片幻灯片

图 5 拱肋应力随抗压刚度变化的趋势

Figure 5. Changing tendences of rib stresses with compressive rigidity

下载: 全尺寸图片幻灯片

图 6 肋挠度随抗弯度的变化趋势

Figure 6. Changing tendences of rib deflections with flexural rigidity

下载: 全尺寸图片幻灯片

图 7 肋挠度随抗压刚度的变化趋势

Figure 7. Changing tendenees of rib deflections with compressive rigidity

下载: 全尺寸图片幻灯片

图 8 稳定系数随抗弯刚度的变化趋势

Figure 8. Changing tendences of stability coefficients with flexural rigidity

下载: 全尺寸图片幻灯片

图 9 稳定系数随抗压刚度的变化趋势

Figure 9. Changing tendences of stability coefficients with compressive rigidity

下载: 全尺寸图片幻灯片

图 10 有限元模型前五阶振型

Figure 10. Five vibration modes of finite element model

下载: 全尺寸图片幻灯片

图 11 频率随抗弯刚度的变化

Figure 11. Changing tendences of frequencies with flexural rigidity

下载: 全尺寸图片幻灯片

图 12 频率随抗压刚度的变化

Figure 12. Changing tendences of frequencies with compressive rigidity

下载: 全尺寸图片幻灯片

图 13 管径与拱肋高度的比值

Figure 13. Ratio of tube diameter to height of arch rib

下载: 全尺寸图片幻灯片

图 14 弦管抗弯刚度与截面抗弯刚度的比值

Figure 14. Ratio of tube flexural rigidity to section flexural rigidity

下载: 全尺寸图片幻灯片

表 1 计算方法

Table 1. Calculation methods

规范	抗压刚度	抗弯刚度
CECS^[8]	EA=E_sA_s+E_cA_c	EI=E_sI_s+E_cI_c
JCJ^[9]	E_sc=0.85[ρE_s+(1-ρ)E_c]	E_sc=0.85[ρE_s+(1-ρ)E_c]
DL/T^[10]	查表	查表
LRFD^[11]	EA=E_sA_s+0.8E_cA_c	EI=E_sI_s+0.8E_cI_c
BS^[12]	EA=E_sA_s+E_cA_c	EI=E_sI_s+E_cI_c
AIJ^[13]	EA=E_sA_s+E_cA_c	EI=E_sI_s+0.2E_cI_c

下载: 导出CSV

表 2 桥例刚度

Table 2. Bridge rigidities

规范	EA_x/10⁹kN	EI_x/(10⁹kN·m²)
CECS^[8]	10.08	0.23
JCJ^[9]	8.69	0.16
DL/T^[10]	9.22	0.22
LRFD^[11]	5.72	0.21
BS^[12]	10.08	0.23
AIJ^[13]	10.08	0.13

下载: 导出CSV

表 3 影响规律对比

Table 3. Comparison of effect rules

拱肋形式		受力特性计算结果分析
拱肋形式		内力	应力	变形	一类稳定	振型顺序	自振频率
实体拱肋^[5-7]	抗压刚度增大	可忽略	可忽略	可忽略	可忽略	可忽略	可忽略
实体拱肋^[5-7]	抗弯刚度增大	轴力可忽略, 弯矩增大	增大	减小	增大	可忽略	可忽略
桁式拱肋	抗压刚度增大	轴力可忽略, 弦杆弯矩减小	可忽略	减小	增大	变化过大引起顺序改变	可忽略
桁式拱肋	抗弯刚度增大	轴力可忽略, 弦杆弯矩增大	增大	可忽略	可忽略	可忽略	可忽略

下载: 导出CSV

表 4 刚度折减系数

Table 4. Rigidity reduced factors

计算内容	钢管混凝土拱肋形式
	单圆管及哑铃形		桁式
	α_A	α_I	α_A	α_I
内力、应力、动力特性	1.0	1.0	0.4	1.0
弹性屈曲与变形	0.4	0.4	0.4	0.4

下载: 导出CSV

参考文献(14)

[1]	陈宝春. 钢管混凝土拱桥计算理论研究进展[J]. 土木工程学报, 2003, 36(12): 47-57. Chen Bao-chun. State-of-the-art theory of calculationfor concrete-filled steel tubular arch bridge[J]. China Civil Engineering Journal, 2003, 36(12): 47-57. (in Chinese)
[2]	陈宝春, 杨亚林. 钢管混凝土拱桥调查与分析[J]. 世界桥梁, 2006, 34(2): 73-77. Chen Bao-chun, Yang Ya-lin. Investigation and analysis of concrete-filled steel tube arch bridges[J]. World Bridges, 2006, 34(2): 73-77. (in Chinese)
[3]	王来永, 陈宝春, 孙潮. 钢管混凝土设计方法比较[J]. 工程力学, 2001, 18(增刊): 544-548. Wang Lai-yong, Chen Bao-chun, Sun Chao. Comparison of design methods for CFST[J]. Engineering Mechanics, 2001, 18(S): 544-548. (in Chinese)
[4]	卢辉. 世界各国规程钢管混凝土构件抗弯承载力及抗弯刚度的对比[J]. 福建建筑, 2005, 23(2): 127-130. Lu Hui. Comparison on ultimate flexural bearing capacity and flexural stiffness of concrete filled steel tubes calculated by different design codes[J]. Fujian Architecture & Construction, 2005, 23(2): 127-130. (in Chinese)
[5]	陈宝春, 韦建刚. 钢管混凝土(单圆管)拱肋刚度对其动力特性的影响[J]. 地震工程与工程振动, 2004, 24(3): 105-109. Chen Bao-chun, Wei Jian-gang. Effect of rigidities of concrete filled steel tubular(single tube)arch rib on its dynamic characteristics[J]. Earthquake Engineering and Engineering Vibration, 2004, 24(3): 105-109. (in Chinese)
[6]	韦建刚, 陈宝春, 彭桂翰. 钢管混凝土单圆管拱刚度取值对静力计算的影响[J]. 公路交通科技, 2004, 21(11): 47-51. Wei Jian-gang, Chen Bao-chun, Peng Gui-han. Analysis of rigidity of concrete filled steel tubular (single tube) arch[J]. Journal of Highway and Transportation Research and Development, 2004, 21(11): 47-51. (in Chinese)
[7]	韦建刚, 王加迫, 陈宝春. 钢管混凝土哑铃形拱肋设计刚度取值问题研究[J]. 福州大学学报: 自然科学版, 2007, 35(4): 582-587. Wei Jian-gang, Wang Jia-po, Chen Bao-chun. Analysis of rigidity in design for CFST dumbbell-rib arch bridges[J]. Journal of Fuzhou University: Natural Science Edition, 2007, 35(4): 582-587. (in Chinese)
[8]	CECS 28: 90, 钢管混凝土结构设计与施工规程[S].
[9]	JCJ 01—89, 钢管混凝土结构设计与施工规程[S].
[10]	DL/T 5085—1999, 钢-混凝土组合结构设计规程[S].
[11]	LRFD-US-3-12, Load and resistance factor design specifica-tion for structural steel buildings[S].
[12]	BS5400, British standards part 5: concrete and composite bridges[S].
[13]	AIJ 1997, Recommendations for design and construction of concrete filled tubular structures[S].
[14]	Chen Bao-chun. Nonlinear characteristics and ultimate loadcarrying capacity of concrete filledtubular arch[D]. Kyushu: Kyushu University, 2003.