类矩形盾构隧道衬砌结构设计模型研究

叶宇航; 柳献; 刘震; 张维熙; 杨志豪; 朱瑶宏

doi:10.3969/j.issn.0258-2724.20170553

类矩形盾构隧道衬砌结构设计模型研究

doi: 10.3969/j.issn.0258-2724.20170553

叶宇航^1,2,,
柳献^2, ,,
刘震²,
张维熙²,
杨志豪³,
朱瑶宏⁴

基金项目: 国家自然科学基金资助项目（51578409）

详细信息

作者简介:
叶宇航（1995—），男，工程师，研究方向为隧道与地下工程设计，E-mail：2584300145@qq.com

通讯作者:
柳献（1977—），男，教授，研究方向为隧道与地下建筑工程结构全寿命设计理论与维护技术，盾构隧道衬砌结构的性能诊断、安全评价与加固设计，E-mail：xian.liu@tongji.edu.cn

中图分类号: TU93
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- 被引次数: 0
出版历程
- 收稿日期: 2017-07-13
- 修回日期: 2018-06-12
- 网络出版日期: 2019-05-09
- 刊出日期: 2019-12-01

Study on Design Model of Quasi-Rectangular Shield Tunnel Linings

YE Yuhang^{1,2
,},
LIU Xian^{2
, ,},
LIU Zhen²,
ZHANG Weixi²,
YANG Zhihao³,
ZHU Yaohong⁴

摘要

摘要: 为了得到适用于类矩形盾构隧道结构设计模型，通过整环足尺试验模拟类矩形盾构隧道在正常运营工况下的实际受力，得到试验结构的变形和内力，采用等效刚度模型和梁-弹簧模型对试验结果进行分析，得到有效的类矩形盾构隧道结构设计参数. 结果表明：采用等效刚度模型作为类矩形盾构隧道结构计算模型，难以得到同时符合结构长短轴变形的管片刚度折减系数；采用梁-弹簧模型作为类矩形盾构隧道结构计算模型，结构变形和结构内力计算结果和足尺试验结果较为匹配，能真实反应类矩形盾构隧道结构受力，选用梁-弹簧模型作为类矩形盾构隧道结构计算模型更为合理，所研究类矩形结构管片接缝的抗剪刚度建议为341 × 10⁶～368 × 10⁶ N/m；负弯矩接缝抗弯刚度建议为114 × 10⁶～491 × 10⁶ N•m/rad，正弯矩接缝抗弯刚度范围为85 × 10⁶～177 × 10⁶ N•m/rad.
- 类矩形盾构隧道 /
- 足尺试验 /
- 等效刚度模型 /
- 梁-弹簧模型
Abstract: In order to obtain a design model for quasi-rectangular shield tunnel linings, a full-scale ring test was conducted to acquire the deformation and internal forces of the linings with loads simulated according to the actual ones in normal operation conditions. The test results were then analyzed in comparison with the numerical results based on the equivalent stiffness model and the beam-spring model, to determine parameters of the design model of quasi-rectangular tunnel linings. Results show that using the equivalent stiffness model to design of the quasi-rectangular shield tunnel linings, the segment stiffness reduction factor that can account for the deformation along both the long and short axes could not be obtained. While applying the beam-spring model, the computed structural responses and the influence of longitudinal joints on moment distribution both agree well with the experimental results. Therefore, it is more reasonable to use the beam-spring model as the design model of quasi-rectangular shield tunnel linings. For the quasi-rectangular shield tunnel linings under study, input parameters for the design model, including the shearing rigidity, negative-moment bending rigidity, and positive-moment bending rigidity of segment joints, are recommended as 341 × 10⁶ − 368 × 10⁶ N/m, 114 × 10⁶ − 491 × 10⁶ N•m/rad, and 85 × 10⁶ − 177 × 10⁶ N•m/rad, respectively
- quasi-rectangular shield tunnel /
- full-scale ring test /
- equivalent stiffness model /
- beam-spring model

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图 1 试验试件

Figure 1. Schematic diagram of test specimen

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图 2 加载装置及荷载分组

Figure 2. Schematic diagram of loading device and test load grouping

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图 3 结构变形测点布置

Figure 3. Layout of structure deformation measuring points

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图 4 主筋及混凝土应变测点布置

Figure 4. Layout of main steel bars strain and concrete strain measuring point

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图 5 试验荷载作用下衬砌结构整体变形

Figure 5. Overall deformation of ling under test load

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图 6 截面应变分布

Figure 6. Strain distribution of segmental cross section

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图 7 试验荷载作用下弯矩

Figure 7. Bending moment diagram under test load

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图 8 试验荷载作用下轴力

Figure 8. Axial force diagram under test load

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表 1 试验荷载作用下衬砌结构长短轴变形

Table 1. Long and short axis deformation of ling

项目	长轴变形	中柱右侧短轴变形	中柱左侧短轴变形
变形值/mm	4.68	4.74	6.92
千分比/‰	0.42	0.68	1.00

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表 2 试验荷载作用下衬砌结构内力

Table 2. Internal force of ling under test load

截面编号	弯矩/（kN•m）	轴力/kN
①	–289	–631
②	237	–628
③	–121	–719
④	247	–592
⑤	–283	–648
⑥	–287	–635
⑦	260	–599
⑧	–135	–741
⑨	210	–598
⑩	–298	–636
中柱	9	–1 191

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表 3 试验荷载作用下结构变形数值计算结果与试验结果对比

Table 3. Comparison of numerical results of structural deformation with experimental results mm

结构变形位置	不同管片刚度折减系数								试验结果
结构变形位置	0.85	0.80	0.75	0.70	0.65	0.60	0.55	0.50	试验结果
长轴	3.24	3.41	3.61	3.84	4.10	4.40	4.77	5.20	4.68
中柱右侧短轴	4.32	4.55	4.81	5.12	5.47	5.88	6.36	6.94	4.74
中柱左侧短轴	4.32	4.55	4.81	5.12	5.47	5.88	6.36	6.94	6.92

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表 4 内力数值计算结果与试验结果对比分析

Table 4. Comparison of numerical results of internal force with experimental results

截面编号	试验结果		数值计算结果		试验/数值
截面编号	弯矩/（kN•m）	轴力/kN	弯矩/（kN•m）	轴力/kN	弯矩	轴力
①	–289	–631	–277	–639	1.04	0.99
②	237	–628	228	–607	1.04	1.03
③	–121	–719	–153	–730	0.79	0.98
④	247	–592	251	–605	0.98	0.98
⑤	–283	–648	–277	–641	1.02	1.01
⑥	–287	–635	–277	–639	1.04	0.99
⑦	260	–599	251	–605	1.04	0.99
⑧	–135	–741	–153	–730	0.88	1.02
⑨	210	–598	249	–605	0.88	0.99
⑩	–298	–636	–277	–641	0.84	0.99
中柱	–9	–1 191	0	–1 191		1.00

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表 5 试验荷载作用下结构变形数值计算与试验结果对比

Table 5. Comparison of numerical results of structural deformation with experimental results

结构变形位置	试验/mm	计算数值/mm	试验/数值
长轴	4.68	4.98	0.94
中柱右侧短轴	4.74	4.68	1.01
中柱左侧短轴	6.92	7.29	0.95

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表 6 内力数值计算结果与试验结果对比分析

Table 6. Comparison of numerical results of internal force with experimental results

截面编号	试验结果		数值计算结果		试验/数值
截面编号	弯矩/（kN•m）	轴力/kN	弯矩/（kN•m）	轴力/kN	弯矩	轴力
①	–289	–631	–278	–634	1.04	1.00
②	237	–628	215	–603	1.10	1.04
③	–121	–719	–117	–710	1.03	1.01
④	247	–592	227	–602	1.09	0.98
⑤	–283	–648	–276	–636	1.03	1.02
⑥	–287	–635	–289	–633	0.99	1.00
⑦	260	–599	211	–601	1.23	1.00
⑧	–135	–741	–139	–711	0.97	1.04
⑨	210	–598	208	–603	1.01	0.99
⑩	–298	–636	–295	–637	1.01	1.00
中柱	–9	–119 1	–14	–123 0		0.97

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