CRTS Ⅱ型板断裂条件下桥上无缝线路伸缩力特性

doi:10.3969/j.issn.0258-2724.20180944

基金项目:国家自然科学基金项目（51768023）；江西省研究生创新专项资金项目（YC2017-S243）；江西省自然科学基金项目（20171BAB206054）；江西省教育厅重点项目（GJJ180290）

详细信息

作者简介:
张鹏飞（1975—），男，副教授，研究方向为桥上无缝线路设计理论与关键技术，E-mail：zhangpf4236@163.com

通讯作者:
雷晓燕（1956—），男，教授，研究方向为轨道结构动力学、轨道交通环境振动、噪声预测与控制，E-mail：xiaoyanlei2013@163.com

中图分类号:U213.9+11
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出版历程
- 收稿日期:2018-11-03
- 修回日期:2019-03-28
- 网络出版日期:2020-05-08
- 刊出日期:2020-10-01

Expansion-Constriction Force Characteristics of Continuously Rails on Bridge under Fracture Condition of CRTS Ⅱ Track Slab Welded

摘要

摘要:为了研究桥上CRTSⅡ型轨道板断裂条件下轨道、桥梁结构纵向受力变形规律及其影响，基于有限元法和梁-板-轨相互作用机理，建立桥上CRTSⅡ型板式无砟轨道无缝线路空间耦合模型，分析不同轨道板断缝位置、断缝宽度、裂缝深度及轨道板、底座板伸缩刚度对断板条件下桥上无砟轨道无缝线路伸缩力分布规律的影响. 研究结果表明：在计算轨道板断裂条件下桥上无砟轨道无缝线路伸缩力时，应根据不同检算部件选取最不利的断板位置，建议将轨道板断缝宽度和深度分别取2 mm和200 mm、轨道板、底座板伸缩刚度折减至10%～50%，计算结果是偏安全的且不失一般性；轨道板断裂增加了断缝处CA （cement asphalt）砂浆层及底座板断裂的风险，断板侧的钢轨纵向位移及轨板相对位移均在断缝处急剧变化.
- CRTSⅡ型板式无砟轨道/
- 桥上无缝线路/
- 轨道板断裂/
- 断缝位置/
- 断缝宽度/
- 裂缝深度
Abstract:In order to study the longitudinal stress and deformation characteristics and their influences on track and bridge structure under the fracture condition of CRTSⅡ track slab, a spatial coupling model based on the finite element method and bridge-slab-rail interaction mechanism was established. This model can analyze the influences of crack location, width and depth of track slabs, as well as the expansion-constriction stiffness of track slab and bed plate, on distribution rules of the expansion-constriction force of continuously welded rail (CWR) on bridge. Results show that, in order to calculate the expansion-constriction force of CWR on bridge under the fracture condition of CRTSⅡ track slab, a most unfavorable fracture location at track slab should be selected according to the different checking parts. Meanwhile, the crack width and depth of track slab are suggested to be 2 mm and 200 mm, respectively, and the expansion-constriction stiffness of track slab and bed plate should be reduced to 10%−50%, since in this way the calculation result is conservative without losing generality. Track slab fracture increases the fracture risk of cement asphalt mortar screed and bed plate; the longitudinal displacement of rail and the relative displacement between rail and track slab on the side of broken slab are changed dramatically at the crack.
- CRTSⅡ slab track/
- CWR on bridge/
- track slab fracture/
- crack location/
- crack width/
- crack depth

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图 1精细化的有限元模型

Figure 1.Refined finite element model

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图 2轨道板断缝位置

Figure 2.Crack locations of track slab

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图 3结构纵向力与位移

Figure 3.Longitudinal forces and displacements of structures

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图 4不同轨道板断缝位置工况下钢轨纵向力

Figure 4.Longitudinal forces of rail under different crack locations of track slab

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图 5不同轨道板断缝宽度条件下钢轨纵向力

Figure 5.Longitudinal forces of rail under different crack widths of track slab

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图 6不同轨道板裂缝深度条件下钢轨纵向力

Figure 6.Longitudinal forces of rail under different crack depths of track slab

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图 7不同轨道板裂缝深度条件下轨道板内部纵向应力

Figure 7.Longitudinal stresses in track slab under different crack depths of track slab

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图 8不同轨道板裂缝深度条件下轨道板内部裂缝宽度

Figure 8.Crack widths in track slab under different crack depths of track slab

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图 9不同轨道板、底座板伸缩刚度条件下钢轨纵向力

Figure 9.Longitudinal forces of rail under different expansion-constriction stiffness of track slab and bed plate

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表 1主要结构物理量符号

Table 1.Symbolic representation of main structural physical quantities

结构名称	物理量	符号
钢轨	纵向力	F_r
钢轨	纵向位移	D_r
轨道板	上表面纵向应力	S_tsu
	下表面纵向应力	S_tsl
	上表面纵向位移	D_tsu
CA砂浆层	纵向应力	S_CAm
底座板	上表面纵向应力	S_bpu
	下表面纵向应力	S_bpl
	下表面纵向位移	D_bpl
桥梁梁体	纵向位移	D_b
桥台	纵向力	F_a
桥台	纵向位移	D_a
桥墩	纵向力	F_p
桥墩	纵向位移	D_p
钢轨轨道板	相对位移	∆D_rts
轨道板底座板	相对位移	∆D_tsbp
底座板桥梁	相对位移	∆D_bpb

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表 2主要结构纵向力最大值

Table 2.Maximum longitudinal forces of main structures

轨道板断裂工况	F_r/kN		S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa	F_a/kN	F_p/kN
轨道板断裂工况	压（应）力	拉（应）力	S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa	F_a/kN	F_p/kN
未断板	−46.865	10.835	21.901	16.093	2.783	12.735	16.416	341.731	183.594
断板（断板侧）	−47.731	30.343	16.310	155.824	16.287	43.736	21.161	339.867	176.715
断板（非断板侧）	−46.902	12.537	21.211	15.747	2.741	12.390	15.403	339.867	176.715

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表 3主要结构位移最大值

Table 3.Maximum longitudinal displacements of main structures mm

轨道板断裂工况	D_r		∆D_rts	D_tsu	∆D_tsbp	D_bpl	∆D_bpb	D_b	D_a	D_p
轨道板断裂工况	压缩变形	拉伸变形	∆D_rts	D_tsu	∆D_tsbp	D_bpl	∆D_bpb	D_b	D_a	D_p
未断板	−1.727	1.041	0.192	−1.755	0.015	−1.745	56.927	−58.392	1.139	1.476
断板（断板侧）	−1.854	1.009	0.368	−2.111	0.083	−1.876	56.837	−58.458	1.133	1.457
断板（非断板侧）	−1.768	1.009	0.192	−1.796	0.016	−1.787	56.948	−58.447	1.133	1.457

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表 4不同轨道板断缝位置条件下伸缩力计算结果

Table 4.Calculation results of expansion-constriction force with different crack locations of track slab

轨道板断缝位置	F_r/kN		D_r/mm		∆D_rts/mm	S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa
轨道板断缝位置	压（应）力	拉（应）力	压缩变形	拉伸变形	∆D_rts/mm	S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa
位置A	−47.583	28.430	−1.695	1.164	0.345	21.978	151.994	15.506	42.121	19.708
位置B	−43.014	10.496	−1.668	0.965	0.412	21.970	129.348	13.173	35.830	17.602
位置C	−48.545	10.502	−1.66	1.011	0.303	21.968	136.862	13.888	38.001	17.499
位置D	−48.600	11.390	−1.719	1.007	0.336	21.967	149.018	15.294	41.214	19.205
位置E	−47.731	30.343	−1.854	1.009	0.368	16.310	155.824	16.287	43.736	24.161

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表 5不同轨道板断缝宽度条件下伸缩力计算结果

Table 5.Calculation results of expansion-constriction forces with different crack widths of track slab

轨道板断缝宽度/mm	F_r/kN		D_r/mm		∆D_rts/mm	S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa
轨道板断缝宽度/mm	压（应）力	拉（应）力	压缩变形	拉伸变形	∆D_rts/mm	S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa
1	−47.721	30.141	−1.853	1.009	0.366	16.310	160.817	16.594	43.058	24.089
2	−47.731	30.343	−1.854	1.009	0.368	16.310	155.824	16.287	43.736	24.161
3	−47.741	30.536	−1.856	1.008	0.371	16.310	151.089	16.033	44.371	24.230
4	−47.750	30.720	−1.857	1.008	0.373	16.309	146.597	15.819	44.966	24.296
5	−47.759	30.895	−1.858	1.008	0.376	16.309	142.325	15.634	45.524	24.358

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表 6不同轨道板裂缝深度条件下纵向力和位移最大值计算结果

Table 6.Calculation results of maximum longitudinal forces and maximum longitudinal displacements with different crack depths of track slab

轨道板裂缝深度/mm	F_r/kN		D_r/mm		∆D_rts/mm	S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa
轨道板裂缝深度/mm	压（应）力	拉（应）力	压缩变形	拉伸变形	∆D_rts/mm	S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa
0	−46.865	10.835	−1.727	1.041	0.192	21.901	16.093	2.783	12.735	16.416
40	−46.875	10.973	−1.729	1.040	0.192	21.313	16.819	2.825	13.049	16.610
80	−46.922	12.060	−1.736	1.038	0.193	19.965	19.036	3.527	14.149	17.262
120	−47.033	14.965	−1.753	1.033	0.193	18.006	23.813	4.950	17.193	18.498
160	−47.256	20.258	−1.786	1.025	0.226	16.313	36.464	7.741	24.019	20.548
200	−47.731	30.343	−1.854	1.009	0.368	16.310	155.824	16.287	43.736	24.161

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表 7不同轨道板/底座板伸缩刚度条件下纵向力和位移最大值计算结果

Table 7.Calculation results of maximum longitudinal forces and maximum longitudinal displacements under different expansion-constriction stiffness of track slab and bed

轨道板、底座板伸缩刚度	D_r/mm		S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa	F_a/kN	F_p/kN
轨道板、底座板伸缩刚度	压缩变形	拉伸变形	S_tsu/MPa	S_tsl/MPa	S_CAm/MPa	S_bpu/MPa	S_bpl/MPa	F_a/kN	F_p/kN
刚度不折减	−1.854	1.009	16.310	155.824	16.287	43.736	21.161	339.867	176.715
刚度折减至30%	−3.668	1.705	8.632	77.718	8.126	22.166	13.908	315.230	364.641
刚度折减至10%	−24.435	9.100	2.527	21.475	2.242	6.438	4.838	455.361	2 062.186

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