大跨铁路桥梁支座位移监测数据漂移现象分析及处理

为研究大跨铁路桥梁支座位移监测数据漂移现象,以国内某大跨铁路桥梁监测系统为背景,对支座位移漂移现象进行分类及处理。结果表明:支座位移监测数据漂移可分为渐进式漂移和突变式漂移,渐进式漂移是结构正常响应,突变式漂移是异常数据,需归位修正;支座位移渐进式漂移现象多发生在列车过桥时段,由列车激振释放主梁与支座间摩阻力产生,温度上升时段,支座位移渐进式增加,反之则反之;采用支座位移突变式漂移位置前后小区间均值可以准确实现数据归位修正;由于部分列车载重较大及材料老化等原因,导致列车过桥时支座渐进式漂移量增大。

大跨铁路桥梁信息化管养平台设计研究

为进一步保障大跨铁路桥梁结构安全,科学化桥梁运维管理,以天兴洲长江大桥信息化管养平台设计为案例,详细介绍了管养信息化平台的基本架构,阐述了管养信息化平台各子系统的基本功能,借助现代信息化技术,将多源数据融合,分析挖掘数据特征,建立结构预警体系,实现结构状态评价,指导桥梁实际管理养护,为同类型桥梁管养信息化平台设计提供参考。

大跨度铁路连续梁桥现浇支架设计

为保障大跨度铁路连续梁桥支架结构施工期安全、稳定,桥梁成桥线形及内力满足设计要求,文章以黔张常铁路联络线特大桥跨新河(40+64+36)m连续梁桥为工程实例,通过对该桥支架系统的设计计算,重点分析支架力学特性及杆件优化。计算结果表明:支架系统强度、刚度及稳定性均满足规范要求,且具有一定的富余量,力学指标合理,为今后类似工程提供参考和经验。

沪通长江大桥数字化运维系统的设计研发

当前,我国大量已建大跨铁路桥梁的运营维护与安全面临巨大挑战,既有养修的人员、技术、设备、理念及管理制度越来越滞后于大型铁路桥梁的现代化运维需求,随着现代信息及物联网技术的发展,数字化、标准化、智能化、网络化的智慧运营维护技术与体系的形成成为可能。以沪通长江大桥运营维护方案为依托,针对大跨径铁路桥梁现代化运维和管养需求,提出集多源信息获取及管理、结构智能分析与状态评估、智能养修管理等功能于一身的数字化大桥运维平台的总体设计,明确平台的基本功能和物理架构,并进一步介绍沪通长江大桥已建BIM建设管理、长期结构健康监测、电子化巡检、视觉检测等子系统的具体实施情况,为大数据时代下大跨径铁路桥梁的先进维护进行了一定探索。

Applicability of small resistance fastener on long-span continuous bridges of high-speed railway

Ballastless tracks have been widely applied in high-speed railway (HSR). The adaptability research between continuous welded rails (CWR) and long-span bridges of HSR is of great practical engineering significance. Based on the HSR long-span continuous bridges, the integrative spatial finite element model of track-bridge-pier-foundation system was established with the nonlinear spring element simulating the longitudinal resistance between track and bridge. Comparative study on the various additional longitudinal forces of CWR using the common fasteners and small resistance fasteners was carried out. Analysis results indicate that the additional expansion forces and additional rail-breaking forces in long-span ballastless continuous girders can be reduced evidently by 40% 50% after adopting small resistance fasteners, but lead to greater rail broken gap. The small resistance fasteners have little influence on the additional force only caused by vertical load, but can reduce the additional force caused by vertical load combined with braking load by over 10%. Besides, transient analysis method is proved to be more accurate and safe in calculating additional longitudinal forces when the train running or braking on the bridge, compared with the traditional static method.