宁波大榭二桥“帆”形桥塔设计创新

宁波大榭二桥为主跨392 m的单索面斜拉桥,桥塔采用了特殊的“帆”形结构样式,且为钢混组合结构,主梁为钢梁。新型桥塔结构设计为该桥设计的重要难点和特色。从结构受力分析的角度入手,展示桥塔结构的受力状况,论述桥塔各重要节点的设计理念与设计方案,对桥塔整体、拉索锚固区和钢混节点3个关键部位重点展开分析,供类似工程参考。

四肢异形独塔斜拉桥桥塔设计

邓州市穰城跨湍河大桥为主跨90m+90m的空间框架式独塔钢-混凝土组合梁斜拉桥,主塔采用四肢异形空间框架式独塔,桥塔设计总高75.5m,四根塔柱倾斜角度较大,且上塔柱为空间曲线结构,塔柱受弯、剪、扭效应明显。结合MIDAS Civil对桥塔进行静、动力分析。索塔上采用多种形式的横梁,针对不同位置的横梁选择相对最优的衔接位置、锚固方式来优化设计。总结四肢异形独塔斜拉桥在桥塔设计中遇到的重难点,为类似桥塔设计提供参考。

公铁合建四塔斜拉桥桥塔设计研究

以珠机(珠海市区至机场)城际铁路金海特大桥四塔斜拉桥为背景,为研究桥塔材质与布置方式对四塔斜拉桥静、动力性能的影响,比选了全混凝土塔、全钢塔、中间混凝土塔+两边钢塔混合布置3种方案。结果表明:中间混凝土塔+两边钢塔与全混凝土塔相比,结构体系刚度差别很小;全部采用钢塔时,结构体系刚度相对较小;混凝土塔和钢塔在外轮廓尺寸相同的前提下,中塔为混凝土塔时混凝土应力较大;混凝土塔抗震性能较差,钢塔抗震性能较好。综合考虑结构受力、构造、施工等因素,推荐采用全钢塔方案。

双斜塔无背索斜拉桥桥塔设计

六安寿春西路桥为"V"形双斜塔无背索非对称斜拉桥,六安市标志性建筑,方案构思巧妙,造型新颖独特。本文从桥塔设计、拉索合理布置,论证双索面无背索桥梁方案,达到了安全、实用、耐久、经济、美观的设计要求,同时取得了较优的景观效果,可为后续同类桥梁设计提供参考。

重庆市万州长江二桥悬索桥桥塔设计

通过对重庆市万州区万州长江二桥桥塔结构的设计情况的简单介绍,论述了桥塔计算的主要内容,分别就桥塔静力计算、动力计算采用的计算模型进行了分析,说明了需注意的问题,研究了国内外不同规范对船舶撞击力的计算情况及设计采用的纵、横向撞击力数值,对桥塔进行了地震反应分析,根据桥塔局部应力情况进行了结构细节处理,提出了该桥桥塔结构设计的合理性。

常泰长江大桥主航道桥桥塔基础选型研究

常泰长江大桥主航道桥为主跨1176 m公铁合建斜拉桥,桥塔基础采用沉井方案。为降低沉井自重和减少桥墩局部冲刷,采用理论分析、数值模拟与水槽冲刷试验相结合的方式对沉井基础型式进行研究。结果表明:在圆端形、梭形及矩形3种截面型式的沉井中,圆端形截面沉井的水流阻力系数最小;台阶型沉井相比传统沉井可以削弱墩前向下旋辊及减小墩侧高流速区的范围;台阶型沉井台阶宽9.0~10.0 m、台阶顶埋深位于0.6 H(H为沉井周边水深)处、挡墙高度为0.15 H时,可以起到较好的减冲刷防护效果。根据研究结果最终确定该桥采用圆端形截面台阶型沉井基础,其底面尺寸为95.0 m×57.8 m(横桥向×顺桥向),圆端半径28.9 m,台阶宽9.0 m,埋置在床面以下0.6 H处,台阶顶构造采用直角挡墙方案(挡墙高约4 m)。

Design and construction of Sutong Bridge tower

Sutong Bridge tower which is 300.4 m is the highest one in the world.The tower anchor area uses the steel-concrete composite structure,its structure and the stress mechanism are complex,so it must be paid more attention to the structure durable issue.The 300 m height makes the tower quite sensitive to the environmental factors such as wind and temperature.The wind resistance safety of tower in construction stage is especially important.In this paper,the design of composite structure is introduced.The key technologies of tower geometry control and wind resistance in construction stage are analyzed.

Research on key technologies in design of middle pylon of Taizhou Bridge

At the middle pylon of a three-pylon two-span suspension bridge, the effect of unbalanced loads on the adjacent spans may result in a series of technical bottlenecks in design, such as stability and anti-slippage between saddles and main cables. This article presents the researches conducted on structure selection and behavior characteristics of middle pylon, interaction mechanism between main cables and saddles and their anti-slippage safety performance, elastic and plastic stability analysis and safety assessment of steel middle pylon, and fatigue design load and method for steel pylon of Taizhou Bridge. According to the research results, a longitudinal inverted Y shape steel middle pylon is used in design, effectively solving many technical difficulties, and this type of pylon has become a suitable middle pylon structural form for many three-ovlon two-soan susoension bridges.