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纵连底座板断裂对桥上CRTSⅡ型板式无砟轨道受力的影响

陈小平 王芳芳 赵才友

陈小平, 王芳芳, 赵才友. 纵连底座板断裂对桥上CRTSⅡ型板式无砟轨道受力的影响[J]. 交通运输工程学报, 2014, 14(4): 25-35.
引用本文: 陈小平, 王芳芳, 赵才友. 纵连底座板断裂对桥上CRTSⅡ型板式无砟轨道受力的影响[J]. 交通运输工程学报, 2014, 14(4): 25-35.
CHEN Xiao-ping, WANG Fang-fang, ZHAO Cai-you. Fracture influence of longitudinal-continuous base layer on force characteristics of CRTSⅡ slab ballastless track on bridge[J]. Journal of Traffic and Transportation Engineering, 2014, 14(4): 25-35.
Citation: CHEN Xiao-ping, WANG Fang-fang, ZHAO Cai-you. Fracture influence of longitudinal-continuous base layer on force characteristics of CRTSⅡ slab ballastless track on bridge[J]. Journal of Traffic and Transportation Engineering, 2014, 14(4): 25-35.

纵连底座板断裂对桥上CRTSⅡ型板式无砟轨道受力的影响

基金项目: 

国家自然科学基金项目 51308081

铁道部科技研究开发计划项目 2010G006-B

详细信息
    作者简介:

    陈小平(1978-), 男, 福建邵武人, 成都大学副教授, 工学博士, 从事轨道结构研究

  • 中图分类号: U213.912

Fracture influence of longitudinal-continuous base layer on force characteristics of CRTSⅡ slab ballastless track on bridge

More Information
    Author Bio:

    CHEN Xiao-ping(1978-), male, associate professor, PhD, +86-28-84616652, cxp193@163.com

  • 摘要: 考虑纵连底座板断裂建立了CRTSⅡ型板式无砟轨道与桥梁纵向相互作用的力学模型, 采用有限元法求解力学模型, 确定了无砟轨道关键参数。以某大跨度连续梁桥为例, 降温幅度分别为10、20、30、40、50℃时, 纵连底座板在连续梁上7个代表性位置发生断裂后, 分析了钢轨、轨道板、砂浆和桥梁墩台的纵向力与位移。分析结果表明: 降温幅度为30℃时, 纵连底座板在连续梁上发生断裂时, 钢轨和轨道板的最大纵向附加力分别为155.75、233.21 kN, 断板对钢轨和轨道板纵向附加力有较大影响; 降温幅度不大于10℃时, 纵连底座板在连续梁上任意位置发生断裂, 轨道板与底座板的纵向相对位移均小于0.5 mm, 砂浆不会开裂; 降温幅度为50℃时, 纵连底座板在连续梁上任意位置断裂引起的固定支座纵向附加力最大为196.12 kN, 不会直接造成桥梁固定支座破坏; 建议在维修作业时, 锯切纵连底座板与其铺设时的温度差应不大于10℃, 并检算钢轨的强度是否能满足要求。

     

  • 图  1  纵向力学模型

    Figure  1.  Longitudinal mechanics model

    图  2  断裂位置

    Figure  2.  Fracture position

    图  3  钢轨纵向附加力

    Figure  3.  Additional longitudinal forces of rail

    图  4  钢轨纵向位移

    Figure  4.  Longitudinal displacements of rail

    图  5  轨道板纵向附加力

    Figure  5.  Additional longitudinal forces of slab

    图  6  轨道板纵向位移

    Figure  6.  Longitudinal displacements of slab

    图  7  砂浆开裂长度

    Figure  7.  Crack lengths of mortar

    图  8  轨道板与纵连底座板相对位移

    Figure  8.  Relative displacements between slab and LCBL

    图  9  连续梁固定支座纵向附加力

    Figure  9.  Additional longitudinal forces of fixed support

    图  10  滑动层摩擦阻力自平衡

    Figure  10.  Self-balancing of frictional resistance of slide layer

    表  1  墩台顶纵向水平刚度

    Table  1.   Longitudinal horizontal stiffnesses at pier tops

    下载: 导出CSV

    表  2  主要计算参数

    Table  2.   Main calculation parameters

    下载: 导出CSV

    表  3  钢轨纵向附加力最大值(断板股道)

    Table  3.   Maximal additional longitudinal forces of rail (track with fractured LCBL)

    下载: 导出CSV

    表  4  钢轨纵向附加力最大值(非断板股道)

    Table  4.   Maximal additional longitudinal forces of rail (track with non-fractured LCBL)

    下载: 导出CSV

    表  5  轨道板纵向附加力最大值(断板股道)

    Table  5.   Maximal additional longitudinal forces of slab (track with fractured LCBL)

    下载: 导出CSV

    表  6  轨道板纵向附加力最大值(非断板股道)

    Table  6.   Maximal additional longitudinal forces of slab(track with non-fractured LCBL)

    下载: 导出CSV

    表  7  桥梁固定支座纵向附加力

    Table  7.   Additional longitudinal forces of fixed supports of bridge

    下载: 导出CSV
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出版历程
  • 收稿日期:  2014-02-18
  • 刊出日期:  2014-08-25

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