吉林大学学报(工学版) ›› 2023, Vol. 53 ›› Issue (6): 1669-1676.doi: 10.13229/j.cnki.jdxbgxb.20230075

• 交通运输工程·土木工程 • 上一篇    

拆装式桁梁新型钢枕桥面竖向荷载分配机制

孙志星1,2(),陈士通1,2(),赵曼3,许宏伟3,陈哲心4   

  1. 1.石家庄铁道大学 省部共建交通工程结构力学行为与系统安全国家重点实验室,石家庄 050043
    2.石家庄铁道大学 安全工程与应急管理学院,石家庄 050043
    3.石家庄铁道大学 土木工程学院,石家庄 050043
    4.济南金曰公路工程有限公司,济南 250101
  • 收稿日期:2023-01-28 出版日期:2023-06-01 发布日期:2023-07-23
  • 通讯作者: 陈士通 E-mail:sunstar810@126.com;chst@stdu.edu.cn
  • 作者简介:孙志星(1981-),女,副教授.研究方向:应急结构工程.E-mail:sunstar810@126.com
  • 基金资助:
    国家重点研发计划项目(2021YFB2600605);省部共建交通工程结构力学行为与系统安全国家重点实验室自主项目(ZZ2020-16)

Vertical load distribution mechanism of new steel sleeper bridge deck used for assembled truss beam

Zhi-xing SUN1,2(),Shi-tong CHEN1,2(),Man ZHAO3,Hong-wei XU3,Zhe-xin CHEN4   

  1. 1.State Key Laboratory of Mechanical Behavior and System Safety of Traffic Engineering Structures,Shijiazhuang Tiedao University,Shijiazhuang 050043,China
    2.School of Safety Engineering and Emergency Management,Shijiazhuang Tiedao University,Shijiazhuang 050043,China
    3.School of Civil Engineering,Shijiazhuang Tiedao University,Shijiazhuang 050043,China
    4.Jinan Kingyue Highway Engineering Company Limited,Jinan 250101,China
  • Received:2023-01-28 Online:2023-06-01 Published:2023-07-23
  • Contact: Shi-tong CHEN E-mail:sunstar810@126.com;chst@stdu.edu.cn

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摘要:

为解决拆装式桁梁既有桥面木枕储备量严重不足、制约其应急使用的问题,研发了一种新型钢枕桥面。为探明新型钢枕桥面用于拆装式桁梁时的竖向荷载分配机制,开展了4 m节段足尺试验及有限元仿真分析研究,在仿真和试验对比研究的基础上,基于实桥有限元模型探讨了加载位置、钢轨刚度、弦杆刚度、钢枕刚度、桁梁竖向刚度等因素对竖向荷载分配的影响规律。结果表明:竖向荷载在钢枕上的实际分布范围较理论计算值大;位于弦杆节点位置的钢枕较位于节间位置的钢枕所承受的荷载比例要大,且支撑刚度越大,所分担的荷载比例越大;单枕荷载极值占比随钢轨刚度的增大而减小,随钢枕刚度的增大而增大,而与桥跨结构竖向刚度关系很小;桁架梁弦杆刚度增大会减弱加载位置对单枕荷载极值占比的影响。新型钢枕可适用于拆装式桁梁对我国铁路常用钢轨线路中16~32 m跨桥梁进行抢通等应急使用的桥面,为拆装式桁梁的抢修抢险提供基础设施保障,并可提高抢通速度。

关键词: 防灾减灾工程, 钢枕, 明桥面, 荷载分配, 拆装式桁梁

Abstract:

In order to solve the current situation that the reserve of existing bridge wooden sleepers is seriously insufficient and thus restricts the emergency use of assembled truss beams, a new type of steel sleepers instead of wooden sleepers was studied. To find out the vertical load distribution mechanism of the new steel sleeper used for assembled truss beam, full scale test of 4 m section and finite element simulation analysis were carried out. According to comparison between simulation and test, the influence of loading position, rail stiffness, chord stiffness, steel sleeper stiffness, and bridge vertical stiffness on vertical load distribution was discussed according to real bridge finite element model. It can be concluded that the actual distribution range of vertical load on the bridge sleepers is larger than the theoretical value. The steel sleeper at the position of chord joint bears larger proportion of load than the steel sleepers at the position between chord joints, and the stronger the support stiffness is, the larger the proportion of load is borne. The load extremum ratio of single sleeper borne decreases with the increase of rail stiffness, increases with the increase of steel sleeper stiffness, and has little relationship with the vertical stiffness of bridge structure. The increase of chord stiffness weakens the influence of loading position on the load extremum ratio of single sleeper born. The new type of steel sleeper can be applied to the deck of the assembled truss beams which are used to repair 16~32 m span bridges in common steel rail lines of Chinese railway. It can provide infrastructure support for the emergency repair of the assembled truss beams, and improve the reopened speed.

Key words: disaster prevention and mitigation engineering, steel sleeper, open deck, load distribution, assembled truss beam

中图分类号: 

  • U213.3

图1

新型钢枕桥面正面图"

图2

4 m节段钢枕受力分布试验"

图3

三种工况下各轨枕竖向荷载分配对比"

表1

4 m试验节段受力最大钢枕各工况实测值和计算值"

加载

工况

受力最大钢枕单枕承受轴重荷载最大百分比/%
试验值仿真值理论值荷载等级为207~759 kN的试验值波动差设计荷载为345 kN的试验值仿真值理论值

试验值/

仿真值

试验值/

理论值

C16#6#6#26.06~26.770.7126.3528.230.2693.487.1
C24#4#4#25.09~25.820.9225.3026.930.2694.183.6
C38#8#8#(9#)24.33~24.910.5824.3625.123.2397.1104.9

图4

三种工况各级荷载单枕最大分载结果"

图5

16 m跨桥梁计算模型及加载工况"

表2

单枕荷载极值占比"

计算

工况

加载位置单枕荷载极值占比/%
1跨中上弦杆腹杆交叉节点28.6
2跨中左侧2 m位置上弦杆竖杆交叉节点27.6
3跨中左侧0.8 m位置钢枕正上方24.8
4跨中右侧1 m位置右侧节间跨中23.2
5跨中左侧4 m位置上弦杆腹杆交叉节点28.8
6跨中左侧6 m位置上弦杆竖杆交叉节点28.1

图6

不同类型钢轨各工况单枕最大分载结果"

表3

不同类型钢轨单枕荷载极值占比及其加载工况"

轨道类型

对水平轴惯

性矩/cm4

单枕荷载极

值占比/%

加载工况
CHN45148934.26工况5
CHN50203731.90工况5
CHN60321728.76工况5
CHN75449026.68工况5

图7

不同弦杆各工况单枕最大分载结果"

表4

不同弦杆单枕荷载极值占比及其加载工况"

弦杆编号

对水平轴惯

性矩/cm4

单枕荷载极值占比/%加载工况
313 14028.76工况5
50218 49528.18工况5
50123 85027.93工况5

图8

不同钢枕各工况单枕最大分载结果"

表5

不同钢枕单枕荷载极值占比及其加载工况"

钢枕规格/mm惯性矩/cm4单枕荷载极值占比/%加载工况
F150×4807.8227.21工况5
F150×5982.1228.76工况5
F150×61145.9030.07工况5
F150×81411.8032.17工况5

图9

桁梁不同竖向刚度各工况单枕最大分载结果"

表6

桁梁不同竖向刚度单枕荷载极值占比及其加载工况"

桁梁跨度/m挠跨比

单枕荷载极

值占比 %

加载工况
161/242428.76工况5
241/105728.78工况5
321/50828.79工况5
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